RU2637818C1 - Air-supported coating for closed courtyard formed by internal wall envelopes of construction complex - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: coating consists of structurally independent hermetically connected central part and slopes. The coating is made dome-shaped, of elastic transparent material in the form of a hollow membrane. The slope coating membrane is divided radially into structurally independent sections joined together tightly and elastically by lateral sides. The internal cavity of the membrane of each section is divided into two chambers by a perforated partition made of an elastic transparent material. The inner surface of the upper chamber is covered with a light-reflecting coating. An additional membrane made of an elastic transparent material is inserted, which is connected to the lower ends of the coating slopes by the upper end and to the inner wall envelope of the building complex by the lower end at a negative acute angle to the roof surface. The coating slopes are provided with guides in the form of a cable. The first ends of the cables are fixed on the partitions connecting the supports of the central part of the coating. The second ends are fixed on the roof of the building module.

EFFECT: simplifying the installation of the coating, expanding the possibility of increasing the indoor space of the closed courtyard, reducing heat losses through the coating, reducing energy costs for coating installation, and heating the covered courtyard during the cold season.

5 cl, 2 dwg

Description

The invention relates to the construction of residential buildings and can be used to organize air support coatings when forming a closed indoor courtyard, limited by internal wall fencing of the construction complex.

Closest to the proposed invention is an air-bearing coating for a closed courtyard formed by the internal wall fencing of the building complex (RF patent No. 2503780, E04B 1/00, E04H 15/20, 01/10/2014), in which the coating is made dome-shaped from translucent elastic material, which is a hollow membrane inside. In addition, the coating consists of structurally independent central parts and slopes, hermetically connected along the perimeter of the upper ends with a coating of the central part, and the lower ends - with the inner wall of the building complex, forming a closed courtyard. The membranes of the slopes and the central part of the coating are made with the possibility of individual blowing of the internal cavity. The central part of the coating contains vertical supports of at least three, which are bounded from above by horizontal partitions connecting them, on which a membrane of the central part of the coating is fixed. The slopes of the coating are equipped with guides, the first ends of which are connected with partitions, and the second with the internal wall enclosure of the building complex, forming a closed courtyard.

The main disadvantage of the known air support coating for a closed courtyard formed by the internal wall fencing of the building complex is that the slopes of the coating are a continuous membrane. The large area of the membrane complicates the installation of the slopes of the coating, and also requires large energy costs to provide air blowing when installing an air-bearing dome. In aggregate, this limits the size of the area of the indoor closed courtyard.

Since the implementation of a translucent coating in the form of a single hollow membrane in a known airborne coating causes a large volume of its internal cavity, it is not sufficient to effectively create a difference in air temperature inside the membrane and inside an indoor closed courtyard due to blowing the membrane with warm air to the interior of the membrane to effectively shift the dew point to the outer surface of the coating courtyard, which causes heat loss through the roof, and also requires additional energy for heating the indoor space the friction of the yard in the cold season.

In addition, the coating is made transformable to provide natural convection of air in the enclosed space of the courtyard in the warm season, which complicates the design of the coating as a whole and its operation. Moreover, in the construction of the known coating, it is not possible to organize natural convection of air in the cold season, when the courtyard is completely closed and is an enclosed space, which leads to stagnation of air inside the courtyard, reduces comfort and requires additional energy consumption for artificial ventilation of the interior courtyard of a well-known building complex.

The present invention solves the problem of creating an airborne coating for a closed courtyard formed by the internal wall fencing of the building complex, the implementation of which allows to achieve a technical result, which consists in simplifying the installation of the coating, in expanding the possibility of increasing the indoor space of the inner closed courtyard, in reducing heat loss through the coating; in reducing energy costs for installation of the coating, for heating the covered courtyard in the cold season; in improving the comfort of the courtyard space.

