RU65926U1 - ENERGY-EFFICIENT BUILDING "SOLAR-5 ECODOM" - Google Patents

Abstract

Energy-efficient building "SOLAR-5 ECODOM" containing walls, continuous and ventilated window openings, a gable roof with eaves and slopes from the roof ridge to the outside, solar collectors for water heating and solar photovoltaic panels mounted on the roof of the building, and a long longitudinal axis buildings, stretching from east to west, characterized in that the roof slope facing south is made in two parts, while its lower plane is placed at an angle to the horizon from 30 ° to the value defined by the expression 90 - °, where f is the latitude of the construction area of the building, in addition, its edge is made in the form of a visor protruding beyond the plane of the outer walls, not more than a third of their height, while at least part of the lower plane is used to place solar photovoltaic panels, the upper plane of this roof slope is placed at an angle to the horizon, determined by the expression f + 15 °, while at least part of this plane is used to accommodate solar collectors for water heating and is equipped with ventilated window with openings, in addition, the roof slope facing north is placed at an angle to the horizon from 75 - ° to 90 - °, while its edge is made in the form of a visor protruding beyond the plane of the outer end walls, but not more than half their heights and, at the same time, protruding beyond the ridge, but not more than half the width of the upper plane of the roof slope facing south.

In addition, the northern slope of the roof is made in two parts, while its lower plane is placed at an angle of 12 to 26.5 ° to the horizontal, and protrudes beyond the plane of the outer walls in the form of a visor no more than a quarter of their height.

In addition, the surface of the bottom plane of the roof slope, which is free from solar photovoltaic panels, facing south, has a reflective outer coating.

In addition, the orientation of the longer longitudinal axis of the building, stretched from east to west, is limited by the maximum deviation of the axis to 20 ° north and south from the specified direction, and the internal angle of intersection of the end walls and the longitudinal axis of the building in the horizontal plane is at least 60, but not more than 90 °, while the area of window openings is taken as not less than 60% of the area of walls oriented to the southern, western and eastern sectors of the horizon, and not more than 30% of the area of walls oriented to the northern sector of the horizon, and also not less than 30% of the total area of the window openings are ventilated.

In addition, within the boundaries of the outer walls there is a vertical space through the floor to the roof ridge with an area in horizontal section of not more than 50% of the building area within the borders of the outer walls.

Using the claimed model of an energy-efficient building ensures the achievement of the energy-saving effect when creating a comfortable thermal regime due to additional heat input from direct solar heating and reduction of heat loss during wind exposure in winter, as well as natural aeration and shading of residential premises in summer. 4 s.p. f-ly, 4 ill.

Description

The utility model relates to the field of architecture and construction and can be used in the development of projects and the subsequent development of territories of suburban and rural systems of permanent residence, as well as recreational areas of seasonal recreation, for the temperate climatic zone of the northern hemisphere.

Famous domestic and foreign models of energy-efficient buildings made for the temperate climatic zone of the northern hemisphere.

An energy-efficient building is known that contains the southern slope of the gable roof starting from the basement and is fully used for the placement of solar collectors for hot water supply. (See: Energy-Active Buildings, under the editorship of N.P. Selivanov, M., S / I. 1988., p. 247-248: “Single-family dwelling house of the M series, landfill“ Sun ”, Russia).

The disadvantage of this model is the solution of the southern slope of the roof, covering the entire southern wall of the house, which eliminates or complicates direct sunlight and heating of living quarters in winter, as well as their natural aeration in summer, in the energy-efficient building under consideration.

An energy-efficient building is known that contains a black painted and glazed wall of a southern orientation, and a south slope with a visor above the wall, a gable roof slope used to house solar collectors of hot water supply. (See: Energy-Active Buildings, ed. By N.P. Selivanov, M., S / I. 1988., p. 248: "P-series single-family house, polygon" Sun ", Russia).

The disadvantages of the model are the solution of the south wall without window openings, which makes direct sunlight and heating of residential premises located in the southern part of the building difficult in winter; the choice of a shallow depth of the visor of the southern slope of the roof, which eliminates shading

a glazed wall in the summer; the small area of the southern slope of the roof, which makes it difficult to place solar photovoltaic panels in addition to the collectors, as well as the decision of the roof of the building as a whole, excluding solar heating of rooms located in the northern part of the building in winter.

An energy-efficient building is also known, containing the southern slope of the gable roof, fully used for the joint placement of solar collectors for water heating and solar photovoltaic panels, as well as a continuous stained-glass window (window opening) of the southern orientation. (See: Solararchitectur fur Europa / Focus film. Astrid Schneider, Berlin, 1996., p. 48-51: residential building "Nullenergiehaus - serienreif", Wettringen, Germany).

The disadvantages of the described prototype are the proposed roofing solution in general, which excludes or impedes direct sunlight and heating, as well as the natural aeration of rooms located in the back of the building, as well as the solution of the angle of the southern slope of the roof normal to the sun's rays at noon of the autumn / spring equinox, optimal for solar photovoltaic panels, but reducing, when combined with them, the maximum heat transfer of solar water heating collectors in the coldest months of the year at viscous altitude of the sun above the horizon.

