RU2737590C1 - Roof with translucent coating for closed courtyard, formed by inner wall enclosures of building complex - Google Patents

Abstract

FIELD: construction.SUBSTANCE: invention relates to a roof with a translucent coating for an internal closed courtyard limited by internal wall enclosures. Roof has the shape of a surface of a body of revolution formed when a flat figure is rotated and bounded by a curve around a vertical axis - an axis of symmetry of an internal courtyard lying with a generatrix in one plane but not crossing it. Forming figure is limited on the side of the inner courtyard by a virtual horizontal plane at the level of the wall enclosures facing inside the courtyard. Peripheral and directed inside courtyard edges of surface of rotation body form peripheral and inner edges of roof slopes with slope from 40 to 90° relative to horizontal level. Roof inner slopes are continued with formation of funnel with preservation of slope in range from 40 to 90°, resting on the soil surface in the inner courtyard centre and tightly connected to the water collector. Inner slopes can rest on hollow central support.EFFECT: technical result is improved illumination of inner yard during winter season due to self-cleaning of translucent coating from snow.11 cl, 7 dwg

Description

The invention relates to the construction of residential buildings and can be used for the construction of a roof with a translucent coating for a closed inner courtyard, bounded by internal wall fences of a building complex, with the possibility of self-cleaning of the translucent roof covering from snow to improve the illumination of the inner space of the courtyard in the winter season.

In areas with snowy winters, one of the main problems in organizing a roof with a translucent coating for a closed courtyard, bounded by the internal wall fences of the building complex, is a decrease in the illumination of the inner space of the courtyard due to the adhesion of snow on the outer surface of the translucent coating.

Known building module, in which residential buildings are installed with the formation between them of an open closed space, the roof of which is made with a translucent coating. The roof has a central glass skylight and inclined glazing, which is connected by a slope to the roofs of residential buildings (USSR, Inventor's Certificate No. 1784728, E04N 1/00, 12/30/92.)

In the known roof structure, it is theoretically possible to organize the spontaneous sliding of snow onto the roofs of residential premises, increasing the angle of the inclined glazing. In this case, it is obvious, since the shape of the roof under consideration is close to the shape of a pyramid, the optimal slope angle will be 45 °. However, in the structure under consideration, any increase in the slope angle of the roof increases the vertical size of the roof, which significantly makes the roof structure of the courtyard heavier. In addition, with an increase in the slope of the roof, the lateral wind load also increases.

It is more rational to make a roof for a closed courtyard in the form of a dome using a translucent material.

Known roof for a closed courtyard formed by internal wall fences of a building complex, made of elastic translucent material. The roof consists of structurally independent central part, slopes and an additional membrane hermetically connected along the perimeter, and an additional membrane, hermetically connected to each other to form a dome in the form of a sphere segment. The lower ends of the roof slopes along the perimeter are connected to the internal wall fences by means of an additional membrane, the lower end of which along the perimeter is hermetically connected to the wall fences of the building complex facing the inside of the closed courtyard at a negative acute angle to the roof surface, and the upper end is tightly connected along the perimeter with the lower edges of the slopes roofs. The roof is equipped with central vertical supports and ramp guides in the form of cables. (RF, patent No. 2637818, E04H 15/20, 07.12.2017).

In a known roof, an improvement in the illumination of the courtyard in a snowy winter is achieved by introducing a source of additional illumination in the form of a membrane of light-permeable material, hermetically connected along the perimeter with the lower edges of the roof slopes and fixed at a negative acute angle to the surfaces of the roofs of the buildings of the complex, which reduces the likelihood of it falling asleep with snow. However, with abundant snowfall, snow accumulates on the main translucent surface of the dome, which sharply reduces the illumination of the courtyard and, in addition, does not exclude the possibility of falling asleep with snow and a source of additional lighting. In this case, the central vertical supports and guides for the slopes in the form of cables that pass through special through cavities in the additional membrane and are rigidly fixed at the first ends on the roof of the building module, and are rigidly connected with the second ends to the central supports of the roof, worsen the aesthetic appearance of the courtyard.

It is known, the closest to the proposed, the implementation of the roof for a closed courtyard formed by the internal wall fences of the building complex, from an elastic translucent material. The roof consists of a perimeter-tightly interconnected, structurally independent, central part and slopes, hermetically interconnected to form a dome in the form of a sphere segment. The lower ends of the roof slopes along the perimeter rest on the wall fences of the building complex facing the inside of the closed yard and are hermetically connected to them by means of additional rigid vertical translucent fences. The upper ends of the slopes are hermetically connected to the central part of the roof also by means of additional rigid vertical translucent fences. The roof is equipped with four central vertical supports and ramps. The guides are rigidly connected to the central supports of the roof and internal wall fences (RF, patent No. 2503780, E04B 1/00, E04H 15/20, 01/10/2014).

In a known roof, an improvement in the illumination of the courtyard in a snowy winter is achieved by additional rigid vertical translucent fences installed on the wall fences of the building complex facing the closed courtyard, as well as between the edges of the central part of the roof and the upper ends of the roof slopes. Since the fences are installed vertically, the snow does not linger on them. However, with abundant snowfall, snow accumulates on the main translucent surface of the dome, which sharply reduces the illumination of the courtyard and, in addition, does not exclude the possibility of falling asleep with snow and rigid vertical fences. In addition, the introduction of rigid vertical translucent fences into the roof increases the total weight of the courtyard coating, and, therefore, increases the load on the internal wall fences of the buildings of the building complex. At the same time, the covering is equipped with four central supports and ramp guides rigidly connected to the central supports of the covering and internal wall fences, which impairs the aesthetic appearance of the indoor courtyard of the complex.