The essence of the invention lies in the fact that in the air-bearing coating for a closed courtyard, formed by the internal wall fencing of the building complex, made dome-shaped from an elastic translucent material, which is a hollow membrane inside, in addition, the coating consists of structurally independent central parts and slopes hermetically connected along the perimeter of the upper ends with a coating of the central part, while the membranes of the slopes and the central part of the coating are made with possible by the individual blowing of the internal cavity, in addition, the central part of the coating contains vertical supports of at least three, which are bounded from above by horizontal partitions connecting them, on which the membrane of the central part of the coating is fixed, while the slopes of the coating are equipped with guides made in the form of a cable, the first ends of which fixed on the partitions, the new thing is that the membrane of the slope coating is radially divided into structurally independent sections, tightly connected to each other and elastic but on the sides, with the formation of a closed surface, in addition, the inner cavity of the membrane of each section is divided into two chambers, respectively, the upper and lower, flat inner perforated partition made of elastic, translucent material connected to the sides of the membrane of the section from the inside, while on the inner surface of the upper a reflective coating is applied to the chamber, in addition, an additional membrane of elastic, translucent material is introduced, which has an upper end along the perimeter of the herme it is elastic, permanently and permanently connected to the lower ends of the sections of the membrane of the slopes of the coating with the formation of through cavities through which the second ends of the guides of the slopes of the coating pass, while the second ends of the cables are fixed to the roof of the building module, in addition, the lower end of the additional membrane is sealed and detachable with the Inside a closed courtyard with wall fencing of a building complex. In addition: the lower end of the additional membrane is connected to the wall of the building complex facing the inside of the closed courtyard at a negative acute angle to the roof surface; the additional membrane is hollow and equipped with a nipple device for pumping air; the additional membrane is multi-sectional in the number of sections in the membrane of the slope of the coating, and the width of the upper end of the section of the additional membrane corresponds to the width of the lower end of the membrane of the section of the slope of the coating, while the additional membrane can be hollow, and each section of the additional membrane is equipped with a nipple device for pumping air.

Salient features of the claims: “An air-bearing coating for a closed courtyard formed by internal wall fencing of a building complex, made dome-shaped from an elastic translucent material, which is a hollow membrane inside, in addition, the coating consists of structurally independent central parts and slopes hermetically connected around the perimeter the upper ends coated with the central part, while the membranes of the slopes and the central part of the coating are made with the possibility of individual blowing of the internal cavity, in addition, the central part of the coating contains vertical supports of at least three, which are bounded from above by horizontal partitions connecting them, on which the membrane of the central part of the coating is fixed, while the slopes of the coating are equipped with guides made in the form of a cable, the first ends of which fixed on the partitions, ... ”- are an integral part of the declared building module and ensure its feasibility, and, therefore, ensure the achievement the claimed technical result.

The technical result is achieved as follows. The implementation of the membrane air support coating of translucent material provides illumination of the covered courtyard with sunlight. In the claimed airborne coating, the membrane of the slope coating, in contrast to the prototype, is divided radially into structurally independent sections interconnected hermetically and elastically on the sides, with the formation of a closed surface. In this case, the slope coating is a set of separate sections from an elastic translucent membrane, the number of which is determined by the size of the coating, which allows you to vary the size of the coating.

The introduction of an additional membrane made of elastic, translucent material provides the possibility of forming a closed translucent coating of the courtyard, and also provides the possibility of organizing natural convection of air inside the covered courtyard at any time of the year without resorting to transformation of the slope coating, which simplifies the design and assembly of the coating as a whole. This is due to the fact that the additional membrane with the upper end along the perimeter is hermetically, elastic and inseparably connected with the lower ends of the sections of the membrane of the slopes of the coating. Due to the implementation of the elastic membrane, it is possible to tightly connect the lower end of the additional membrane with the wall enclosures of the building complex facing the inside of the closed courtyard, which ensures the formation of an indoor enclosed space of the courtyard of the building complex. For the possibility of organizing natural air convection inside the covered courtyard at any time of the year, the connection of the additional membrane with the wall fences facing the enclosed courtyard is detachable, which increases the comfort of the building module. Moreover, since the second ends of the cables are fixed on the roof of the building module, this allows you to spatially install the lower ends of the slopes of the coating above the roof surface above the level of the internal wall enclosure. As a result, this makes it possible to connect the lower end of the additional membrane to the wall of the building complex facing the inside of the closed courtyard at a negative acute angle to the roof surface. Together, this prevents the additional membrane from falling asleep with snow, while maintaining the illumination of the courtyard and making it possible to organize natural air convection inside the covered courtyard at any time of the year, increasing comfort.

In addition, the additional membrane is hollow and equipped with a nipple device for pumping air. The elastic material of the additional membrane, in addition to the tightness of the joints, makes it possible to give it the desired shape and fill it with air, which is a coolant, which reduces energy consumption for heating the courtyard.

The implementation of the additional membrane is multi-sectional in the number of sections in the membrane of the slopes of the coating, and the width of the upper end of the sections of the additional membranes corresponds to the width of the lower end of the membrane section of the coating of the slopes, simplifies the connection of the additional membrane with the membrane of the slopes. In addition, the implementation of an additional multi-section membrane allows you to maximally approximate the shape of the courtyard to the connection line of the lower end of the additional membrane with wall fencing, which increases the tightness of the connection, ensures that heat and comfort inside the courtyard, and reduces energy consumption for heating the courtyard.

