NL7807865A - Solar energy collector - has rectangular metal conduits retained by steel channels in concrete - Google Patents

Abstract

Rectangular sleeves of Al or Cu, with a wall thickness of 0.4-0.5mm, are retained in a mass of a heat storing medium, such as concrete, by 'U'-section channels of corrosion resistant steel 2mm thick, with flanged top edges, to form an arrangement for collecting and storing the heat of the sun. Wall sections of the sleeves form the upper surface of the collector and there are feed and waste connections for the heat conveying medium which flows through the sleeves. The disadvantages of steel tubes which react more slowly to alternating changes in the light intensity due to cloudy conditions are eliminated, and the efficiency of the collector is much improved.

Description

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Nw 5690! Stichting Bouwcentrum j - ROTTERDAM. Inventor: Joannes Marie van Heel

Device for collecting and storing solar heat.

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The invention relates to a device for collecting and storing solar heat, comprising a number of tubes for a heat transport medium, which tubes adjoin, or at least make heat contact with, a storage medium which is kept or forms part of the device, wherein wall parts of the tubes form part of the surface of the device which serves to receive radiation from the sun, while the device furthermore comprises supplying discharge means to and from the tubes for the heat transport medium.

Such a device is known from Dutch patent application T6.03857. In particular, that patent application describes a combined collector and storage device in which the tubes for the heat transport medium have a rectangular profile and are embedded in the storage medium, such that one surface of each tube is uncovered.

When concrete is used as a heat storage medium, in connection with corrosion problems, almost only steel is eligible as the material for the pipes. Usually steel sheet with a thickness of a few millimeters is used. Although the known device is satisfactory with continuous irradiation, the device is less suitable for use in slightly cloudy and variable cloudy weather, due to the relatively slow inertia of the material of the tubes. Also when other heat storage media and other metal are used for the pipes, the device remains relatively slow, because relatively thick metal sheet for the pipes must always be used.

There is therefore a need for a device that can respond quickly to incident radiation and which can be used even with low intensity radiation.

The object of the invention is to provide such a device. According to the invention, the stated object is achieved with a device, wherein the houses consist of substantially closed tubes of thin-walled metal, which are suitably slid into open ü-shaped profile beams of a thicker metal, which U-shaped profile trays are embedded in the heat storage medium or at least with the base of the 5 U limits on the heat storage medium, and which U-shaped profile beams are provided with inwardly directed flanges at the top of the side walls of the beam for holding the tubes in the beam.

In a suitable embodiment of the device according to the invention, the tubes are perpendicular in cross section to the longitudinal axis square and the perpendicular cross section of the profile beams is a U with legs which are substantially equal in length to the base.

In another suitable embodiment, the dimensions of the tubes and of the profile beams and the materials of the tubes and the profile beams are chosen such that. in. a situation in which solar heat is absorbed «15 each tube just does not touch the enveloping profile beam Or just touches it, ♦ The tubes can suitably consist of aluminum or copper or another heat-conducting material and have a wall thickness of the order of 0.¼ up to 0.5 mm. For example, the square cross-section of the tubes can vary from 2 × 2 to 5 ^ 5 cm, although other dimensions may be the same. Although a square cross-section is further preferred, it is also possible to use another cross-section, for example a rectangular one. The tubes can be suitably secured therein after insertion into the profile beams, for example by means of a rivet or the like.

The thin-walled tubes used in the device according to the invention are heated up relatively quickly even with incident radiation of low intensity, so that a heat transport medium to be passed through the device can dissipate the collected heat. In addition, due to the good heat contact between the tubes and the enveloping 30 U-shaped beams, heat is transferred to these beams and hence to the heat storage medium. The construction should be such that if the tubes have already been heated up, but the enveloping beams are still relatively cool, the tubes are at most colorfast in the beams. If they are just not colourfast, the thickness of the air gap between the walls of the tubes and the walls of the beams should not exceed about 0.5 mm, since otherwise no V 7807865: -: s- . - ^ fc '; V; i'y. ; - "‘: ί- -s ^ | SS '* tI "- 3 - good heat conduction from ducts to beams is ensured.

