RU122682U1 - BUILDING COMPLEX - Google Patents

Abstract

1. A building complex consisting of interconnected buildings, peripherally closed to form an inner courtyard, which is equipped with an air-supported dome-shaped covering and a general means for blowing air, the outlet of which is directed to the inside of the closed courtyard, and the entrance is connected to the external atmosphere, while the covering is made of elastic translucent material, and the slopes of the covering around the perimeter rest on the wall fences of the building complex facing the inside of the closed yard and are hermetically connected to them, characterized in that the covering consists of, hermetically connected along the perimeter, structurally independent central part and slopes, which are made in in the form of elastic translucent membranes, hollow inside, and equipped with individual means for blowing air, moreover, the outlets of the individual means for blowing air are communicated with the inner cavity of the corresponding membrane, and the inputs are communicated with the space of the courtyard, in addition, on membranes membrane deflection sensors are installed, connected to the switch of the general means of air blowing, while the central part of the cover is fixed on vertical supports, and the roof slopes are detachably connected to the wall fences of the building complex facing the inside of the closed yard and are made transformable, in addition, the general air blowing device located at the bottom of the courtyard. 2. The construction complex according to claim 1, characterized in that the membrane deflection sensor is a strain gauge, which is connected to the switch of the general means for blowing air through resistor

Description

The utility model relates to the construction, namely the construction of residential buildings.

Famous residential complex "Poluy", including external and internal wall fences, ceilings, coatings and light openings of residential buildings, established with the formation of a closed inner space between them, with external facades, the coating of which is translucent of glass (Karateev L.P., Nikitin G .G., Suponitsky ZG “Translucent structures for the construction of facilities in the north”, L .: “Stroizdat”, 1078, p. 42).

The disadvantage of the Polui residential complex is that the glass coating has a large weight, which creates an additional load on the wall fencing, especially in the winter season when there is snow cover, and, as a result, limits the size of the free space of the courtyard. In addition, in the warm season, there are problems with maintaining a comfortable temperature and humidity in the enclosed space of the courtyard, which requires energy for heaters and fans, and also reduces the fire safety of the building complex due to the lack of an operational smoke removal system from the courtyard.

The construction complex is known, which is a two or more storey peripherally enclosed building, forming in its middle part a courtyard with a domed cover, the ramps of which are inflatable, with the dome resting on the roof of the building. The central part of the dome cover is rigid, opaque and rests on a pipe fixed in the center of the courtyard. The slopes of the dome are hermetically connected to the central part of the dome and are translucent. The diameter of the hard section of the roof and the height above the ground are made from the condition of the impossibility of forming domes of elasticity on the slopes of the slopes, delaying the flow of precipitation during emergency discharge of excess pressure inside the elastic coating (RF Patent No. 2373358, E04H 14/00, 06/20/2009).

A disadvantage of the known building complex is that the retention of the elastic coating is ensured by the constant maintenance of excess pressure inside the inflatable structure of the slopes of the coating, ensuring both the retention of its own weight and the possibility of additional loads, as well as due to precipitation, especially in the winter season , and wind loads. The need to constantly maintain excess pressure inside the inflatable coating, taking into account the possibility of an increase in the load on the coating, leads to unproductive energy costs, and also imposes restrictions on the size of the space of the courtyard.

The slopes of the covering of the courtyard are made non-transformable (transformation - transformation, changing the type, shape, essential properties - http://tolkslovar.ru/t4305html), which does not allow to remove the coating of the slopes in the warm season, does not allow to create natural conditions in the yard, reduces insolation of the yard and comfortable conditions for users. As a result, maintaining a comfortable climate in the courtyard during the warmer months requires additional energy costs for air conditioning and ventilation. In addition, due to the lack of an operational smoke removal system from the courtyard, the fire safety of the building complex is reduced