The implementation of the additional membrane is hollow, and each section of the additional membrane is equipped with a nipple device for pumping air, gives the additional membrane heat-insulating properties, which reduces heat loss through the coating, helps to preserve heat inside the closed indoor courtyard in the cold season and reduces energy consumption for heating the space of the courtyard.

Since the additional membrane is connected to the lower ends of the sections of the slope membrane with the formation of through cavities, through which the guides of the slopes of the coating — the cables — pass through the second ends, it is possible to fasten the slopes with the second ends on the roof of the building module, which allows you to change the slope of the slopes and, thus, vary the dimensions of the indoor the courtyard. The first ends of the cables are fixed on partitions connecting the vertical supports of the central part of the coating. As a result, in addition to the function of the guides, they perform the function of fixing the coating of the slopes, which simplifies the assembly and installation of the coating.

As a result, the proposed design of the slopes of the coating in combination with an additional membrane allows the complete assembly of the coating of the slopes of a closed courtyard on the ground and in assembled form to fix it in place, which simplifies installation of the coating as a whole. The sections of the slopes on the ground are interconnected by the sides, an additional membrane is attached to the lower ends of the sections. The second ends of the cables are passed through the through cavities formed when the additional membrane is connected to the lower ends of the ramp coating membrane. The first ends of the cables are attached to the partitions connecting the vertical supports of the central coating. For the second ends of the cables, the ramps are simultaneously lifted to the roof and secured.

The execution of the coating of skates with multisection, eliminating the need for transformation of the skates of the coating due to the introduction of an additional membrane, fixing the skates of the coating by means of ropes made it possible to eliminate the blowing operation when fixing the skates of the coating, which simplifies the assembly of the skates and, in turn, allows a wide variation of the indoor indoor area the yard. At the same time, due to the exclusion of the blowing operation when fixing the slopes of the coating, the energy consumption for installation of the coating is reduced.

Due to the presence of an individual blowing of the internal cavity of the sections of the membrane of the slope coating and the elasticity of the membrane material, the section, after turning on the blowing, in section is a biconvex lens, the convex surfaces of which, due to the fact that the membrane of the slope coating is radially divided into sections independently facing outward and inside the yard.

In addition, the inner cavity of the membrane of each section is divided into two chambers, respectively, the upper and lower, flat inner perforated partition of an elastic, translucent material, which is connected to the sides of the membrane of the section from the inside.

As a result, after the blowing is switched on, each section of the slopes is a two-chamber translucent package in which air serves as the coolant.

At the same time, a reflective coating is applied to the inner surface of the upper chamber. Since in the working state, due to the elasticity of the coating material, the section shape in cross section is a biconvex lens, the conditions for repeated reflection of the light beam from its internal surfaces, i.e. a solar collector is being formed. It is known that about 90% of infrared radiation in the sun's beam. As a result, the air temperature inside the upper chamber significantly exceeds the air temperature in the lower chamber and is higher than the temperature of the dome space. This contributes to the persistent preservation of the conditions for transferring the dew point to the outer surface of the slope membrane, eliminates the accumulation of moisture inside the upper chamber, reduces heat loss through the coating, reduces energy consumption for heating the courtyard.

In addition, since the chambers are formed by a perforated partition, during individual blowing, the heated air from the upper chamber enters the lower chamber and then into the space of the courtyard. As a result, an additional heat source is formed to heat the inner space of the closed courtyard. In other words, thanks to the proposed design of the slope section, the coating from the source of heat loss turns into an additional heat source, which increases comfort inside the yard and, at the same time, reduces energy consumption for heating the courtyard in the cold season. Moreover, in the summer season, the presence of a reflective coating inside the upper chamber of the slope sections softens the effect of sunlight, which increases the comfort of the space of the courtyard.

Thus, from the foregoing, it follows that the proposed air-bearing coating for a closed courtyard formed by the internal wall fencing of the building complex, when implemented, ensures the achievement of a technical result consisting in simplifying the installation of the coating, in expanding the possibility of increasing the indoor space of the inner closed courtyard, in reducing heat loss through coating; in reducing energy costs for installation of the coating, for heating the indoor courtyard in the cold season; in improving the comfort of the space of the courtyard Figure 1 shows a schematic fragment of the inventive air support coating for a closed courtyard formed by the internal wall fencing of the building complex in the installed state; figure 2 shows schematically a fragment of the claimed air support coating for a closed courtyard formed by the internal wall fencing of the building complex, a vertical section.