The technical task to be solved is the provision of high energy efficiency of a building by a combination of architectural means and techniques.

The expected technical result obtained when solving the problem is expressed in providing 57% of the estimated costs of heating the building for the period of the year with an average daily air temperature below + 8 ° C and 38% of the estimated costs of heating in the coldest five days with an air temperature of -24 ° C , and also expressed in

providing a comfortable thermal regime of residential premises during the day, during the period of the year with an average daily air temperature above + 20 ° С.

To solve this problem, an energy-efficient building containing walls, continuous and ventilated window openings, a gable roof with eaves and a slope from the roof ridge, solar water heaters and solar photovoltaic panels mounted on the roof of the building, and a long longitudinal axis of the building, elongated from east to west, characterized in that the slope of the roof facing south is made in two parts, while its lower plane is placed at an angle to the horizon from 30 ° to a value determined by the expression 90 - f °, where f is the latitude of the building construction area, in addition, its edge is made in the form of a visor protruding beyond the plane of the outer walls by no more than a third of their height, while at least part of the lower plane is used to place solar photovoltaic panels, and the upper plane of this roof slope is placed at an angle to the horizon, determined by the expression f + 15 °, while at least part of this plane is used to accommodate solar collectors for water heating and equipped with a valve the openings of the windows, in addition, the roof slope facing north is placed at an angle to the horizon from 75 - 90 ° to 90 - °, while its edge is made in the form of a visor protruding beyond the plane of the external end walls, but not more than half their height and, at the same time, protruding beyond the ridge, but not more than half the width of the upper plane of the roof slope facing south.

In addition, the northern slope of the roof is made in two parts, while its lower plane is placed at an angle of 12 to 26.5 ° to the horizontal, and protrudes beyond the plane of the outer walls in the form of a visor no more than a quarter of their height.

In addition, the surface of the bottom plane of the roof slope, which is free from solar photovoltaic panels, facing south, has a reflective outer coating.

In addition, the orientation of the longer longitudinal axis of the building, stretched from east to west, is limited by the maximum deviation of the axis to 20 ° north and south of the specified direction, and the internal angle of intersection of the end walls (facades) and the longitudinal axis of the building in the horizontal plane is not less than 60, but also no more than 90 °, while the area of window openings is taken as not less than 60% of the area of walls oriented to the southern, western and eastern sectors of the horizon, and not more than 30% of the area of walls oriented to the northern sector of the horizon, as well as at least 30% of the total area of the window openings made ventilated.

In addition, within the boundaries of the outer walls there is a vertical space through the floor to the roof ridge with an area in horizontal section of not more than 50% of the building area within the borders of the outer walls.

A comparative analysis of the features of the claimed solution with the signs of the prototype and analogues indicates the conformity of the claimed solution to the criterion of "novelty."

The features of the utility model formula solve the stated technical problem, provide high energy-saving building efficiency.

Figure 1 schematically shows a cross-section of an energy-efficient building "Eco-Solar-5", figure 2 schematically shows the roof of an energy-efficient building "Eco-Solar-5" from above, figure 3 schematically shows a plan of an energy-efficient building "Eco-Solar-5" , figure 4 schematically presents a view of the facade of the energy-efficient building "Solar-5 Eco-house" from the south.

The drawings show the lower plane of the roof slope facing south (1), placed at an angle to the horizontal in the vertical plane (2) from 30 ° to the value defined by the expression 90 - f °, where f is the latitude

the construction area of the building, with a visor (3) protruding beyond the plane of the outer walls by no more than a third of their height, and with solar photovoltaic panels located on it (4), the upper plane of the roof slope facing south (5), located under angle to the horizon (6), determined by the expression f + 15 °, with solar collectors for water heat supply (7) located on it, and equipped with ventilated window openings (8); the roof slope facing north (9), placed at an angle to the horizon (10) from 75 - ° to 90 - °, with a visor (11) protruding beyond the plane of the outer end walls, but not more than half their height and, at the same time, protruding beyond the ridge, but not more than half the width of the upper plane of the roof slope facing south.

In addition, the drawings show the lower plane of the roof slope facing north (12), placed at an angle to the horizon (13), from 12 and not more than 26.5 °, with a visor (14) protruding beyond the plane of the outer walls more than a quarter of their height, a reflective coating (15) of the lower plane of the roof slope facing south, a longitudinal axis of the building (16), elongated from east to west, limited to a maximum deviation of up to 20 ° north and south of this direction , end walls of the building (17) and the angle of their intersection horizontal plane (18) with the longitudinal axis of the building (16), which is not less than 60, but also not more than 90 °, as well as window openings (19), the area of which is taken at least 60% of the area of the walls oriented to the south, west and the eastern sector of the horizon, and not more than 30% of the area of the walls oriented to the northern sector of the horizon, at least 30% of the total area of the indicated window openings are made ventilated, the vertical space (20) through the floor to the roof ridge does not have a horizontal sectional area more than 50% of the building area in gr Anitsa external walls.