In addition, a common disadvantage of the above-described dome-shaped roof structures with a light-transmitting coating is that, in order to maintain light transmittance in winter, measures must be taken to clean the outer surface of the dome-shaped part of the roof from snow. In theory, the problem of self-cleaning of the courtyard cover from snow can be solved, for example, by increasing the slope angle of the slopes to at least 45 degrees so that the snow itself would slide off the roof. However, in this case, the height of the dome increases significantly, the area of the courtyard coverage increases and, in addition, the load on the internal wall fences of the buildings of the complex increases due to the increase in the weight of the guides for the elastic translucent roof covering.

Insufficient insolation of the courtyard due to the covering covered with snow has a negative effect not only on the state of health of people, but creates unfavorable conditions for winter garden plants.

As a result of the patent search, technical solutions have been identified that provide the ability to free the dome-shaped surface of inflatable structures from snow.

Known is a device for removing snow from an inflatable structure used in the implementation of the corresponding method. The device contains a panel laid along the protected surface of the structure symmetrically to its vertical axis. The hanging ends of the panel are also symmetrically fixed at the same level with the base of the structure with the possibility of changing the tension of the cables. Shaking off snow from the surface of the structure is as follows. On one side of the panel, the tension of the cables is relaxed, and on the other side of the panel, the tension of the cables is increased. Then the air pressure is increased in the structure, the panel slides towards the cables with increased tension, dragging the snow along (USSR, Inventor's Certificate No. 1604984, E04N 15/20, 07.11.90.)

Known device for protecting pneumatic structures from meteorological influences, which contains a panel laid on the protected surface of the structure. Elastic braces are attached to the opposite edges of the panel hanging down. The second ends of the guys are connected to the corresponding drive drums of the winches located on both sides of the above said edges of the panel. The drive drums simultaneously carry out the function of the panel support. To dump snow, the drive of one of the winches is turned on, elastic braces from this side are wound on the winch drum and move the panel down to the sides. Snow slides down from the dome of the structure.

An analysis of the devices for clearing snow from domed surfaces revealed as a result of a patent search showed that the revealed devices can only be used to remove snow from extended surfaces with a vertical section in the form of a symmetrical oval arch. The hypothetical use of the known devices for throwing snow from the cover for a closed courtyard formed by the internal wall fences of the building complex is impractical, since as a result the area of the translucent cover is reduced due to the need to overlay the cloth on the cover. In addition, given the large size of the courtyard cover, the use of known snow shaking devices is in principle impractical.

Thus, from the foregoing, it follows that there is a problem of self-cleaning of snow from a roof with a translucent coating for a closed yard formed by the internal wall fences of a building complex.

The proposed roof with a translucent coating for a closed yard formed by the internal wall fences of the building complex, when implemented, solves the problem of self-cleaning of the translucent surface of the roof covering from snow.

In addition, the proposed roof with a translucent coating for a closed courtyard formed by internal wall fences of a building complex, when implemented, provides the achievement of the technical result: improved illumination of the courtyard interior space in the winter season by self-cleaning the translucent coating from snow; providing the required insolation for people and plants in the winter garden of the yard in the winter season; saving drinking water for watering plants in the winter garden due to the possibility of utilizing precipitation both in the form of snow and in the form of rain; improving the aesthetic appearance of the courtyard.

In addition, the proposed roof with a translucent coating for a closed courtyard formed by the internal wall fences of the building complex, when implemented, provides an additional technical result: the ability to change the shape of the roof without changing the internal dimensions of the courtyard.

The essence of the claimed invention lies in the fact that in the proposed roof with a translucent coating for a closed courtyard formed by the internal wall fences of the building complex, it is new that the roof has the shape of the surface of a body of revolution formed by the rotation of a flat figure bounded by a curve (hereinafter - the forming figure ), around a vertical axis lying with the generating figure in one plane, but not crossing it, and the vertical axis of rotation of the generating figure coincides with the vertical axis of symmetry of the inner courtyard space, while the generating figure is bounded from the side of the courtyard surface by a virtual horizontal plane resting on wall fences of the building complex facing the inside of a closed yard, while the shape of the generating figure makes it possible to form peripheral and internal roof slopes with a slope of 40 to 90 ° relative to the horizontal level, while the peripheral edges of the surface spines of the body of revolution are the peripheral edges of the roof slopes, which along the perimeter rest on the wall fences of the building complex facing the inside of the closed yard and are tightly connected to them, and the inner edges of the surface of the body of revolution, facing the center of the yard, form the inner edges of the roof slopes, which are continued to form funnels, maintaining a slope in the range from 40 to 90 ° relative to the horizontal level, rest on the ground surface in the center of the courtyard symmetrically relative to the vertical axis of symmetry of the courtyard space and at a given distance from this axis, with the possibility of a hermetic connection with a catchment located below zero the level of the surface of the courtyard.