The claimed air support coating for a closed courtyard formed by the internal wall fencing of the building complex is made dome-shaped from an elastic translucent material, which is a hollow membrane inside. The coating consists of structurally independent central part 1 and slopes 2, hermetically connected along the perimeter of the upper ends with a coating of the central part 1. Membranes 3, 4 of the central part 1 and slopes 2 of the coating are made with the possibility of individual blowing of the internal cavity (not shown). The central part 1 of the coating contains vertical supports 5 of at least three, which are bounded from above by the horizontal partitions 6 connecting them, on which the membrane 4 of the central part 2 of the coating is fixed. The slopes 2 of the coating are provided with guides 7 made in the form of cables, the first ends of which are fixed on horizontal partitions, and the second ends are fixed on the roof 8 of the building complex. The membrane 3 of the slope coating 2 is divided radially into structurally independent sections 9, interconnected hermetically and elastically on the sides, with the formation of a closed surface. The inner cavity of the membrane of each section 9 is divided into two chambers 10 ₁ and 10 ₂ , respectively, the upper and lower, flat inner perforated partition 11 of elastic, translucent material connected to the sides of the membrane of section 8 from the inside. A reflective coating is applied to the inner surface of the upper chamber 9. An additional membrane 12 of elastic, translucent material has been introduced, which is sealed, elastic and inseparably connected to the lower ends of sections 8 of the ramp membrane 2 of the coating with the upper end face around the perimeter to form through cavities 13 through which the guiding slopes of the coating pass through the second ends — cables 7. First ends the cables 7 are connected to the partitions 6, and the second ends are fixed on the roof of the building module. Additional membrane 12 is multi-sectional. The number of sections 14 of the additional membrane 12 corresponds to the number of sections 8 in the membrane of the slopes 2 of the coating. The width of the upper end of the section 14 of the additional membrane 12 corresponds to the width of the lower end of the membrane of the section 8 of the slope coating 2. The additional membrane 12 is hollow, equipped with a nipple device for pumping air. The lower end of the additional membrane 12 is connected hermetically and detachably with the wall fences 15 of the building complex facing the inside of the closed courtyard at a negative angle to the roof surface. For inward opening (ventilation), you can use, for example, a circular rope connected to the lower end of the additional membrane and thrown through a block mounted on the inner wall fence 15 perpendicular to its side surface at a distance sufficient to fully open section 14 of the membrane 12.

The connection of the sides of the sections 8 of the slopes 2, sections 14 of the additional membrane 12 and the connection of the upper ends of the sections 14 of the additional membrane 12 with the lower ends of the sections 8 can in the simplest case be performed, for example, as follows. Along the connecting edges 16 of the sides and the corresponding ends of the sections 8 of the ramps 4 and sections 14 of the additional membrane 12, a self-locking tape, such as a pile lightning, is welded so that the mating surfaces are aligned towards each other (so that they engage on each other when aligned ) Combine overlap. Docking edges can be made differently, for example, along the perimeter of the side of the section, depending on the design. Outside, the seam is sealed with a self-adhesive tape. At the intersection of the lower ends and sides of the sections 8 with the corresponding sides of the sections 14 of the additional membrane, the connection is made with the formation of through tubular cavities for the passage of the cables 7, which after installation of the coating in place seal.

The assembly of the coating of the building complex is as follows. The membrane 3 of the central part 1 of the coating is permanently and hermetically fixed to the partitions 6 connecting the vertical supports 5. The membrane 4 of the slopes of the coating 2 is collected on the ground. Connect the sides of the section 8 of the membrane of the slope 2 and sections 14 of the additional membrane 12. Connect the upper ends of the sections 14 of the additional membrane 12 with the lower ends of the sections 8 of the membrane 4 of the slopes 2, forming through cavities 13 at the intersection of the lower ends and the sides of the sections 8 s the respective sides of the sections 14 of the additional membrane 12. The sections 14 of the additional membrane 12 are pumped with air. The second ends of the cables 7 are pulled through the formed through cavities 13. The first ends of the cables 7 are fastened to the partition 6 connecting the vertical supports 5 of the central coating 2. The slopes are lifted simultaneously for the second ends of the cables 7 (sectionally, depending on the size of the yard space to be covered) 2 s connected to them by an additional membrane 12 on the roof 8. Tighten the cables 7 at the second ends, which, then, are fixed on the roof 8 of the building complex. Then, from the side of the courtyard, the lower ends of the additional membrane 12 are pulled by the ropes with effort to the inner wall fence 15 until a tight connection is achieved. The ropes are fixed.

The final installation of the coating dome is carried out by blowing from the compressor of the common blowing means and by individual blowing of the internal cavities of sections 9 of the membrane 4 of the slope coating 2 and of the membrane 3 of the central part 1 of the coating.

