RU2265162C2 - Solar energy collector used as building structure member - Google Patents

Abstract

FIELD: use of solar heat, particularly individual solar stations and solar radiation engineering systems for public and domestic use.

SUBSTANCE: solar heat collector comprises body of profiled material with transparent glass member, rear heat insulation and absorbing means made as tube-in-tube structure. The absorbing means include a number of heating pipes connecting one to another by metal ribs in metal rib plane and provided with inlet and outlet hydraulic manifolds to supply and discharge liquid to be heated. The solar heat collector is composed of translucent and light-absorbing parts connected one to another along perimeters thereof by means of detachable screw connectors through adhesive layer. To create the solar heat collector structure aluminum window profile system members are used. Above members are compatible with facade profile system of three-dimensional aluminum building structure.

EFFECT: increased ability of collector manufacture, assemblage and mounting and improved technical and operational performance.

6 cl, 11 dwg

Description

The invention relates to solar engineering, in particular to the device of solar liquid heaters, and can be used both in the construction of individual solar installations, and in solar systems for household and household purposes.

Known designs of solar collectors containing a housing with transparent glazing, thermal insulation, as well as an absorber, including a beam-absorbing surface with heating pipes and inlet and outlet hydraulic collectors for supplying and discharging a heated coolant / 1, 2 /.

Known devices can be installed both on the ground and on various parts of residential buildings, public buildings and industrial structures, but only on special, stable support and fixing structures, the presence of which generally negatively affects cost indicators and in some cases does not always satisfy existing ones architectural and aesthetic requirements.

The integration of the solar collector in the building structure makes it possible to comprehensively solve these problems, and also allows to reduce the requirements for thermal and waterproofing of the back surface of the collector and connecting pipelines due to the lack of direct contact of the latter with the external environment.

Known solar collector as an element of a building structure, comprising a housing in the form of a support element with a profiled frame and transparent glazing, thermal insulation and an absorber with channels for the flow of coolant / 3 /.

The closest technical solution is the known design of the solar collector, combined with the building structure, comprising a housing made of profiled material with transparent glazing, rear thermal insulation, and a pipe-in-sheet absorber in the form of a series of heating pipes interconnected by metal ribs in the plane of the latter and with inlet and outlet hydraulic manifolds for supplying and discharging a heated fluid / 4 /.

The key link in these two devices is the use of support and mounting profiled materials in the design of the collector body for its interface with the load-bearing elements of building structures, but at the same time there is no single chain of unified links based on well-established common manufacturing, assembly and installation technologies.

The common disadvantage of analogues and prototype, using as a absorber a beam-absorbing surface with heating pipes and hydraulic inlet and outlet manifolds for supplying and discharging heated fluid, affecting their technical and operational qualities, include the possibility of formation of air plugs in them during filling and operation hydraulic system, causing the termination of the circulation of the heated fluid in solar installations operating on the principle of thermosiphon effect, or decrease the flow rate of the coolant in solar systems with forced supply.

The most likely points of air congestion are the narrowing of the passageways at the junctions of the heating pipes with the hydraulic inlet manifold for supplying the heated fluid, since in practice in the described solar engineering devices the diameter of the heating pipes is 2-3 times smaller than the diameter of the inlet and outlet hydraulic collectors / fifteen/.

The task to which the invention is directed is the unification of properties, increasing the manufacturability of manufacturing, assembly and installation, as well as improving the technical and operational qualities of the solar collector as an element of a building structure.

The problem is solved as follows. In the design of the well-known solar collector, which includes a body made of profiled material with transparent glazing, rear thermal insulation, and a pipe-in-sheet absorber in the form of a series of heating pipes interconnected by metal ribs in the plane of the latter and with inlet and outlet hydraulic manifolds for supply and drainage of heated fluid, elements of the window system of aluminum profiles are used, compatible with elements of the facade system of profiles of spatial building aluminum x designs.