In addition: the roof has the shape of the surface of a body of revolution formed by the rotation of a flat figure in the form of a semicircle; the roof has the shape of the surface of a body of revolution formed by the rotation of a flat figure in the shape of a triangle, the base of which lies in the horizontal plane at the level of the internal wall railing, and the top is directed upward; the roof has the shape of the surface of a body of revolution formed by the rotation of a flat figure in the form of a half-ellipse; the inner edges of the roof slopes rest on a hollow and sealed vertical central support, the vertical axis of which coincides with the vertical axis of symmetry of the courtyard space, and are hermetically connected along the perimeter to its upper end, while the lower end of the support rests on the ground surface in the center of the courtyard, with the possibility of a hermetically sealed connection with a water collector; the water collector is connected to the water purification device and is equipped with a transfer pump installed with the possibility of supplying water to the upper part of the water collector; the roof is made air-supported, while the translucent coating is made in the form of elastic translucent hollow membranes inside, made with the possibility of connecting to individual means of air blowing; the roof is made of frame; the roof frame is made in the form of guides, which in the zone of interaction with the coating are congruent to the internal shape of the body of revolution and the peripheral ends along the perimeter of the roof rest on the wall fences of the building complex, facing the inside of the closed yard, and with the ends facing the center of the yard, rest on the ground surface in the center the courtyard, symmetrically about the vertical axis of symmetry of the inner space of the courtyard and at a distance from it; the roof frame is made in the form of guides, which in the interaction zone with the coating are congruent to the internal shape of the body of revolution and the peripheral ends along the perimeter of the roof rest on the wall fences of the building complex facing the inside of the closed yard, and the ends facing the center of the yard rest on a hollow and sealed vertical a central support, the vertical axis of which coincides with the vertical axis of symmetry of the courtyard space, and is connected along the perimeter to its upper end, while the edges of the roof slopes facing the center of the courtyard are hermetically connected along the perimeter to the upper end of the support, the lower end of which rests on the surface soil in the center of the courtyard, with the possibility of a hermetic connection with the water collector; the roof covering is made with variable transparency.

The essential features of the invention, set out in the limiting part of the claims: "A roof with a translucent coating for a closed courtyard formed by internal wall fences of a building complex ..." are an integral part of the claimed device and ensure its implementation, and, therefore, ensure the achievement of the claimed technical result.

The solution of the identified technical problem and the implementation of the claimed technical result is achieved as follows.

In the claimed invention, the roof has the shape of the surface of a body of revolution formed by rotating a flat figure bounded by a curve (hereinafter referred to as a generating figure) around a vertical axis lying with the generating figure in the same plane, but not crossing it. The formation of the proposed roof surface is well illustrated by the example of the formation of the torus surface (Fig. 7; https://ok-t.ru/mydocxru/baza3/152917040686.files/image160.jpg). For the present invention, the roof has the shape of the outer surface of the upper part of the body of revolution in the form of a torus, which is formed as a result of sectioning the surface of the torus by a horizontal plane passing through the radius of the generating circle and resting on the wall fences of the building complex facing the inside of the closed yard. In this case, the generating figure is a semicircle. In the proposed invention, the shape of the generatrix of the figure can be any, providing the possibility of forming the peripheral and internal slopes of the roof with a slope of 40 to 90 ° relative to the horizontal level.

Since in the claimed invention the roof has the shape of the surface of a body of revolution formed by the rotation of a flat figure bounded by a closed curve (hereinafter referred to as a generatrix figure), this makes it possible to give the plane of the generatrix a certain shape and required geometric dimensions. Since the axis of rotation of the generatrix of the figure coincides with the vertical axis of symmetry of the space of the courtyard, this ensures the vertical position of the generatrix of the figure during rotation, which, in turn, ensures the symmetry of the roof relative to the axis of symmetry of the internal space of the courtyard, and, in addition, the vertical size of the figure provides the required roof height.

In this case, the surface of the body of revolution, formed as a result of rotation of the generatrix of the plane around the vertical axis, lying with the generatrix in the same plane, but not crossing it, has an axial hole in the center. As a result, the surface of the body of revolution, obtained in accordance with the claimed claims, has peripheral edges and internal edges facing the center of the yard. In this case, the peripheral edges of the surface of the body of revolution are the peripheral edges of the roof slopes, and the inner edges of the surface of the body of revolution, facing the center of the yard, form the inner edges of the roof slopes. Thus, the claimed roof has peripheral slopes and slopes facing the inside of the closed courtyard, i.e. is made of gable, symmetrical about the vertical axis of symmetry of the courtyard space. In this case, since the generating figure is bounded from the side of the surface of the courtyard by a virtual horizontal plane resting on the wall protections of the building complex facing the inside of the closed courtyard, the surface of revolution is formed at the level of the wall protections, which ties the geometric dimensions of the formed surface of rotation to the dimensions of the courtyard.

In this case, the peripheral edges of the surface of the body of revolution, the peripheral edges of the roof slopes along the perimeter rest on the wall fences of the building complex facing the inside of the closed courtyard and are connected to them hermetically. The inner edges of the surface of the body of revolution, facing the center of the courtyard, the inner edges of the roof slopes, continued to form a funnel and rest on the ground surface in the center of the courtyard symmetrically relative to the vertical axis of symmetry of the courtyard space and at a distance from it, with the possibility of a hermetic connection with the water collector, which is located below the zero level of the courtyard surface. As a result, a vertical channel is formed for receiving atmospheric precipitation.

In addition, the edges of the roof slopes facing the center of the courtyard can rest on the ground surface in the center of the courtyard by means of a hollow and sealed vertical central support, the vertical axis of which coincides with the vertical axis of symmetry of the courtyard space, and the lower end of the support rests on the ground surface in the center of the courtyard, with the possibility of a hermetically sealed connection to the water collector In this case, the edges of the slopes are hermetically connected along the perimeter to the upper end of the support.

