DE3309252A1 - Solar collector - Google Patents

Abstract

A solar collector is described, with an absorbing panel (1) which is provided on both sides with a selective absorption layer with an absorption coefficient greater than 0.9 and an emission strength smaller than 0.1, and includes an inlet (11) and also an outlet (12) for a heat transfer fluid. The absorbing panel (1) is surrounded by a housing (2) which is filled with a gas which has a temperature conductivity coefficient of at most 0.015 W/m DEG C and a pressure which is less than the atmospheric pressure. The housing (2) includes a frame (3), two transparent panels (4) inserted into the frame (3), and spacers (20) for the transparent panels (4) which extend transversely through openings formed in the absorbing panel (1). <IMAGE>

Description

The invention relates to a solar collector or sensor with a absor-

bieren plate, which on one side with at least one light-absorbing Layer is provided and inside at least one flow channel for a heat transfer fluid as well as having an inlet and an outlet for the fluid, which pass through the flow channel are connected to each other, and with an absorbent plate enclosing, at least partially translucent and with a thermally insulating gas filled case.

A sun sensor of this type is described in FR-A-2 343 208. The thermally insulating gas in the housing is at atmospheric pressure.

This also applies to a sun sensor known from DE-A 2 610 370 to.

An object of the invention is to provide a sun sensor of the type mentioned in the opening paragraph Art to create an even higher degree of efficiency compared to the known sun sensors owns.

The object is achieved according to the invention in that the housing is filled with a gas that has a coefficient of thermal conductivity of at most 0.015 W / m ° C, and the pressure of the gas is less than atmospheric Pressure is.

The gas pressure is advantageously in the range from 10 to 100 millibars.

A particularly advantageous variant is that the absorbent plate covered on both sides by a selective absorption layer is that the housing on both sides at least locally made of translucent Material consists and that a thermally insulating gas with a pressure that is lower than atmospheric pressure, on both sides of the absorbent plate between this and the housing is provided.

The known sun sensors work on one side. The absorbent Plate is covered on one side by an insulating material, whereby the thermally insulating gas is only on the other side, which is marked with e, 7th small, thermally insulating layer is coated.

Due to a two-sided mode of action, the sun sensor can be used in Presence of white reflectors or mirror reflectors compared to a one-sided functioning sensor with 50 to 80% higher illumination or

Illuminance in both diffuse and direct light Exposed to light.

Sun sensors with an absorbent active on both sides Plate are known per se, for example from FR-A-2 357 832 (design variants according to Fig.

10 and 11). The sensors, however, are not of a thermally insulating one Gas filled under reduced pressure, which helps to achieve higher efficiency a sun sensor active on both sides compared to a one-sided active sun sensor is required.

The invention is illustrated below, for example, with reference to the drawing explained in more detail; 1 shows a side view of a sun sensor, FIG. 2 shows a sectional view of the sun sensor along line II-II in FIG. 1, FIG. 3 is a front view of the sun sensor on a smaller scale and partially broken; FIG. 4 shows a sectional view along line IV-IV in FIG. 3 on a larger scale, and FIG Fig. 5 is a sectional view along line V-V in FIG. 3, the same scale as in Fig. 4 is present.

In the figures, corresponding parts are given the same reference characters assigned.

The housing 2 consists essentially of a rectangular frame 3 and two plates 4 made of hardened <tremp6) glass. The frame 3 is off four omega-shaped mild steel profiles, which with their opening after are directed outside and welded together at the corners.

These profiles are opposite with their outwardly facing edges the side walls or surfaces of the plates 4 are arranged. These are with the frame 3 glued airtight by means of Thiokol and silicone rubber 5.

This housing 2 is vertical with its longitudinal direction horizontal arranged on a base part, for example a roof. This basic part and this roof are preferably covered with a reflective material, wherein reflectors may be provided on the side of the sun sensor on this base part so that the sun sensor receives as much sunlight as possible. The case 2 is welded to the outer surface of the two upper corners of its frame 3 with two Bracket 6 provided. These are used, for example, to grip the sensor when it is Relocation or

Transport, for connecting electrodes in an electrochemical Treatment of the plate 1 used in the frame 3 during the manufacture of the sensor and for attaching the sensor to a vertical wall, for example.