Closest to the proposed one is a building complex, which is an air-bearing structure consisting of interconnected buildings with the formation of a closed courtyard, which is covered with a domed translucent roof made of elastic fiberglass fabric (US, No. 4,696,133, F04B 1/342, NKI US 52/80 ; 52/6; 52/2; 52 / 236.3, published on September 29, 1087). The dome is mounted on top of the perimeter of the inner wall. To keep the domed shape of the coating on the roof of the building directly next to the coating, supply fans are installed that organize air blowing directly under the coating material. For emergency situations, autonomous electric generators are provided to ensure the operability of the fans. In addition, in emergency situations, the coating can be prevented from falling into the courtyard by mechanical tension by means of ropes fixed directly above the perimeter of the internal wall of the building, or by hooking the edges of the slopes of the coating with brackets with hooks, also fixed on the walls of the buildings facing the courtyard.

The well-known building complex solves the problem of optimizing heat losses through the dome of the coating and the internal wall enclosure of the complex for a given temperature difference in order to reduce energy consumption to maintain atmospheric pressure inside the building and fenced space both to maintain the dome and to maintain comfortable climatic conditions for people and plants.

A disadvantage of the known building complex is that it achieves a reduction in energy consumption for maintaining the dome and comfortable conditions inside the indoor courtyard only at a certain predetermined temperature difference between the external and internal space of the indoor courtyard, i.e. the concrete construction of the building complex does not reduce energy costs for maintaining the dome and comfortable conditions inside the covered courtyard for any time of the year. In addition, in this case, the energy consumption remains the same for the entire temperature range, which also reduces the efficiency of energy consumption. At the same time, the reduction in energy consumption is achieved by choosing the surface areas of the inner wall enclosure and the elastic coating, their thickness and thermal conductivity coefficients, which complicates the implementation of the well-known building complex, and also limits the size of the inner space of the closed indoor courtyard.

In addition, in the well-known construction complex, the retention of the own weight of the coating and external loads on the coating caused by precipitation, especially in the winter season, as well as wind loads, is ensured only by creating an air support that keeps the domed shape of the coating. In the winter season, the load on the inner wall of the building increases in direct proportion to the increase in snow load on the coating. Exceeding the load on the coating leads to the fact that the inflatable coating bends, which can lead to an emergency. Given the foregoing, in a known solution create excess pressure inside the yard, designed for the maximum load on the coating, which is constantly maintained, regardless of the actual load on the coating. The need to constantly maintain maximum overpressure under the dome, regardless of the external load on the coating, increases the energy consumption for maintaining the dome, as a result of which limits the size of the space of the indoor courtyard. Moreover, in the well-known construction complex, the dome cover is not transformed. As a result, in the warm season, the temperature inside the courtyard rises above the permissible level necessary for a comfortable stay of a person and plants, which requires an air conditioning and ventilation system to maintain a comfortable environment for plants and people, and, consequently, increases energy consumption and, as a result, imposes a restriction on the size of the inner space of the yard.

In addition, the inability to transform the dome cover does not allow removing it in case of emergency, in particular in case of fire. As a result, there is no operational smoke removal system from the courtyard, which reduces the fire safety of the construction complex.

The proposed utility model solves the problem of creating a building complex, the implementation of which allows to achieve a technical result, which consists in reducing energy consumption for maintaining an air-supporting structure and creating comfortable conditions for people and plants inside the closed courtyard at any time of the year, in the possibility of increasing the size of the inner closed courtyard, in increase fire safety.