From the above it follows that the tightness of the connection with the space of the courtyard of the roof slopes is ensured both at the level of the wall fences of the building complex facing the inside of the closed courtyard, and below the zero level of the courtyard surface. As a result, the tightness of the connection of the entire roof with a translucent coating with the space of the courtyard is ensured, which makes it possible to create your own microclimate and comfortable conditions inside the closed courtyard at any time of the year.

It is known that the most common method of self-cleaning of the surface of a roof covering from snow is to achieve snow sliding under its own weight by varying the angle of inclination of the roof slopes relative to the horizontal level. It is also known that the angle of inclination of the roof slopes, which is 40-45 °, already provides an independent snow fall from the surface of the roofing material (http://beton-stroyka.ru/kiysha/kakoy-dolzhne-byt-ugol-naklona-kryshi- chtoby-ne-skaplivalsya-sneg.html; https://krovlyakrishi.ru/obsliizhivanie/ochistka-ot-snega/ugol-kryshi-dlya-sxoda-snega.html).

In the claimed invention, the shape of the generatrix of the figure makes it possible to obtain a roof with a shape in which the peripheral and internal slopes have a slope of 40 to 90 ° relative to the horizontal level. In addition, the inner edges of the roof slopes are extended with the formation of a funnel to the ground surface in the center of the courtyard, while maintaining a slope in the range from 40 to 90 ° relative to the horizontal level. As a result, the proposed shape of the roof provides the possibility of snow sliding from the translucent roof covering under its own weight, both on the peripheral and internal roof slopes.

In this case, since the shape of the roof surface is formed when a flat figure bounded by a curve (hereinafter referred to as a generating figure) rotates around a vertical axis lying with the generating figure in one plane, but does not intersect it, the slopes facing the inside of the closed yard are located symmetrically with respect to the vertical axis of symmetry of the inner space of the courtyard and at a distance from it, i.e. The resulting form of the roof has a vertical channel in the center for receiving precipitation, both in the form of snow and in the form of rain, and below the zero level of the courtyard surface, since the inner edges of the roof slopes are hermetically connected to a water collector, which is located below the zero level of the courtyard surface.

The connection of the collector to the water purification device provides the possibility of cleaning sediments and their further disposal.

In addition, due to the fact that the water collector is equipped with a transfer pump installed with the possibility of supplying water to the upper part of the collector, the melting of snow accumulating in the upper part of the collector is stimulated and accelerated, which makes it possible and increases the efficiency of utilization of atmospheric precipitation in the form of snow. Installing the water collector below the zero level of the yard surface ensures that water does not freeze in it due to the extraction of heat from the soil of the courtyard surrounding the water collector.

The presence of a transfer pump in the water collector and the possibility of cleaning the collected precipitation provide the possibility of using the utilized precipitation for economic purposes, including for watering the winter garden. As a result, drinking water is saved. The possibility of utilizing precipitation, both in the form of snow and in the form of rain, as shown by calculations for a winter garden with a roof area of 6000 m ² , allows saving up to 1450 m ^{3 of} drinking water throughout the year.

In the proposed invention, the roof can be made with the shape of the surface of the body of revolution formed by the rotation of a flat figure in the form of a semicircle, the radius of which is the height of the roof. The forming figure - a semicircle is bounded from the side of the surface of the courtyard by a virtual horizontal plane resting on the wall fences of the building complex, facing the inside of the closed courtyard, in the plane of which the diameter of the semicircle lies.

Let us calculate the height of the zone of the translucent roof covering, in which the conditions are provided for the self-sliding of snow. When performing the generating figure in the form of a semicircle, the slope angle of the roof slopes is the angle of inclination of the tangent to the lateral surface of the generating figure - a semicircle relative to the horizontal level.

The calculation is explained in FIG. 4, which shows the shape of the roof surface, formed in accordance with the claimed claims by rotation of the generatrix of the figure in the shape of a semicircle. In this case, the height of the roof is the radius of the semicircle.

On the arc, for example, of the right rectangular sector of the generatrix of the semicircle, we find the point at which the angle of inclination of the tangent to the horizontal level is 45 °, for which we draw the bisector from the vertex of the right angle C to the intersection with the arc of the generator of the circle (point B).

Draw at this point a tangent to the arc of the generating circle (to the lateral surface of the body of revolution) until it intersects with the horizontal plane passing through the radius of the generating circle. From the formed triangle ABC it can be seen that the angle BAC of the slope of the tangent to the side surface of the roof at the selected point B is 45 °, which confirms the correctness of the previous actions. Thus, the independent snow melt from the surface of the translucent roof covering is ensured starting from point B.

Determine the height of the roof, corresponding to point B, at which the angle of inclination of the tangent to the section plane is 45 °. We build a projection of point B, to the height of the roof (to the vertical radius of the semicircle). We get a right-angled triangle SVK, in which the hypotenuse is the radius r of the generating circle, and the angles adjacent to the hypotenuse are equal to 45 °.

Calculates the length of the leg of the CS, i.e. the height of the roof corresponding to point B, at which the angle of inclination of the tangent to the section plane is 45 °:

h = r x sin 45 ° = 0.707 g.

Thus, relative to the upper level of the inner wall enclosures of the inner space of the courtyard, the height of the zone of the translucent cover that is confidently not covered with snow is 0.707 of the value of the radius r of the generating circle, i.e. 0.707 of the roof height.

Thus, when the roof is made with the shape of the surface of the body of revolution formed by the rotation of a flat figure in the form of a semicircle, the roof has a slope of the slopes, smoothly varying from 0 to 45 °, starting from the highest point of the covering, and then changing from 45 to 90 °. In this case, the height of the zone of the translucent cover that is confidently not covered with snow is 0.707 of the height of the roof.