On the inside of the frame 3 are support at various points or support elements 7 for the absorbent plate 1 are welded on. These support elements 7 are angle profiles, the rib of which runs perpendicular to the plates 4. The angle profiles 7 have their edges parallel to this rib on the inner surface of the frame 3 is welded, its angle being directed inwards. That angle or angle section is provided with an incision into which one edge of the absorbent Plate 1 is inserted.

In the lower profile of the frame 3 are still two openings 9 9 10 for an inlet 11 and an outlet 12 of the absorbent plate 1, respectively.

This absorbent plate is a flat radiator plate made of mild steel or copper, coated on both sides with a selectively absorbing layer which has a high absorption coefficient and a low emission strength or has a low emissivity. The absorbent plate is made of two rectangular ones Plates 13 formed, which over their edges 14 over the entire outer circumference with one another are welded. Between the longitudinal edges 14 are in the plates 13 in the transverse direction extending indentations or indentations 15 formed, in their place the Plates 13 are in turn welded together.

In this way, in the absorbent plate 1 on top Side an inflow space 16 and on the lower side an outflow space 17 created, these two spaces 16 and 17 through the channels 18 which run between the indentations 15 are designed to be in communication with one another. The absorbent plate 1 enters the support elements 7 via the welded edges 14. With a thermal Contraction or expansion, the plate 1 can move in the support elements 7 back. and move here. The inlet or the feed 11 opens into the inlet space 16 and extends in the housing 2 from the opening 9 along the absorbent plate up. At the point of this opening is the inlet 11 with a connection 19 provided for a line of a solar energy facility. The outlet 12 extends is between the outlet space 17 and the opening 10 and is at the point of this opening corresponding to a connection 19 for connecting the outlet 12 to the Provided the line of a solar energy facility. The connections 19 are with the Frame welded in such a way that it creates a hermetic seal of openings 9 and 10.

They are used during the electrochemical treatment described above of the absorbent plate 1 is used as electrical contacts.

The selective absorption layer with which the absorbent plate 1 is coated, is chosen depending on the metal from which the panels are made 13 are made. This layer preferably has an absorption coefficient greater than 0.9 and an emissivity or emissivity less than 0.1. This layer must withstand a heat up to 0 to temperatures of about 300 C. The plates 13 can be made of steel, in which case a suitable one Absorption coating is formed by a copper layer, which is a light chemical Oxidation until the formation of a matt black Cu2O was exposed by zinc chromate oxide on zinc, or by chromium oxide on nickel or copper. The plates 13 can be made from Be made of copper, in which case a suitable absorbent layer is a chromium oxide or copper oxide layer.

The space between the absorbent plate 1 and the case 2 is a completely hermetically sealed interior. This room is with one Gas filled with a coefficient of thermal diffusivity of no more than 0 0.015 W / m C, whereby the gas pressure is significantly lower than atmospheric pressure is. The gas pressure is, for example, between 10 and 100 millibars and preferably at about 20 millibars. Preferred or suitable gases are: krypton, xenon, hydrocarbon compounds such as C6H6, C6H12 and chlorinated hydrocarbon compounds such as CHCl3, Freon and CCl4.

In order to avoid that the glass plates 4 under the action of in the housing 2 prevailing negative pressure deform or even break, these plates are kept apart in the interior of the frame 3 by means of spacers 20.

These spacers 20 are made of a middle, widening and again tapering part and two adjoining conical foot pieces formed with their large round base section on the inner surfaces of the Support glass plates 4. The spacers 20 occur with their middle part or The body freely passes through openings 21 in the de-absorbent plate 1. These Openings w1 are provided at the location of an indentation or indentation 15, which is slightly widened at the location of an opening 21. The openings 21 border thus not on the inside of the absorbent plate 1, i.e. they do not open out into the channels 18 of this absorbent plate. The openings 21 and thus also the Spacers 20 are arranged in a rectangular shape. The number of openings 21 and the diameter of the base part or of the bottom of the foot pieces of the spacers 20 depend on the thickness of the glass plates 4. The conical base of the spacer 20 are made of polymethyl methacrylate, polycarbonate or transparent glass to make the Withstand heat. Its middle part or body is made of steel. the Spacers 20 are held by the glass plates 4 themselves in their position, the are pressed against each other by the higher pressure outside the housing 2.

The openings 21 have a diameter which is larger than the cross section of the transversely penetrating portion is the spacer 20; he is like that chosen so that the spacers have no contact with the absorbent plate 1 and this plate is also under the influence of temperature fluctuations can expand freely. This expansion can be very large, as the temperature of the absorbing plate 1 at maximum solar irradiation without plate-0 cooling can reach about 300 ° C.