Individual blowing means (not shown in FIG.) Contain compressors and dispensing hoses rigidly and hermetically connected to the internal cavity of the corresponding membrane. Individual blowing means are equipped with internal pressure sensors in the coating membranes.

The air support coating for a closed courtyard formed by the internal wall fencing of the construction complex, operates as follows. After individual blowing is switched on, each section 9 of the slopes is a two-chamber translucent package in which air performs the function of the heat carrier. Due to the fact that a reflective coating is applied to the inner surface of the upper chamber 10 ₁ , the passage of a light beam through it is delayed due to repeated reflection from its inner surfaces. As a result, the air temperature inside the upper chamber 10 ₁ significantly exceeds the air temperature in the lower chamber 10 ₂ and above the temperature of the dome space, which in the cold season contributes to the persistence of conditions for the transfer of the dew point to the outer surface of the membrane 4 of the slopes 2, eliminates the accumulation of moisture inside the upper chamber 10 ₁ , reduces heat loss through the coating of the courtyard, reduces energy consumption for heating the courtyard.

In addition, the heated air from the upper chamber 101 through the perforated partition 11 enters the lower chamber 10 g and then into the space of the courtyard, additionally heating the inner space of the closed courtyard. In this case, the coating from the source of heat loss turns into an additional source of heat, which increases the comfort of the inner space of the courtyard and reduces the energy consumption for heating the courtyard in the cold season.

In the winter season, a slight decrease in the illumination of the courtyard due to the use of a reflective coating inside the upper chamber 10x of the sections 9 of the slopes 2 is compensated by the fact that the central part 1 of the coating and the additional membrane 12 maintain maximum transparency, which does not reduce the comfort of the inner space of the courtyard. At the same time, in the summer season, the presence of a reflective coating inside the upper chamber 10 _{1 of the} sections 9 of the slopes 2, due to the multiple reflection of the sunbeam inside the upper chamber 10 _{1 of the} sections 9 of the membrane 4 of the slopes 2, softens the effect of sunlight, which increases the comfort of the space of the courtyard.

In the warm season, natural climatic conditions form inside the courtyard. To do this, disconnect the additional membrane 12 from the wall fence 15, attracting it with ropes from the side of the courtyard in the direction of the slopes 2 of the coating.

In addition, the detachable connection of the additional membrane 12 with the inner wall enclosure 15 provides fire safety of the courtyard, since in case of fire it allows you to quickly organize smoke removal.

Claims (5)

1. The air-bearing coating for a closed courtyard formed by the internal wall fencing of the building complex, made dome-shaped from an elastic translucent material, which is a hollow membrane inside, in addition, the coating consists of structurally independent central part and slopes, hermetically connected along the perimeter of the upper ends with coating the central part, while the membranes of the slopes and the central part of the coating are made with the possibility of individual blowing inside of the lower cavity, in addition, the central part of the coating contains vertical supports of at least three, which are bounded above by horizontal partitions connecting them, on which the membrane of the central part of the coating is fixed, while the slopes of the coating are equipped with guides made in the form of a cable, the first ends of which are fixed on the partitions characterized in that the membrane of the slope coating is divided radially into structurally independent sections, interconnected hermetically and elastically on the sides, with the formation a closed surface, in addition, the inner cavity of the membrane of each section is divided into two chambers, respectively, the upper and lower, a flat inner perforated partition made of an elastic, translucent material connected to the sides of the membrane of the section from the inside, while a reflective coating is applied to the inner surface of the upper chamber, in addition, an additional membrane of elastic, translucent material has been introduced, which is sealed, elastic and inseparably with the upper end along the perimeter on the lower ends of the sections of the membrane of the slopes of the coating with the formation of through cavities through which the second ends of the guides of the slopes of the coating pass, while the second ends of the cables are fixed to the roof of the building module, in addition, the lower end of the additional membrane is sealed and detachable with the walls facing the inside of the closed courtyard fences of the construction complex. 2. The air support coating according to claim 1, characterized in that the lower end of the additional membrane is connected to the wall of the building complex facing the inside of the closed courtyard at a negative acute angle to the roof surface. 3. The air support coating according to claim 1, characterized in that the additional membrane is hollow and is equipped with a nipple device for pumping air. 4. The air support coating according to claim 1, characterized in that the additional membrane is multi-sectional in the number of sections in the membrane of the coating slopes, the width of the upper end of the additional membrane section corresponding to the width of the lower end of the membrane section of the coating ramp. 5. The air support coating according to claim 4, characterized in that the additional membrane is hollow, with each section of the additional membrane provided with a nipple device for pumping air.

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