In the claimed invention, the roof can have the shape of the surface of a body of revolution formed by the rotation of a flat figure in the form of a semi-ellipse, which is a generating figure bounded from the side of the surface of the courtyard by a virtual horizontal plane resting on the wall fences of the building complex facing the inside of the closed courtyard, in the plane of which lies the minor or major axis of the ellipse, and the height of the roof is, respectively, half the length of the major or minor axis of the ellipse, depending on which axis the section of the ellipse is made.

Let us calculate the height of the zone of the translucent roof covering, in which the conditions are provided for the self-sliding of snow with a generating figure in the form of a semi-ellipse.

The ellipse is described by a mathematical equation in parametric form: x = a sint, y = b cost or x = a cost, y = b sint, where x, y are the current coordinates, t is the corresponding angle, and is half the length of the major axis of the ellipse, b - half the length of the minor axis of the ellipse (Prof. AF Astafiev "Engineering reference book", M., 1937, p. 22).

When the roof is made in the form of the surface of a body of revolution formed by the rotation of a flat figure in the form of a semi-ellipse, the height of the roof is equal to half the length of the minor axis of the ellipse, if the generating figure is a semi-ellipse obtained by a section along the major axis, or equal to half of the minor axis, if the generating figure is is a semi-ellipse obtained by a section along the minor axis of the ellipse.

Since the optimal slope angle of the roof slopes is 45 °, then sint = cost = 0.707. Then: x = 0.707a, y = 0.707b.

Thus, when the roof is made in the form of a surface of a body of revolution, formed by the rotation of a flat figure in the form of a semi-ellipse at a roof slope angle of 45 °, the height of the zone of the translucent cover that is confidently not covered with snow relative to the upper level of the inner wall fences of the inner space of the courtyard, as well as for semicircle, is 0.707 of the height of the roof, i.e. 0.707 from half the length of the major or minor axis of the ellipse. However, in contrast to the use of a generatrix of a figure in the form of a semicircle, when using a semi-ellipse as a generatrix, the area of the translucent roof covering can be adjusted by increasing its height, i.e. increasing the corresponding semiaxis of the semi-ellipse, since, unlike a semicircle, changing the length of the semi-minor axis does not lead to a change in the length of the semi-major axis and vice versa. In both cases, the roof is pulled upwards, which increases the area of the translucent cover.

In the claimed invention, the roof may have the shape of the surface of a body of revolution formed by the rotation of a flat figure in the shape of a triangle, the base of which lies in a virtual horizontal plane at the level of the inner walls of the enclosures, and the top is directed upward. In this case, the slope angle of the roof slopes is provided by choosing the inner angles of the triangle. In this case, the following options may be optimal: the slope angle of the peripheral slopes is 90 °, the slope angle of the slopes facing the inside of the yard is 45 °;

the slope angle of the peripheral slopes is 45 °, the slope angle of the slopes facing the inside of the yard is 45 °;

the slope angle of the peripheral slopes is 45 °, the slope angle of the slopes facing the inside of the yard is 90 °.

The forms of roof execution described above are optimal. In practice, the shape of the generating figure can be any, providing the possibility of forming the peripheral and internal slopes of the roof with a slope of 40 to 90 ° relative to the horizontal level. For example, the figure can be composite: a quarter of a circle and a quarter of an ellipse, one of the axes of which coincides with the radius of the circle and is the height of the roof; by analogy - a quarter circle and a triangle; quarter ellipse and triangle, etc.

The roof is air-supported, while the translucent cover is made in the form of elastic translucent hollow membranes inside, made with the possibility of connecting to individual means of air blowing, allows you to fix the resulting shape of the roof by organizing air blowing inside the yard.

Another proposed option for fixing the shape of the roof is the implementation of the frame roof. In this case, the roof frame is made in the form of guides, which in the zone of interaction with the translucent coating are congruent to the inner surface of the body of revolution, which makes it possible to form the roof with the shape of the surface of the body of revolution formed when the selected generator of the figure rotates.

Since the guides in the zone of interaction with the translucent coating are congruent to the inner surface of the body of revolution, while the peripheral ends along the perimeter of the roof, the guides rest on the wall fences of the building complex, facing the inside of the closed courtyard, and with the ends facing the center of the courtyard, rest on the ground surface in the center of the courtyard symmetrically about the vertical axis of symmetry of the inner space of the courtyard, then the conditions for the formation in the center of the roof of a funnel and a vertical channel for receiving precipitation, both in the form of snow and in the form of rain, are satisfied, and below the zero level of the surface of the courtyard.

In addition, the guides of the frame with their ends facing the center of the courtyard can be supported on the ground by means of a central vertical support, for which the guides are connected along the perimeter with its upper end of the support. Since the vertical axis of the central support coincides with the vertical axis of symmetry of the courtyard space, and the lower end rests on the ground surface in the center of the courtyard, with the possibility of a hermetic connection with the water collector, while the edges of the roof slopes facing the center of the courtyard are hermetically connected along the perimeter with the upper the end of the support, the conditions are preserved for the formation of a funnel and a vertical channel in the center of the roof for receiving precipitation, both in the form of snow and in the form of rain, also below the zero level of the courtyard surface.