The indicated systems of aluminum profiles are currently widely used in the construction of civilian objects for residential and household purposes / 6 /. They are distinguished by the depth of elaboration of technical solutions related to the “technology of manufacturing, assembly and installation of various structures used in civil engineering. The main developers, manufacturers and suppliers of these systems are such large companies as Schueco and Hueck (Germany), New Tec and Indinwest (Italy), Nordic (Finland), Reynaers (Belgium) , "Agrisovgaz", "VSMPO", "MOSMEK" and "Rasstal" (Russia).

The profile systems of these developers and manufacturers are fundamentally similar and differ in individual parts and product range.

The collector itself consists of translucent and ray-absorbing parts connected along the perimeter with each other through an adhesive gasket by means of screw detachable joints.

The translucent part contains a case made of fragments of a “warm” frame aluminum profile of the front window with two heat-insulating inserts and an external seal, corner connectors, a joined glazing bead profile with an internal seal, glazing from one, two or three layers of transparent insulation, as well as plastic linings for glazing and fastens using heat and moisture resistant sealant through an external sealant with moisture-proof adhesive tape and an internal sealant between the cross-strut profiles mi and clamping strips of the facade system of profiles of spatial building aluminum structures, which also includes transparent, of two or three layers of glazing, or opaque filling of light openings, external and internal seals and plastic linings for filling, mounting brackets for crossbar-strut profiles, protective cover profiles for vertical and inclined facades, as well as thermal spacers between clamping strips and crossbar-strut profiles, connected to each other by means of self eznyh screw connectors.

The beam-absorbing part also includes a case made of fragments of a “warm” frame aluminum profile of a window system of aluminum profiles with two heat-insulating inserts, corner connectors and profiled latches joined on one side, and on the other hand a glazing bead profile with rear thermal insulation fixed through an internal seal, as well as an absorber, in wherein the inlet and outlet hydraulic manifolds for the inlet and outlet of the heated fluid and the heating pipes have the same bore diameter p, while inside the latter, a hollow or one-piece cylindrical fairing with double-edged ends is made coaxially made of heat-resistant, moisture-proof or moisture-proof material and provides the required annular clearance for the passage of the coolant by means of spacing ribs, while the value of the outer diameter of the cylindrical fairing D _obt. determined by the ratio:

where n is the number of heating pipes in the solar collector;

D _proh - the value of the bore diameter of the heating pipes and hydraulic manifolds for the supply and removal of the heated fluid.

The basis of this relationship is the condition that if the diameters of the heating pipes and hydraulic manifolds are equal, and therefore, in the absence of constrictions (places of possible formation of air jams), the hydraulic diameter of the heating pipes of the proposed device is equivalent to the hydraulic diameter of the heating pipes of the device selected as a prototype ,

The latter is characterized by the fact that the cross-sectional area of the passage channel of the hydraulic collectors is equal to the total cross-sectional area of the passage channels of the heating pipes:

F _proh = nf _proh ,

- площадь поперечного сечения проходного канала гидравлических коллекторов;here

- cross-sectional area of the passage channel of hydraulic manifolds;

- площадь поперечного сечения проходного канала нагревательных труб.

- the cross-sectional area of the passage channel of the heating pipes.

Then the value of the bore diameter of the heating pipes d _prox can be determined as:

The hydraulic diameter d _{g of the} heating pipes is equal to:

where P _proh = πd _proh is the perimeter of the passage channel of the heating pipes.

The hydraulic diameter d _{g of the} heating pipes with a cowl will be equal to:

- площадь поперечного сечения цилиндрического обтекателя;here

- the cross-sectional area of the cylindrical fairing;

P _proh = πD _proh is the perimeter of the passage channel of the heating pipes;

P = πD _{MBT MBT} - outside the perimeter of the cross section of the cylindrical fairing.

From the condition of equivalence of hydraulic diameters, the above relation follows to determine the value of the outer diameter of the cylindrical fairing D _obt .

To ensure the assembly strength of the translucent and ray-absorbing parts of the solar collector, fragments of the “warm” frame aluminum profile of the front window and fragments of the “warm” frame profile of the window system of aluminum profiles can be fastened together by crimping the corner connectors.