The essence of the claimed utility model consists in the fact that in a building complex consisting of interconnected buildings, peripherally closed to form an inner courtyard, which is equipped with an air-bearing dome-shaped coating and a common means of blowing air, the outlet of which is directed into the inner courtyard, and the entrance is connected to external atmosphere, while the coating is made of elastic translucent material, and the slopes of the coating around the perimeter are based on the wall fences facing the inside of the closed courtyard of the complex and hermetically connected to them, it is new that the coating consists of structurally independent, central parts and slopes that are hermetically connected together around the perimeter, which are made in the form of elastic translucent membranes, hollow inside and equipped with individual means of blowing air, the outputs of the individual means of blowing air are communicated with the internal cavity of the corresponding membrane, and the inputs are communicated with the space of the courtyard, in addition, on the membrane covering the courtyard the deflection sensors of the membrane are connected to the switch of the common means of blowing air, while the central part of the coating is mounted on vertical supports, and the slopes of the coating are detachably connected to the wall of the building complex facing the inside of the closed courtyard and are transformable, in addition, the common means of blowing air are located in the lower parts of the courtyard. In addition: the membrane deflection sensor is a strain gauge that is connected to a switch of a common air blowing means through a resistor bridge, one of the resistors of which is a strain gauge, and the number of bridges corresponds to the number of strain gauges, and a constant voltage is applied to one of the diagonals of each bridge, and the second diagonal includes a load resistor connected in parallel with the input of the corresponding differential amplifier, the outputs of which are connected to the inputs of the OR circuit, to the output of which a relay winding connected through open contacts of which are connected to the compressor supply voltage; the central part of the coating is fixed to at least four vertical supports; the vertical supports of the central part of the coating are connected by partitions on which the frame of the first vertical rigid translucent fence is fixed along the perimeter of the central part of the coating, hermetically connected along the perimeter by the respective surfaces with the edges of the central part and with the upper ends of the slopes of the coating; on the walls of the building complex, facing the closed courtyard, around the perimeter, the frame of the second vertical rigid translucent fence is tightly fixed, hermetically connected along the perimeter of the corresponding surface with the lower ends of the slopes of the coating; the slopes of the coating of the inner enclosed space are provided with guides, one end of which is fixed to the inner wall fence, and the other is attached to the partitions connecting the vertical supports of the central part; slopes of the coating are fixed on the rails with the possibility of pulling them to the central part of the coating; guides of the slopes of the coating of the inner enclosed space are made of light metal or high-strength plastic material; the common blowing means is connected in series with the air heater and is equipped with an electromechanical temperature sensor connected to the air heater switch; a common blowing facility is located in the courtyard at the zero mark of the construction complex; the input of the common blowing means is connected to the external atmosphere through the ventilation shaft in the construction complex; individual blowing means are equipped with internal pressure sensors in the coating membranes.

The technical result is achieved as follows.

The essential features of the utility model formula are: “A building complex consisting of interconnected buildings, peripherally closed to form an inner courtyard, which is equipped with an air-bearing dome-shaped coating and a common air blowing means, the outlet of which is directed into the enclosed courtyard, and the entrance is connected to the external atmosphere, the coating is made of elastic translucent material, and the slopes of the coating along the perimeter are based on the wall fences facing the inside of the closed courtyard th complex and sealingly connected to them, ... "are an integral part of the claimed construction complex and provide its feasibility, and therefore, provide the achievement of the claimed technical result.

The hermetic connection of the upper ends of the ramps covering the courtyard with the central part of the coating and the hermetic connection of the lower ends of the ramps with the wall fences facing the inside of the courtyard together provide a continuous covering of the inner courtyard and isolation of the inner space of the courtyard from the external environment. As a result, load-bearing external wall fences facing the courtyard are isolated from the external environment, which reduces heat loss in residential premises and, consequently, energy consumption and at the same time creates comfortable conditions for people and plants inside a closed courtyard at any time of the year.

Performing translucent coating of the courtyard ensures insolation of the inner space of the courtyard in accordance with the standards. In addition, the insolation of the inner space of a closed courtyard is improved by vertical rigid translucent fencing, fixed along the perimeter of the central part of the coating and along the perimeter of the wall fencing of the buildings of buildings facing inward. In this case, the frame of the first rigid vertical translucent fence is fixed on the partitions connecting the vertical supports of the central part of the coating and hermetically connected along the perimeter with the corresponding surfaces with the edges of the central part and with the upper ends of the slopes of the coating, which ensures the tightness of the connection of the slopes and the central part of the coating and forms the continuity of the coating. As a result, energy consumption for lighting the courtyard is reduced and at the same time comfortable conditions for people and plants inside the enclosed courtyard are provided at any time of the year.