In addition, due to the fact that the shape of the generatrix of the figure allows the formation of peripheral and internal roof slopes with a slope of 40 to 90 ° relative to the horizontal level, i.e. forms the conditions for the spontaneous rolling of snow from the translucent roof covering, then the translucent roof covering can be made with variable transparency. In the optimal version, the zone of the translucent cover on the roof slopes with the slope angle of the slopes is greater than or equal to 40 °, i.e. in areas of confident spontaneous snow sliding, can be made with a transparency coefficient higher than the transparency coefficient of the main translucent coating. As a result, the illumination of the inner space of the courtyard increases in the winter season. In addition, in the general case, the ability to perform roofing with variable transparency allows you to organize specially shaded zones inside the yard, which is important in the summer season. As a result, comfortable illumination of the yard is maintained at any time of the year.

In addition, the proposed implementation of the roof allows you to minimize the number of supports for the roof inside the yard to one central support, or even to refuse it. As a result, the aesthetic appearance of the courtyard is improved, space is freed up for organizing people's everyday life, and the comfort of conditions for rest is increased.

Thus, from the foregoing, it follows that the proposed roof with a translucent coating for a closed yard formed by internal wall fences of a building complex, when implemented, solves the problem of self-cleaning of the translucent surface of the coating from snow.

In addition, the proposed roof with a translucent coating for a closed courtyard formed by internal wall fences of a building complex, when implemented, provides the achievement of the technical result: improved illumination of the courtyard interior space in the winter season by self-cleaning the translucent coating from snow; providing the required insolation for people and plants in the winter garden of the yard in the winter season; saving drinking water for watering plants in the winter garden due to the possibility of utilizing precipitation both in the form of snow and in the form of rain; improving the aesthetic appearance of the courtyard.

In addition, the proposed roof with a translucent coating for a closed courtyard formed by the internal wall fences of the building complex, when implemented, provides an additional technical result: the ability to change the shape of the roof without changing the internal dimensions of the courtyard. This is achieved due to the fact that the roof has the shape of the surface of a body of revolution formed by the rotation of a flat figure bounded by a curve around a vertical axis lying with the generating figure in one plane, but not intersecting it, and the vertical axis of rotation of the generating figure coincides with the vertical axis of symmetry courtyard space. As a result, the shape of the roof is in direct proportion to the shape of the flat figure bounded by the curve. In the claimed invention, the figure can be limited by a curve in the form of a semicircle, half-ellipse, triangle, and in principle, the forming figure can have any shape that allows the formation of peripheral and internal roof slopes with a slope of 40 to 90 ° relative to the horizontal level.

FIG. 1 shows a roof with a translucent covering for a closed courtyard formed by internal wall fences of a building complex, made of frame, vertical section, front view; in fig. 2 - the declared roof, made with air support, vertical section, front view; in fig. 3 - the declared roof, made of air support, in which the inner edges of the roof slopes rest on the vertical central support, vertical section, front view; in fig. 4 is a drawing explaining the calculation of the height of a roof not covered with snow for a generating figure in the form of a semicircle; in fig. 5 is an internal view of the space of a closed courtyard formed by internal wall fences of a building complex, a vertical section of the roof with a frame design, the guides rest on the ground by means of a central support; in fig. 6 is an internal view of the space of a closed courtyard formed by the internal wall fences of the building complex, the guides rest with the formation of a funnel on the ground surface in the center of the courtyard symmetrically relative to the vertical axis of symmetry of the courtyard space and at a given distance from this axis, with the possibility of a hermetic connection with the water collector, which is located below the zero level of the courtyard surface; in fig. 7 is a figure explaining the formation of the roof surface by the example of the formation of the upper part of the torus surface with a semicircle generating figure.

The roof 1 with a translucent covering 2 for a closed courtyard formed by the internal wall fences 3 of the building complex 4 has the shape of the surface of a body of revolution formed by the rotation of a flat figure bounded by a closed curve (hereinafter referred to as the generating figure 5, Fig. 4) around the vertical axis, lying with the generating figure in one plane, but not intersecting it. The vertical axis of rotation of the generatrix of the figure coincides with the vertical axis of symmetry 6 of the inner courtyard space. The forming figure 5 is bounded from the side of the courtyard surface by a virtual horizontal plane resting on the wall fences 3 of the building complex 4, facing the inside of the closed courtyard. The shape of the generatrix of figure 5 allows the formation of peripheral and internal roof slopes with a slope of 40 to 90 ° relative to the horizontal level. The peripheral edges of the surface of the body of revolution are the peripheral edges of the roof slopes 7, which along the perimeter rest on the wall fences 3 of the building complex 4 facing the inside of the closed courtyard and are connected to them tightly. The inner edges of the surface of the body of revolution, facing the center of the courtyard, form the inner edges of 8 roof slopes, which continue to form a funnel while maintaining a slope in the range from 40 to 90 ° relative to the horizontal level, rest on the ground surface in the center of the courtyard symmetrically about the vertical axis of symmetry 6 of the inner courtyard space and at a distance from it, with the possibility of a hermetic connection with the water collector 9, which is located below the zero level of the courtyard surface.

The water collector 9 is connected to a water purification device (not shown) and is equipped with a transfer pump 10 installed to supply water to the upper part of the water collector 9.

The roof can be in the form of the surface of a body of revolution formed by the rotation of a flat figure in the form of a semicircle (Fig. 2, Fig. 3, Fig. 4).

The roof can be in the form of a surface of a body of revolution formed by the rotation of a flat figure in the shape of a triangle, the base of which lies in a virtual horizontal plane at the level of the inner wall railing, and the top is directed upwards (not shown in the figure).

The roof can be in the form of a surface of a body of revolution formed by the rotation of a flat figure in the form of a semi-ellipse (Fig. 1, Fig. 5, Fig. 6).