When glazing a translucent part of two or three layers of transparent insulation, as well as when transparent, of two or three layers of glazing, filling the light openings of spatial building aluminum structures, one-chamber or two-chamber glued glass units made in accordance with the requirements of state standard / 7 can be used, respectively / and consisting, respectively, of two or three smooth sheets of transparent glass fastened along the contour with adhesive tape with one or two spacer frames, having dehydration openings for access of air from the inter-glass gap to the internal volume of the latter, filled with a moisture-absorbing molecular sieve, with the formation of sealed chambers between the sheets with a layer of dried air, while the ends of the glass units are treated with a moisture-proof, vulcanizing sealant.

Opaque filling of the light openings of spatial building aluminum structures can be performed in the form of a glued or typeset sandwich panel, the inner layer of which made of foam material has good thermal insulation properties, and the external ones, depending on the material and its thickness, provide the panels with the required structural strength and resistance to impacts of negative environmental factors.

The rear thermal insulation of the beam-absorbing part of the solar collector can be made in the form of a stacked sandwich panel, the inner layer of which is made of fiberglass with good thermal insulation properties, on one side is adjacent to the absorber, and on the other hand is protected from mechanical influences by a sheet of sheet material, which also has good thermal insulation properties .

The cylindrical cowling can be made in the form of a metal tube, to which on both sides hermetically, by welding or soldering, metal conical ends are connected with spacing ribs buried in the latter and engraved in the grooves of the heating pipes.

Figure 1 presents a General view of the solar collector; figure 2 schematically shows a spatial building aluminum structure with integrated solar collector; figure 3 presents a section aa of the solar collector with glazing from one layer of transparent insulation and spatial building aluminum structure with opaque filling of the light openings; figure 4 is a section aa of the solar collector with glazing from two layers of transparent insulation and spatial building aluminum structure with transparent, from two layers of glazing, filling light openings; figure 5 is a section aa of the solar collector with glazing from three layers of transparent insulation and spatial building aluminum structure with transparent, from three layers of glazing, filling light openings; figure 6 presents a section bB of the solar collector with glazing from one layer of transparent insulation and spatial building aluminum structure with opaque filling of the light openings; Fig.7 is a section bB of the solar collector with glazing from two layers of transparent insulation and spatial building aluminum structure with transparent, from two layers of glazing, filling light openings; on Fig - section BB of the solar collector with glazing from three layers of transparent insulation and spatial building aluminum structure with transparent, from three layers of glazing, filling light openings; figure 9 shows the node I of fastening fragments of the "warm" frame aluminum profile of the front window and the node II of fastening fragments of the "warm" frame profile of the window system of aluminum profiles; figure 10 shows a single-chamber (node III) and two-chamber (node IV) glued glass; figure 11 presents an embodiment (node V) of a cylindrical fairing.

The solar collector includes a housing 1 made of profiled material with transparent glazing 2, rear thermal insulation 3, and a pipe-in-sheet absorber in the form of a series of heating pipes 4 interconnected by metal ribs 5 in the plane of the latter and with input 6 and output 7 hydraulic collectors for supplying and discharging heated fluid.

The design of the collector uses elements of the window system of aluminum profiles that are compatible with elements of the facade system of profiles of spatial building aluminum structures.

The solar collector consists of a translucent 8 and a beam-absorbing 9 parts, connected along the perimeter with each other through an adhesive strip 10 by means of screw detachable connections 11.

The translucent part 8 comprises a case of fragments 12 of a “warm” frame aluminum profile of the front window with two heat-insulating inserts 13 and an external seal 14, corner connectors 15, a joined bead profile 16 with an internal seal 17, and glazing 2 of one, two or three layers 18 of transparent insulation, as well as plastic pads for glazing 19, 20, 21 and is fastened using heat and moisture resistant sealant 22 through an external seal 23 with moisture-proof adhesive tape 24 and an internal seal 25 between p needle-rack profiles 26, 27, 28 and pressure strips 29 of the facade system of profiles of spatial building aluminum structures, including transparent, of two or three layers of glazing 30, or opaque filling of light openings, outer 31 and inner 32 seals and plastic linings 33, 34, 35 for filling, brackets 36 for fastening bolt-and-rack profiles, profiles of protective covers 37, 38 for vertical and inclined facades, as well as heat-sensitive spacers 39 between the clamping plates 29 and the bolt-and-rack profiles profiles 26, 27, 28, connected to each other by means of self-tapping screw connectors 40.