The tubes in the device according to the invention can be suitably formed by folding thin 41 into the desired shape.

sheets of metal, "the tangent ends of the folded sheets by welding or by a". labyrinth fold are attached to each other.

The sleeves can furthermore be provided with a longitudinal seam of such a construction that a clearance of adjacent wall parts is provided, so that a small degree of compression of the sleeves is possible.

When the device according to the invention is being built up, the tubes, after being manufactured, are slid into the profile beams, which can take place before or after these beams have been fixed in or on the device. In order to promote the good sliding or sliding of the tubes in the beams, a thin layer of a material which promotes sliding is to be applied between the tube and the associated beam.

This material, for example, graphite can be applied to the tube or to the inner wall of the beam.

The flanges provided with the profile beams at the ends of the legs of the U should only protrude over a small distance. They only serve to prevent the tube from jumping out of the beam. A width of the flanges of not. more than about 5 nim is sufficient for this. It is not absolutely necessary for the flanges to extend the entire length of the beams. If the flanges are interrupted, the area of the tubes which can be exposed to radiation is advantageously enlarged.

The invention will be elucidated with reference to the drawing, in which: Fig. 1 is a top view of an embodiment of the device according to the invention, Fig. 2 is a cross-sectional view of the device according to Fig. 1, taken along the line II-II.

Fig. 3 is a cross-sectional view of a detail of the device according to Figs. 1 and 2, and Fig. 1 * is a cross-sectional view of another embodiment of the device according to the invention. .

Figure 1 shows a "top view of an embodiment of the device according to the invention. The top shown" will be exposed to solar radiation during operation. The illustrated embodiment mainly consists of a body 1 of a heat storage medium, for instance concrete. A number of beams 2 with a U-shaped profile are embedded in the body 1. The beams 2 are provided with inwardly directed flanges 3 at the ends of the legs of the U. The cross-section shown in Figure 2 clearly shows this. When using concrete as a storage medium, the beams preferably consist of corrosion-resistant steel and have a wall thickness of, for example, approximately 2 mm. As shown in figure 2, the flanges 3 lie in almost the same plane as the surface of the storage medium 1. The flanges 3 protrude only a short distance inwards, for example a distance of no more than about 5 mm *

Tubes of thin-walled metal are slid into the U-shaped beams 2. The material of the tubes 1 is preferably a highly conductive heat material, such as aluminum or copper. The wall thickness of the tubes is, for example, 0.5 to 0.5 mm.

20 The flanges 3 on the U-shaped profile beams 2 serve to hold the U tubes firmly. The dimensions of the sleeves and the profile beams. 2 'should be such that a good heat contact is ensured. The dimensions are, for example, such that when the tubes U are heated by incident radiation in operation and rapidly attain a higher temperature than the slower rising bars 2, the walls of the sleeves it just or barely touch the walls of the beams 2 and the flanges 3 on all sides. An air gap of. no more than about 0.5 mm between tube it and beam 2, stretches of flanges 3 are still permissible without a good heat transfer being lost. In the respective state, the tubes are virtually clamp-tight in the beams 2. A completely clamp-proof state is less desirable because undesired stresses and eating phenomena could then occur.

As shown in figure 1, the tubes 4 open into conduits 5 embedded in the storage medium 1, to which a supply conduit 6, 78, 7, 7, 5, 5 and 5, respectively, a discharge conduit T connects. the top surface of the device are covered by a glass plate, such that an air layer is present between the plate and the top surface. Such a construction is known and is not shown in the figure.

Figure 3 shows a possible structure of the housing for a heat transport medium. The U-shaped "beam 2, provided with flanges 3, is embedded in the heat storage medium 1. The tube 1+ is arranged in the beam 2. The tube U and beam 2 have an almost square cross-section. Suitable dimensions vary, for example, 2x2 up to 5x5 cm.

It will be clear that instead of square sections, other, for example rectangular sections, are also possible. The sleeve U is formed from a thin vej. of a heat conducting material, for example aluminum or. buyer. The sheet is folded into the desired shape by folding. At the location of the seam 8 between the folded edges of the sheet, these edges are folded in a labyrinth shape such that a substantially dense labyrinth fold 9 is formed. A weld may also be provided instead of a labyrinth fold. The advantage of the labyrinth fold is that there is a certain amount of play between the adjoining edges on the spot, so that the tube is somewhat compressible. This increases the allowable tolerance in the dimensions of the tube U relative to the dimensions of the envelope beam 2.