The inner edges 8 of the roof slopes can rest on a hollow and sealed vertical central support And (Fig. 3). The vertical axis of the central support coincides with the vertical axis of symmetry 6 of the courtyard space. The inner edges 8 of the roof slopes are hermetically connected along the perimeter to the upper end of the central support 11. The lower end of the support 11 rests on the ground surface in the center of the courtyard, with the possibility of a hermetic connection with the water collector 9.

The roof can be air-supported, in which the translucent cover can be made in the form of elastic translucent hollow membranes inside, made with the possibility of connecting to individual means of air blowing. In addition, when the roof is air-supported, the inner courtyard is provided with a common air blowing device communicating with the external environment.

The roof can be made of frame. The roof frame can be made in the form of guides 11, which in the interaction zone with the covering 2 are congruent to the internal shape of the body of revolution that forms the shape of the roof. The guides 11 with their peripheral ends along the perimeter of the roof rest on the wall fences 3 of the building complex 4, and with the ends facing the center of the yard, rest on the ground surface in the center of the courtyard, symmetrically about the vertical axis of symmetry 6 of the inner space of the yard and at a distance from it.

Connections to the ground surface of the ends of the guides facing the center of the courtyard can be made by means of a hollow and sealed central support 12, the vertical axis of which coincides with the vertical axis 6 of symmetry of the courtyard space. In this case, the ends of the guides 11, facing the center of the courtyard, rest on the vertical central support 12 and are connected along the perimeter with its upper end. In this case, the edges of the roof slopes facing the center of the courtyard are hermetically connected along the perimeter to the upper end of the support 12, the lower end of which rests on the ground surface in the center of the courtyard, with the possibility of a hermetic connection with the water collector 9.

Translucent roofing can be made with variable transparency. In the optimal version, the zone of the translucent cover on the roof slopes with the slope angle of the slopes is greater than or equal to 40 °, i.e. in areas of confident spontaneous snow sliding, can be made with a transparency coefficient higher than the transparency coefficient of the main translucent coating. As a result, the illumination of the inner space of the courtyard increases in the winter season.

In general, the ability to perform roofing with variable transparency allows you to organize specially shaded zones inside the yard space, which is important in the summer season.

The claimed invention is carried out as follows. A curve is preliminarily formed that bounds a flat figure, which forms during rotation the surface of a body of revolution with a shape required for the roof.

For example, for the generatrix of the figure in the form of a semicircle, based on the given width of the courtyard, the radius of the generatrix of the semicircle is selected, which is also the height of the covering. Build a semicircle. From the side of the inner edge of the semicircle facing the center of the courtyard, a tangent is drawn to the semicircle at an angle of 45 ° to the horizontal level. Then, from the point of contact, the inner edge of the semicircle is smoothly continued to form a funnel 13 while maintaining a slope in the range from 40 to 90 ° relative to the horizontal level for a length at which it rests on the ground surface in the center of the courtyard at a given distance from the vertical axis of symmetry of the inner space of the courtyard and has the possibility of hermetic connection with the water collector 9, which is located below the zero level of the surface of the courtyard.

Obtaining drawings of the required shape of the generatrix of the figure and the shape of the surface of revolution as a whole can be automated, for example, using computer digital programs for design.

When making an air-supported roof, an elastic translucent coating is used, which is shaped into the resulting total curve, for example, by heat treatment.

For ease of assembly, the elastic translucent cover can be divided, for example, radially into sections. The connection of the sides of the sections in the simplest case can be performed, for example, as follows. A self-engaging tape, such as a pile zipper, is welded along the joining edges of the lateral sides, so that the interlocking surfaces, when aligned, are directed towards each other (so that, when aligned, they engage each other). Combine overlap. Outside, the seam is hermetically closed with self-adhesive tape.

In the case of an air-supported roof, the roof assembly with an elastic translucent coating is carried out on the ground. Installation is carried out using a crane. The roof with a translucent coating is sectionally tightly connected to the wall fences of the building complex facing inside the closed courtyard. Then, also in sections, the sides of the sections and the translucent cover are hermetically connected. The ends of the roof sections connected to each other and installed in the required position, facing the center of the courtyard, are hermetically connected to the water intake.

When the roof is air-supported, the elastic translucent coating can be made in the form of elastic translucent hollow membranes inside, made with the possibility of connecting to individual means of air blowing. Typically, individual means of inflation contain compressors and dispensing hoses, rigidly and hermetically connected to the inner cavity of the corresponding membrane.

After the tight connection of the elastic coating on the internal enclosing structures of the building complex, with the help of individual blowing means, excess pressure is created in the membranes of the slopes. Then the final setting of the roof is carried out by blowing directly from the compressor of the general blowing device.

When making a frame roof, the translucent coating can be either elastic (membrane) or rigid (glass).

When making a frame roof, guides 11 are made, giving them the shape of the roof, namely: guides 11 in the zone of interaction with the translucent coating 2 are congruent to the inner surface of the body of revolution, in this case - semicircles for the peripheral slopes of the roof, and to the inner edges of the surface of the body of revolution facing the center of the yard, which form the inner edges of the roof slopes and which are continued to form a funnel while maintaining a slope in the range from 40 to 90 ° relative to the horizontal level.

The guides 11 are assembled in sections on the ground and lifted by a crane with further installation in place, previously a translucent cover is fixed on them.