The execution of the central part of the coating and slopes is inflatable, in the form of elastic translucent membranes, hollow inside and equipped with individual blowing means, the outputs of which are communicated with the internal cavity of the corresponding membrane, and the entrance is communicated with the space of the courtyard, provides conditions for giving the required shape to the coating of the yard and further holding it in the desired position by creating a constant overpressure inside the membranes controlled by pressure sensors.

The presence of a common means of blowing air, the outlet of which is directed inside the enclosed courtyard, and the inlet is connected to the external atmosphere, makes it possible to create excessive atmospheric pressure inside the enclosed space of the courtyard, which provides support in the required position for the entire elastic covering of the courtyard as a whole. In addition, the presence of a common blowing means makes it possible to use individual blowing means, since it allows you to compensate for the likely change in pressure inside the courtyard due to air intake by individual blowing means from the inner space of the closed courtyard, while maintaining the pressure inside the courtyard favorable to humans.

From the foregoing, it follows that in the claimed building complex, a combination of two methods of maintaining the dome is used: the creation of a constant excess pressure inside the hollow membranes of the slopes and the central part of the coating and the creation of excess pressure in the space under the dome, i.e. the coating of the claimed building complex is a combination of air support and inflatable coatings with their own blowing means. Thanks to this, the introduction of membrane deflection sensors installed on the yard covering membranes and connected to the switch of the common air blowing means made it possible to assign an additional function to the common blowing means, namely:

prevention of deflection of the coating membranes inside the courtyard when the external load increases on them, by regulating the amount of excess pressure inside the closed courtyard depending on the change in the external load on the coating, not allowing the deflection of the coating membranes. The ability to organize overpressure inside a closed courtyard based on the actual load on the elastic coating of the courtyard reduces the energy consumption for maintaining the dome at any time of the year.

In addition, it became possible to change the bearing capacity of the elastic coating of the inner enclosed courtyard in accordance with the changing load (atmospheric precipitation, especially snowfall, wind load). As a result, in the claimed building complex, an increase in the load on the elastic coating does not lead to an increase in the load on the internal wall fencing, exceeding the permissible building norms of the load on the wall fencing, which is especially important for areas with snowy winters.

It is known that the construction norm of the snow load that any covering of a building structure must withstand is set equal to 330 kg / m ² for the Ural region. The calculation shows that in order to maintain such a snow load on the inflatable pavement, it is necessary to provide an excess pressure of not less than 0.033 kg / m ² inside the enclosed courtyard, which corresponds to 0.033 atm. (in a square meter of 10000 cm ² , therefore, 0.033 kg × 10000 = 330 kg). Thus, taking into account the above requirements, the maximum overpressure that needs to be created in the winter season inside the enclosed courtyard, the coating of which is made in accordance with the declared one, is 0.033 atmospheres, which is insensitive to humans and does not impair the comfort of the climatic conditions of the inner enclosed courtyard.

The ability to change the bearing capacity of the elastic coating of the inner enclosed courtyard in accordance with the load changing on it, while not exceeding the allowable load standards on wall fencing, theoretically, allows you to vary within wide limits the dimensions of the inner enclosed courtyard.

In the claimed building complex, the common blowing means is located on the surface of the courtyard at the zero mark of the residential complex, while the input of the common blowing means is connected to the outside atmosphere through the ventilation shaft, as a result of which the general blowing air is warmer than the outside. In addition, the common blowing means is connected in series with the air heater and is equipped with an electromechanical sensor connected to the air heater switch, which allows the air inside the enclosed space to be heated simultaneously with the organization of excess pressure in the cold season. In addition, the coating membranes, after filling them with air, work on the principle of a double-glazed window, i.e. from the side of the courtyard under the membrane there is always a plus temperature close to the temperature of the air in the courtyard. As a result, the claimed complex reduces heat loss in residential premises, eliminates the possibility of condensation on the inner surface of the coating and draining it to the inner wall enclosure. As a result, energy consumption for maintaining comfortable conditions inside a closed courtyard is reduced and comfortable conditions for a person and plants are provided inside a closed courtyard at any time of the year.