The beam-absorbing part 9 also includes a case of fragments 41 of a “warm” frame aluminum profile of a window system of aluminum profiles with two heat-insulating inserts 42, corner connectors 43 and profiled latches 44 joined on one side, and on the other side a glazing bead 45 with a rear fixed through an internal seal 46 thermal insulation 3, as well as an absorber, in which the inlet 6 and outlet 7 hydraulic manifolds for supplying and discharging the heated fluid and heating pipes 4 have the same ohodnoy diameter, with the latter coaxially mounted inside the hollow cylindrical or tselnotelny fairing 47 with double-edged ends, made of temperature-resistant, moisture-proof or waterproof material, and by providing the desired spacing bars 48 an annular gap for the heating medium passage.

Fragments 12 of the “warm” frame aluminum profile of the front window and fragments 41 of the “warm” frame profile of the window system of aluminum profiles can be fastened together by crimping the corner connectors 15 and 43 (Fig. 9).

When glazing 2 of the translucent part 8 of two or three layers 18 of transparent insulation, as well as when transparent, of two or three layers of glazing 30, filling the light openings of spatial building aluminum structures, one-chamber or two-chamber glued glass units can be used, respectively (Fig. 10 ), consisting, respectively, of two or three smooth sheets of transparent glass 49, fastened along the contour with adhesive tape 50 with one or two spacer frames 51 having dehydration openings 52 for access to zduha of inter-glass gap into the interior of the latter, filled with molecular sieve desiccant 53 between the sheets to form a hermetically closed chambers with a layer of dried air, wherein the ends of waterproof insulating glass processed, the vulcanizing sealant 54.

Opaque filling of the light openings of spatial building aluminum structures can be in the form of a glued or typeset sandwich panel, the inner layer 55 of which of foam material has good thermal insulation properties, and the outer 56 and 57, depending on the material and its thickness, provide the panel with the required structural strength and resistance to the effects of negative environmental factors.

The rear thermal insulation 3 of the beam-absorbing part 9 of the solar collector can be made in the form of a stacked sandwich panel, the inner layer 58 of which is made of fiberglass with good thermal insulation properties, on one side is adjacent to the absorber, and on the other hand is protected from mechanical stresses by a layer of sheet material 59, also possessing good thermal insulation properties.

The cylindrical cowling (Fig. 11) can be made in the form of a metal tube 60, to which metal conical ends 61 with spacer ribs 48 embedded in the latter and engraved in the grooves of the heating pipes 4 are sealed on both sides by welding or soldering.

The device operates as follows. The flux of solar radiation 62 (figure 2) falls on the solar collector integrated into the spatial aluminum construction. Glazing 2 of the solar collector has a high transmittance with respect to the incident flux of solar radiation and almost completely absorbs its own thermal radiation from the collector. A tube-in-sheet absorber in the form of a series of heating pipes 4 interconnected by metal ribs 5 in the plane of the latter and with the inlet 6 and outlet 7 hydraulic collectors, interacting with the solar flux passing through the glazing 2, heats up and transfers the absorbed heat to the heated fluid . Part of the heat is lost due to convective and radiative heat transfer between the solar collector and the environment. The heated liquid is suitable for subsequent use in individual solar installations and in solar systems for household and household purposes.

Sources of information

1. Duffy J. A., Beckman W.A. Thermal processes using solar energy: Per. from English - M.: Mir, 1977, 420 p.

2. Krepis IB The sun is for people. - Chisinau: Shtiintsa, 1989, pp. 24-37.

3. Mac-Weig D. Application of solar energy: TRANS. from English - M .: Energy, 1981, p. 44-45.

4. Kharchenko N.V. Individual solar installations. - M .: Energoatomizdat, 1991, p.167-168.

5. Kharchenko N.V. Individual solar installations. - M.: Energoatom-Publishing House, 1991, p.200-201.

6. System profiles for windows and doors: directory-directory. Issue 1 M .: SSK-Inform, 2001, 336 p.

7. GOST 24866-89.

Claims (6)