The peripheral ends of the guides 11 along the perimeter of the roof 1 are fixed on the wall fences 3 of the building complex 4, facing the inside of the closed courtyard. The ends of the guides 11, facing the center of the courtyard, are fixed on the ground surface in the center of the courtyard, symmetrically relative to the vertical axis of symmetry 6 of the inner space of the courtyard and at a specified distance from the axis 6, which provides the required width of the vertical channel of the funnel 13 for efficient reception of precipitation.

If the cover 2 is elastic, then it is cut out in the shape of the sections of the guides 11. A self-engaging tape, such as a pile zipper, is welded along the butting edges of the lateral sides of the cover 2 so that the mating surfaces are directed towards each other when aligned.

From the inside, the elastic cover 2 is sealed with self-adhesive tape to both sides of the guides 11.

The lower ends of the translucent cover 2 are hermetically connected to the water intake 9.

In the case of using a central vertical support 12, in the roof frame 1, the guides 11 with their ends facing the center of the courtyard rest on the upper end of a hollow and sealed vertical central support 12, the vertical axis of which coincides with the vertical axis of symmetry of the courtyard space, and the lower the end rests on the ground surface in the center of the courtyard with the possibility of a hermetic connection with the water collector 9.

The only difference from the previous version is that the edges of the slopes 8 of the roof 1, facing the center of the courtyard, are hermetically connected along the perimeter to the upper end of the support 12.

The roof covering can be made of glass. In this case, the guides are interconnected by cells for fixing glass inserts in them.

When using the declared roof in the winter season, the formed slope of the slopes 7, 8 of the roof 1 contributes to the active rolling of snow onto the roof of the buildings of the complex 4 and into the funnel 13, and then into the water intake 9. As a result, the insolation of the inner space of the courtyard improves, the aesthetic appearance of the winter garden improves ... The possibility of using atmospheric precipitation for domestic needs saves drinking water.

Claims (11)

1. A roof with a translucent covering for a closed courtyard formed by internal wall fences of a building complex, characterized in that the roof has the shape of the surface of a body of revolution formed by the rotation of a flat figure bounded by a curve, hereinafter called a generating figure, around a vertical axis lying with the generating figure in one plane, but not crossing it, and the vertical axis of rotation of the generator of the figure coincides with the vertical axis of symmetry of the space of the courtyard, while the generating figure is bounded on the side of the surface of the courtyard by a virtual horizontal plane resting on the wall fences of the building complex facing the inside of the closed courtyard, in this case, the shape of the generating figure provides the possibility of forming peripheral and internal roof slopes with a slope of 40 to 90 ° relative to the horizontal level, while the peripheral edges of the surface of the body of revolution are the peripheral edges of the roof slopes whether, along the perimeter, rest on the wall fences of the building complex facing the inside of the closed courtyard and are tightly connected to them, and the inner edges of the surface of the body of revolution, facing the center of the courtyard, form the inner edges of the roof slopes, which continue to form a funnel while maintaining a slope in the range from 40 to 90 ° relative to the horizontal level, rest on the ground surface in the center of the courtyard symmetrically with respect to the vertical axis of symmetry of the courtyard space and at a given distance from this axis with the possibility of a hermetic connection with a water collector, which is located below the zero level of the courtyard surface. 2. The roof of claim. 1, characterized in that the roof has the shape of the surface of a body of revolution formed by the rotation of a flat figure in the form of a semicircle. 3. The roof of claim. 1, characterized in that the roof has the shape of the surface of a body of revolution formed by the rotation of a flat figure in the shape of a triangle, the base of which lies in the horizontal plane at the level of the inner wall railing, and the top is directed upwards. 4. The roof of claim. 1, characterized in that the roof has the shape of the surface of a body of revolution formed by the rotation of a flat figure in the form of a semi-ellipse. 5. The roof according to claim 1, characterized in that the inner edges of the roof slopes rest on a hollow and sealed vertical central support, the vertical axis of which coincides with the vertical axis of symmetry of the courtyard space, and is tightly connected along the perimeter to its upper end, while the lower end of the support rests on the ground surface in the center of the courtyard with the possibility of a hermetic connection with the catchment. 6. The roof of claim. 1, characterized in that the water collector is connected to the water purification device and is equipped with a transfer pump installed with the ability to supply water to the upper part of the water collector. 7. The roof of claim. 1, characterized in that the roof is made air-supported, while the translucent coating is made in the form of elastic translucent hollow membranes inside, made with the possibility of connecting to individual means of air blowing. 8. The roof of claim. 1, characterized in that the roof is made of frame. 9. The roof according to claim 8, characterized in that the roof frame is made in the form of guides, which in the interaction zone with the coating are congruent to the internal shape of the body of revolution and the peripheral ends along the perimeter of the roof rest on the wall fences of the building complex, facing the inside of the closed courtyard, and the ends , facing the center of the courtyard, rest on the ground surface in the center of the courtyard symmetrically about the vertical axis of symmetry of the courtyard interior space and at a distance from it. 10. The roof according to claim 8, characterized in that the roof frame is made in the form of guides, which in the interaction zone with the coating are congruent to the internal shape of the body of revolution and the peripheral ends along the perimeter of the roof rest on the wall fences of the building complex facing the inside of the closed yard, and the ends facing the center of the courtyard, rest on a hollow and sealed vertical central support, the vertical axis of which coincides with the vertical axis of symmetry of the courtyard space, and are connected along the perimeter to its upper end, while the edges of the roof slopes facing the center of the courtyard are sealed along perimeter with the upper end of the support, the lower end of which rests on the ground surface in the center of the courtyard with the possibility of a hermetic connection with the water collector. 11. The roof of claim. 1, characterized in that the roof covering is made with variable transparency.

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