The coating of the inner enclosed courtyard is inflatable and, in addition, is supported by controlled excess atmospheric pressure created inside the courtyard in accordance with the changing external load on the elastic coating. As a result, the coating of the courtyard practically does not exert pressure on the inner wall of the building complex. The implementation of the guide slopes of the coating of light metal or high-strength plastic material, for example, polyurethane, does not lead to a significant increase in the load on the inner wall enclosure. Placing a common blowing means not on the roof, as in the prototype, but on the surface of the courtyard at the zero mark of the residential complex, reduces the load on the inner wall fence, compared with the prototype. Together, all of the above allows you to vary the size of the courtyard over a wide range without exceeding the permissible load standards on wall fencing.

Coverage of the courtyard consists of structurally independent central parts and ramps with individual blowing means, which are tightly interconnected around the perimeter. This makes the central part of the coating and slopes structurally independent of each other, which allows you to use them autonomously and make the slopes of the cover transformable. For this, the slopes of the coating are detachably connected to the wall enclosures of the residential complex facing the inside of the enclosed courtyard and are fixed on the rails with the possibility of pulling them to the central part of the coating. This allows you to use only the central coating during the warmer months, providing natural environmental conditions in the courtyard: natural insolation and natural air movement, which provides comfortable living conditions for users and also reduces energy costs for maintaining the dome and comfortable conditions inside the enclosed courtyard.

In addition, the ability to perform transformable slopes allows you to quickly remove them, providing the conditions for prompt smoke removal in a closed courtyard, which increases the fire safety of the complex. Moreover, the presence of guides, fixed in accordance with the claims, and fixing the central part of the coating on vertical supports, exclude the possibility of the elastic coating falling inside the yard in emergency situations when there is insufficient pressure both inside the coating membranes and inside the yard space, which increases safety residential complex.

For example, strain gauges that convert the mechanical deformation of the membrane into an electrical signal (http://www.tenzo-pribor.ru/production/tenzo/1/; http: //www.tenzo-pribor. com / production / tenzo / tenzodatchiki /). The strain gauge is a resistor whose resistance changes with deformation. It is glued to the surface of the tested part, so that it deforms with it.

Membrane deflection sensors - strain gauges can be connected to the switch of the common air blowing means via a conventional circuit through a resistor bridge, one of the resistors of which is a strain gauge, the number of bridges corresponding to the number of strain gauges, and a constant voltage is applied to one of the diagonals of each bridge, and the second the diagonal includes a load resistor, from which the control voltage is removed.

To amplify the control signal from the strain gauge, a differential amplifier is introduced. In this case, the diagonal of the bridge with the load resistor is connected in parallel with the input of the corresponding differential amplifier. To control the compressor circuit breaker by several load cells mounted on membranes from different sides of the building complex, an OR circuit is introduced, while the output of the load cells is connected to the inputs of the OR circuit. A relay is used as a switch of the compressor electric network, the winding of which is connected to the output of the OR circuit. Opening the compressor electrical network is carried out by relay contacts. To do this, the supply voltage from the mains to the compressor is connected via open relay contacts.

Thus, when the membranes are deformed due to a change in the external load, the membrane deflection sensor, controlling the connection of the common blowing compressor to the electric network, changes the duration of the compressor of the common blowing compressor until the deflection is eliminated. As a result, the magnitude of the overpressure varies in proportion to the magnitude of the external load on the ramp membranes and the central part of the coating, in particular, in accordance with the change in the snow and wind load on the membranes. At the same time, the compressor of the common blowing means works to change the actual load on the elastic coating at any time of the year. The presence of an individual blowing means in the central part of the elastic coating, as well as the possibility of transforming the slopes of the coating in the warm season allows you to disable the common blowing means and the individual means of blowing the slopes of the coating. The execution of the coating, in the form of elastic translucent membranes, hollow inside and filled with air, working on the principle of a double-glazed window, reduces heat loss through the coating. Additional illumination of the inner enclosed space through vertical rigid translucent fencing around the perimeter of the inner wall fencing and around the perimeter of the central part of the coating improves the insolation of the inner enclosed space of the covered courtyard. As a result, energy costs are reduced both for maintaining the dome of the coating, and for creating comfortable conditions inside a closed indoor courtyard for people and plants at any time of the year. The possibility of rapid smoke removal from the enclosed space of the courtyard increases fire safety.