In operation, the device according to the invention reacts very quickly to incident radiation. Thanks to. the use of diagonal wall heat-conducting metal, for the ducts a rapid heating of the ducts takes place even in slightly cloudy or variable cloudy weather, sufficient to heat a heat transport medium which is passed through the ducts. Moreover, with more continuous irradiation of the device, the tubes will be able to pass on the heat collected to the enveloping beams and via them to the heat storage medium.

Another embodiment of the collector storage device according to the invention is shown in figure U. The storage part in this embodiment consists of a casing t0. it is filled with a heat storage medium 11, for example oil. On a surface 35 of the casing * 1.0 there are a "plurality of lead lines erected thereon" \ 7807865 • 6 - ridges 12 * each having flanges 13. confirmed. The corresponding surface forms with adjacent pairs of the ridges 12 a number of parallel U-shaped profile beams, which are mutually attached by the surface. The assembly of casing 10, ridges 125 and flanges 13 may, for example, consist of aluminum, with a thickness of, for example, Λ mm, and may suitably be made in one piece, for example by casting or by extrusion. The tubes 1¼ are located in the U-shaped profiles thus formed. These sleeves are of similar construction and serve the same purposes as the sleeves 104 in the embodiment of Figures 1-3.

When the device according to the invention is being built up, the tubes have to be pushed into the U-shaped profiles at some point, since there is only a slight play between the outer wall of the tubes. the tubes and the inner wall of the U-profiles are recommended on the inner wall of the profiles, on the. on the outer wall of the tubes or on both. a very thin layer. of a material that promotes the sliding of the tubes in the U-profiles. This could include graphite or a similar material.

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Claims (8)

1. Device for collecting and storing solar heat, comprising a number of tubes for a heat transport medium, which tubes adjoin, or at least make heat contact with, a storage medium which is kept in the device or which mows part thereof, wall parts of the tubes being cut out of the surface of the device serving to receive radiation from the sun, while the device further comprises supply and discharge means to and from the tubes for the heat transport medium, characterized in that the tubes consist of substantially closed tubes of thin-walled metal, which are suitably slid into open U-shaped profile beams of a thick-walled metal, which U-shaped profile beams are embedded in the heat storage medium or at least with the base of the U-borders on. the heat storage medium, and which U-shaped profile beams are provided with inwardly directed flanges at the top of the side walls of the beam for retaining the tubes in the beam. 2. Device according to claim 1, characterized in that the tubes perpendicular to the longitudinal axis are square and the perpendicular section of the profile beams is a U with legs of substantially equal length as the base. 3. Device as claimed in claims 1-2, characterized in that the dimensions of the tubes and of the profile beams and the materials of the tubes and the profile beams are chosen such that in a state in which solar heat is collected, each tube has the enveloping profile -25 bar just missing or just hitting l) ·. Device according to claims 1-3, characterized in that the tubes consist of aluminum or copper with a wall thickness on the order of 0.5 to 0.5 mm. . v Device according to claims 1-U, characterized in that the profile beams consist of steel with a wall thickness of the order of 2 mm. Device according to claims 1-5, characterized in that the tubes have a square cross-section with dimensions in the order of 2 by 2 to 5 by 5 cm. 7. Device as claimed in claims 1-6, characterized in that the co 7807865 f; - 8 Λ cherry are formed by folding thin sheets of metal into the desired shape, the tangent ends of the folded sheets being secured together by welding or by a labyrinth fold. 8. Device as claimed in claims 1-7, characterized in that the sleeves are provided with a longitudinal seam of such a construction that a clearance of adjacent wall parts is provided, so that a small degree of compression of the sleeves is possible. 9. Device according to claims 1-8, characterized in that the inwardly projecting flanges of the U-shaped profile beams protrude by a distance of not more than about 5 mm. 10. Device as claimed in claims 1-9, characterized in that a material facilitating sliding of the tubes into the beams is provided between the tubes and the enveloping profiled beams. * (*) 7807865