The solution of the stated technical problem is facilitated by placing the bottom plane of the roof slope facing south (1), at an angle to the horizon in the vertical plane (2), which ensures maximum efficiency of solar photovoltaic panels (4) on days of the year from spring to autumn equinoxes, placement of the upper plane of the roof slope facing south (5), at an angle to the horizontal in the vertical plane (6), which ensures maximum efficiency of solar collectors for water heating (7) and minimal loss of radiant sun heat passing through window openings (8) for reflection, on days of the year from mid-January to mid-February, placement of the roof slope facing north (9), at an angle to the horizontal in the vertical plane (10), which combined with window openings (8) in the upper plane of the roof slope facing south, provides direct sunlight and space heating in the northern part of the building, on days of the year from the autumn day to the spring equinox; the size of the visor (3) protruding beyond the plane of the outer walls by no more than a third of their height, and the value of the visor (11) protruding beyond the plane of the outer walls and to the south, beyond the line of the roof ridge, not more than half the height of the walls and half the width of the upper plane of the southern slope of the roof of the building, providing summer noon shading of window openings (8) and (19).

In addition, the solution of the technical problem is facilitated by the two-part division of the roof slope facing north, in which its lower plane (12) and visor (14) are placed at an angle in the vertical plane to the horizon (13), which, according to the laws of aerodynamics, prevents the separation of the oncoming from the north of the wind flow from the plane of the roof, a reflective outer coating (15) that increases the efficiency of solar water heating collectors (7) when they are additionally irradiated by sunlight reflected from the coating, at a low angle of the sun above g horizons winter, the maximum deviation of greater

along the length of the longitudinal axis of the building (16), stretched from east to west, up to 20 ° north and south of the specified direction, which ensures the greatest solar heat through window openings (8) and (19) in winter; the angle (18) of the intersection of the end walls of the building (17) with its longitudinal axis (16) in the horizontal plane, which contributes to the formation of a zone of wind lull on the south side of the building with an incident wind flow from the north, limiting the area of window openings (19) depending on their orientation, increasing the amount of solar heat entering the premises from the south, and reducing heat loss through openings oriented to the north, as well as limiting the minimum area of ventilated window openings through open sashes (19 ), the placement of ventilated, through open sashes, window openings (8) in the upper plane of the southern slope of the roof and the formation of a vertical space (20) through the floor from the roof to the roof ridge, which helps to ensure a comfortable thermal regime of living quarters during the day, during years with an average daily air temperature above + 20 ° C, through natural aeration.

Claims (5)

1. An energy-efficient building containing walls, continuous and ventilated window openings, a gable roof with eaves and slopes from the roof ridge to the outside, solar water heaters and solar photovoltaic panels mounted on the roof of the building, and a long longitudinal axis of the building extended from east to west, characterized in that the roof slope facing south is made in two parts, while its lower plane is placed at an angle to the horizon from 30 ° to the value defined by the expression 90 ° - f °, where f - the construction site’s spoilage, in addition, its edge is made in the form of a visor protruding beyond the plane of the outer walls, not more than a third of their height, with at least part of the lower plane used to accommodate solar photovoltaic panels, the top plane of this roof slope placed at an angle to the horizon, determined by the expression f ° + 15 °, while at least part of this plane is used to accommodate solar water heating collectors and is equipped with ventilated window openings and, in addition, the roof slope facing north is placed at an angle to the horizon from 75 ° - f ° to 90 ° - f, while its edge is made in the form of a visor protruding beyond the plane of the outer end walls, but not more than half of their height and, at the same time, protruding beyond the ridge, but not more than half the width of the upper plane of the roof slope facing south. 2. The energy-efficient building according to claim 1, characterized in that the northern slope of the roof is made in two parts, while its lower plane is placed at an angle of 12 to 26.5 ° to the horizontal, and protrudes beyond the plane of the outer walls in the form of a visor no more than a quarter of their height. 3. The energy-efficient building according to claim 1, characterized in that the surface of the lower plane of the slope of the roof facing south, free from solar photovoltaic panels, has a reflective outer coating. 4. The energy-efficient building according to claim 1, characterized in that the orientation of the longer longitudinal axis of the building, elongated from east to west, is limited by the maximum deviation of the axis to 20 ° north and south of the specified direction, and the internal angle of intersection of the end walls and the longitudinal the axis of the building in the horizontal plane is not less than 60 °, but also not more than 90 °, while the area of window openings is taken to be at least 60% of the area of walls oriented to the southern, western and eastern sectors of the horizon, and not more than 30% of the area of walls , landmarks nnyh horizon in the northern sector, and at least 30% of the total area of the window openings formed ventilated. 5. The energy-efficient building according to claim 1, characterized in that there is a vertical space through the floor from the roof to the ridge of the roof in the horizontal section with a horizontal section of not more than 50% of the building’s area within the outer walls.