From the above it follows that the claimed building complex during implementation ensures the achievement of a technical result, which consists in reducing energy consumption for maintaining the air support structure and comfortable conditions for people and plants inside the closed courtyard at any time of the year, in the possibility of increasing the size of the inner closed courtyard, and increasing fire safety building.

N figure 1 shows the construction complex, a vertical section (buildings in the background are not shown); figure 2 - building complex in plan, horizontal section, with an example of filling the inner enclosed courtyard; figure 3 - construction complex, a horizontal section at zero level; figure 4 - connection diagram of the sensor deflection of the membrane to the switch of the compressor of the common means of blowing.

The claimed building complex contains interconnected buildings 1, peripherally closed to form a courtyard 2, which is equipped with an air-bearing dome-shaped coating 3 and a common air blowing means 4, located in the lower part of the courtyard 2 on the surface at the zero mark of the building complex.

The output of the common blowing means 4 is directed inside the enclosed courtyard 2, and the entrance is connected to the external atmosphere through the ventilation shaft in the construction complex. The common blowing means 4 is connected in series with the heater and is equipped with an electromechanical temperature sensor connected to the heater switch (not shown in FIG. 1). The common means of blowing air 4 may consist, for example, of a compressor, the output of which is directed into the inside of the closed courtyard, and the input of the common means of blowing is connected to the outside atmosphere through the ventilation shaft in the building complex, which ensures the entry of warmer air into the closed courtyard with the outside. As a result, it is possible to create a comfortable temperature for a person in the inner space of a closed courtyard.

Coating 3 is made of elastic translucent material. The coating 3 consists of, structurally independent, perimeter-sealed, central part 5 and slopes 6. The central 5 part of the coating and slopes 6 are made in the form of elastic translucent membranes, hollow inside and equipped with individual means of blowing air 7, 8, respectively. The outputs of the individual means of blowing air 7, 8 are connected with the inner cavity of the corresponding membrane 5, 6, and the inputs are communicated with the space of the courtyard 2. The slopes 6 of the coating 3 around the perimeter rest on the wall enclosures 9 of the building complex facing the inside of the closed courtyard 2 and are tightly connected to them and detachable. The slopes 6 of the coating 3 are made transformable. The central part of the coating 3 is fixed to at least four vertical supports 10, which are connected by horizontal partitions 11.

On the partitions 11 around the perimeter of the central part of the coating, the frame of the first 12 vertical rigid translucent fencing is fixed, the translucent elements of which are made of glass. The frame of the translucent fence 12 is hermetically connected along the perimeter with the corresponding surfaces with the edges of the central part 5 and with the upper ends of the slopes 6 of the coating 3. On the wall fences 9 of the building complex facing the closed courtyard 2, the frame of the second 13 vertical rigid translucent fence is hermetically fixed . The frame of the translucent fence 13 is hermetically connected along the perimeter of the corresponding surface with the lower ends of the slopes 6 of the coating 3.

The ramps 6 are provided with guides 14, one end of which is fixed to the inner wall fence 9, and the other is attached to the partitions 11 connecting the vertical supports 10 of the central part 5. The guides 14 of the ramps 6 are made of light metal, for example, in the form of a metal cable, or high-strength plastic material, for example, polyurethane. Slopes 6 are fixed on the guides 14 with the possibility of their transformation by tightening to the Central part 5 of the coating 3.

To make slopes 6 of cover 3 transformable, in the simplest version, it is possible to use a system of blocks 16, 17 mounted on an inner wall fence 2 at the point of attachment of the guide 14 and on the partition 11 of the central part 5 of the coating 3. A circular rope rigidly connected to the lower end of the ramp 6. The number of blocks may correspond to the number of guides 14.