1. A solar collector, comprising a housing made of profiled material with transparent glazing, rear thermal insulation, and a pipe-in-sheet absorber in the form of a series of heating pipes interconnected by metal ribs in the plane of the latter and with inlet and outlet hydraulic manifolds for supplying and drainage of the heated fluid, characterized in that its design uses elements of the window system of aluminum profiles compatible with elements of the facade system of profiles of spatial building aluminum structures, and the collector itself consists of translucent and ray-absorbing parts, connected along the perimeter with each other through adhesive gasket by means of screw detachable connections, while the translucent part contains a body of fragments of a frame aluminum profile of the front window with two heat-insulating inserts and an external sealant, corner connectors docked with a glazing bead profile with an internal seal, glazing from one, two or three layers of transparent insulation, as well as plastic under glazing, and is fastened using heat and moisture resistant sealant through an external sealant with moisture-proof adhesive tape and an internal sealant between the bolt-resistant profiles and the pressure strips of the facade system of the profiles of spatial building aluminum structures, which also includes transparent glazing of two or three layers, or opaque filling light openings, external and internal seals and plastic pads for filling, mounting brackets for crossbar-rack profiles , profiles of protective covers for vertical and inclined facades, as well as thermal spacers between clamping strips and crossbar profiles, connected to each other by self-tapping screw connectors, and the beam-absorbing part also includes a case made of fragments of a frame aluminum profile of a window system of aluminum profiles with two heat-insulating inserts, corner connectors and profiled latches docked on one side, on the other hand a glazing bead profile with fixed through a morning seal with rear thermal insulation, as well as an absorber in which the inlet and outlet hydraulic collectors for supplying and discharging the heated fluid and heating pipes have the same bore diameter, while inside the heating pipes there is a hollow or one-piece cylindrical cowling with double-edged ends made of heat-resistant, moisture-proof or moisture-proof material and providing, through spacing ribs, the required annular clearance for passage Yes coolant, while the value of the outer diameter of the cylindrical fairing D _rev. determined by the ratio:

where n is the number of heating pipes in the solar collector; D _pass. - the value of the bore diameter of the heating pipes and hydraulic manifolds for the inlet and outlet of the heated fluid. 2. The collector according to claim 1, characterized in that in order to ensure the assembly strength of the translucent and beam-absorbing parts, fragments of the frame aluminum profile of the front window and fragments of the frame profile of the window system of aluminum profiles can be fastened together by crimping the corner connectors. 3. The collector according to claim 1, characterized in that when glazing a translucent part of two or three layers of transparent insulation, as well as transparent, of two or three layers of glazing, filling the light openings of spatial building aluminum structures, one-chamber or two-chamber, respectively, can be used glued double-glazed windows, respectively consisting of two or three smooth sheets of transparent glass, fastened along the contour with adhesive tape with one or two spacer frames having dehydration holes Stia to the air gap of the inter-glass into the internal volume of the latter filled with desiccant sieve to form between the sheets hermetically closed chambers with a layer of dry air, the ends of insulating glass processed waterproof vulcanizing sealant. 4. The collector according to claim 1, characterized in that the opaque filling of the light openings of the spatial building aluminum structures can be made in the form of a glued or typeset sandwich panel, the inner layer of which is made of foam material with heat-insulating properties, and the outer ones, depending on the material and its thicknesses provide the panels with the required structural strength and resistance to environmental factors. 5. The collector according to claim 1, characterized in that the rear thermal insulation of the beam-absorbing part can be made in the form of a stacked sandwich panel, the inner layer of which is made of fiberglass material with thermal insulation properties, is adjacent to the absorber on the one hand and protected from mechanical stress on the other hand. a layer of sheet material with thermal insulation properties. 6. The collector according to claim 1, characterized in that the cylindrical fairing can be made in the form of a metal tube, to which metal conical ends with spacing ribs embedded in the latter and engraved in the grooves of the heating pipes are sealed on both sides by welding or soldering.

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