Since the absorbent plate 1 with its edges with a certain Play occurs in the incisions 8 of the support elements 7 and thus with respect to this Support elements 7 easily is slidable, these support elements can no longer prevent such an expansion.

The sun sensor is for conventional heat transfer fluids, for example such as water. In the feed space 16 can be attached to the inlet 11 subsequent distribution device can be arranged. Because the sun sensor is vertical arranged and the absorbent plate on both sides of an absorbent covering is covered, the sensor receives both with direct irradiation and with diffuse light relatively much solar energy. This amount of energy can be increased as a result be that the sun sensor is placed vertically on a white reflector or reflectors are directed towards the sun sensor.

In that the space between the absorbent plate 1 and the Housing 2 from a gas with a small coefficient of thermal diffusivity and low Pressure is filled and the absorbent plate has practically no contact with the Housing 2 is the heat transfer between the absorbent plate 1 and the housing 2 is extremely low. Thus, the efficiency of the sun sensor is too great at high working temperatures. So when using an absorbent Plate made of mild steel, which is nickel-plated and provided with a layer of chromium oxide, and an absorption coefficient of 0.94 and an emissivity of 0.1 possesses, and wherein'a space between the absorbent plate and the housing 2 is filled with CHCl3 at 20 millibars, the coefficient of thermal diffusivity between the absorbing plate 1 and the outside air only 0.9 W per m2 of the housing and per ° C, giving a coefficient of heat loss of 2 watts per m2 of absorbent Plate and per Oc.

It is obvious that the sun sensor can also be used on one side e.g. on sloping roofs. In such a case, the heat losses thereby prevented be that between the unused Surfaces of the absorbent plate 1 and the glass plate 4 on the opposite Side a thin aluminum foil and / or a glass fiber layer is inserted.

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Claims (9)

Solar collector patent claims 1. Solar collector with an absorbing Plate provided with at least one light-absorbing layer on one side and inside at least one flow channel for a heat transfer fluid as well having an inlet and an outlet for the fluid, which is via the flow channel are connected to each other, and with an absorbent plate enclosing, at least partially translucent and with a thermally insulating gas filled housing, thereby g e k e n n n -z e i c h n e t that the housing (2) with is filled with a gas that has a coefficient of thermal diffusivity of at most 0.015 W / mOC and that the pressure of the gas is less than atmospheric Pressure is. 2. Solar collector according to claim 1, characterized in that g e k e n n -z e i c h n e t that the gas pressure is in the range of 10 to 100 millibars. 3. Sun collector according to claim 2, characterized in that g e k e n n -z e i c h n e t that the gas pressure is about 20 millibars. 4.Sun collector according to one or more of the preceding claims, in that the absorbent plate (1) is on both sides is covered by a selective absorption layer that the housing (2) on both Pages at least locally made of translucent material and that a thermal insulating gas with a pressure less than atmospheric pressure, provided on both sides of the absorbent plate between the latter and the housing is. 5. Solar collector according to claim 4, characterized in that g e k e n n -z e i c h n e t that the housing (2) a frame (3), two side by side attached to this translucent plates, which together with the frame (3) form a hermetically sealed Form space, as well as spacers (20) comprises which the two translucent Separate plates (4) with the absorbent plate (1) for this spacer (20) has openings (21) which are completely on the side of their flow channel (18) and through which the spacers extend transversely without the absorbent Touching plate. 6. Solar collector according to one or more of the preceding claims, in that the absorbent layer has an absorption coefficient greater than 0.9 and an emissivity or emissivity less than 0.1 owns. 7.Sonnenkollektor according to claim 6, characterized g e k e n nz e i c h n e t that the absorbent plate (1) consists of steel and the absorbent layer is formed by one of the following compositions: copper oxide on copper, Zinc chromate oxide on zinc, chromium oxide on nickel and chromium oxide on copper. d.Sonnenkollektor according to claim 6, characterized g e k e n n -z e i c h n e t that the absorbent plate (1) is made of copper and the absorbent Layer is a chromium oxide or copper oxide layer. 9. Solar collector according to one or more of the preceding claims, characterized in that the absorbent plate (1) is in such a way Housing (2) is used that free thermal expansion of the plate is possible is.