Individual blowing means 7 and 8 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 (not shown in Fig. 1).

On the membranes of the central part 5 and slopes 6 of the coating 3 of the yard 2, deflection sensors 15 of the membranes are installed, connected to the switch of the common air blowing means (the connection of the membranes with the blowing means is not shown in Fig. 1), which ensures the adjustment of the overpressure inside the yard in accordance with the changing load on the elastic coating.

As a deflection sensor 15 of the membrane can be used, for example, strain gauges that convert the mechanical deformation of the membrane into an electrical signal (http://www.tenzo-pribor.ru/production/tenzo/1/; http: //www.tenzo-pribor .ru / production / tenzo / tenzodatchiki /). When the membranes are deformed due to a change in the external load, the strain gauge changes its resistance and generates a control signal for connecting the compressor of the common blowing means to the electric network, changing the duration of the compressor of the common blowing means 4 until the deflection is eliminated. As a result, the magnitude of the overpressure changes in proportion to the magnitude of the external load on the membranes of the ramps 6 and the central part 5 of the coating 3, in particular, in accordance with the change in the snow and wind loads on the membranes.

For example, foil strain gauges, for example, ZEMIC, can be used, with increased elasticity, which are glued to a controlled surface (http: //zemic.m/catalog/.)

The deflection sensors of the membranes 15 can be connected, for example, to a switch of a common air blowing means according to the generally accepted scheme through a resistor bridge 18, one of the resistors of which is a strain gauge 15. The number of bridges 18 corresponds to the number of strain gauges 15. A constant voltage is applied to one of the diagonals of each bridge, and a load resistor 19 is included in the second diagonal. The output of the load resistor 19 is connected in parallel with the input of the corresponding differential amplifier 20, the outputs of which are connected to the inputs of the OR circuit 21, the relay winding 22 is connected to the output. The closed contacts of the relay 22 are included in the compressor power supply circuit of the common blower 4.

The circuit is triggered when the strain gauge 15 mounted on the membrane bends inward, which captures the change in the external load on the membrane. Changing the resistance of the tezzotachik 15 leads to an imbalance of the bridge 18, as a result of which a control signal is formed on the load resistance 19. From the output of the differential amplifier 20, the amplified control signal is fed to the OR circuit 20, which is triggered by the presence of at least one input signal and connects the relay coil 22, which is used as an example of a common blower as a switch. In the initial state, the relay contacts, excluding the power supply to the compressor of the common blowing means 4, are open. Connecting the coil of relay 22 leads to the closure of the compressor electrical network for a time until the overpressure reached inside the courtyard returns the coating to its original state. In this case, the strain gauge will also bend to its original state, which will lead to balancing of the bridge, and, therefore, reduce the voltage across the load resistor to zero. This is hi to turning off the relay winding and, therefore, to opening it with the contacts of the power supply circuit of the compressor of the common blowing means.

After fixing the elastic coating on the building complex, first, using individual blowing means 7, 8, overpressure is created in the membranes of the central part of the coating and slopes. The final installation of the coating dome to its initial state is carried out by blowing directly from the compressor of the common blowing means, bypassing the network connection scheme through the load cells. After that, the power of the compressor of the common blowing means is turned off and the power supply circuit of the compressor of the common blowing means is connected through the open contacts of the relay 22.

The buildings, in the exemplary embodiment, are residential detached buildings with individual exits to the street and into the enclosed courtyard 2. In the courtyard there is an emergency exit 23 that does not violate the enclosed space of the courtyard.

In the cold season, the coating 3 of the courtyard 2 consists of hermetically connected central part 5 and slopes 6. The required form of the coating is maintained by overpressure inside the membranes of the coating 3 and adjustable overpressure inside the enclosed space of the courtyard 2, depending on the changing external load on the membrane 3 At the same time, a common means of air blowing maintains a temperature comfortable for a person inside the courtyard, thereby reducing heat loss through internal wall fencing.

In the warmer months, natural climatic conditions form inside courtyard 2. To do this, remove the coating of the slopes 6, tightening the membrane of the coating of the slopes 6 along the guides 14 to the vertical supports 10 of the central part of the coating 5. Pre-disconnect the general 4 and individual means of blowing slopes 6. The individual blowing of the membrane of the central part 5 of the coating 3 is saved. As a result, the warm season in the middle of courtyard 2 forms a common recreation area 24, protected from precipitation, which increases the comfort of the building complex. Individual recreation areas 25 can be provided in the courtyard. When connecting residential buildings into a closed courtyard, common buildings can be made in the corners of the connections, for example, a shop, laundry, hairdresser, and kindergarten.

Claims (12)

1. A construction complex consisting of interconnected buildings, peripherally closed to form an inner courtyard, which is equipped with an air-bearing dome-shaped coating and a common air blowing means, the outlet of which is directed inside the enclosed courtyard, and the entrance is connected to the external atmosphere, while the coating is made of elastic translucent material, and the slopes of the coating around the perimeter are based on the wall enclosures of the building complex facing the inside of the closed courtyard and are hermetically connected to them, ex which consists in the fact that the coating consists of structurally independent central parts and slopes that are tightly interconnected around the perimeter, which are made in the form of elastic translucent membranes, hollow inside, and equipped with individual means of blowing air, and the outputs of individual blowing means are communicated from the inside the cavity of the corresponding membrane, and the entrances are connected with the space of the courtyard, in addition, membrane deflection sensors are installed on the membrane covering the yard, connected to the elem total air blowing means, wherein the central portion of the coating is fixed to vertical supports, and slopes coating joined detachably with inwardly closed yard building complex wall barriers made transformable and furthermore, the total air blowing means arranged in the lower part of the inner court. 2. The construction complex according to claim 1, characterized in that the membrane deflection sensor is a strain gauge that is connected to a switch of a common air blowing means through a resistor bridge, one of the resistors of which is a strain gauge, and the number of bridges corresponds to the number of strain gauges, with one a constant voltage is applied from the diagonals of each bridge, and a load resistor connected in parallel to the input of the corresponding differential amplifier, the outputs of which are connected, is included in the second diagonal are connected to the inputs of the OR circuit, to the output of which a relay coil is connected, through the open contacts of which a supply voltage is connected to the compressor. 3. The construction complex according to claim 1, characterized in that the central part of the coating is fixed to at least four vertical supports. 4. The construction complex according to claim 1, characterized in that the vertical supports of the central part of the coating are connected by partitions on which the frame of the first vertical rigid translucent fence is fixed along the perimeter of the central part of the coating, hermetically connected along the perimeter by respective surfaces with the edges of the central part and with the upper ends stingrays cover. 5. The construction complex according to claim 1, characterized in that on the wall fences of the construction complex facing the enclosed courtyard, the frame of the second vertical rigid translucent fence is tightly fixed around the perimeter, hermetically connected along the perimeter of the corresponding surface with the lower ends of the slopes of the coating. 6. The construction complex according to claim 1, characterized in that the slopes of the coating of the inner enclosed space are provided with guides, one end of which is fixed to the inner wall fence, and the other is attached to the partitions connecting the vertical supports of the central part. 7. The construction complex according to claim 4, characterized in that the slopes of the coating are fixed on rails with the possibility of pulling them together to the central part of the coating. 8. The construction complex according to claim 4, characterized in that the slope guides of the coating of the inner enclosed space are made of light metal or high-strength plastic material. 9. The building complex according to claim 1, characterized in that the common blowing means is connected in series with the air heater and is equipped with an electromechanical temperature sensor connected to the air heater switch. 10. The construction complex according to claim 1, characterized in that the common blowing means is located in the courtyard at the zero mark of the construction complex. 11. The construction complex according to claim 1, characterized in that the input of the common blowing means is connected to the external atmosphere through the ventilation shaft in the construction complex. 12. The building complex according to claim 1, characterized in that the individual blowing means are equipped with internal pressure sensors in the coating membranes.