NL8300793A - SOLAR COLLECTOR. - Google Patents

Description

* * »* 1 VO 4652 Λ" Solar collector "

The invention relates to a solar collector comprising an absorbing plate, which absorbing plate is provided on at least one side with a light-absorbing layer, internally provided with at least one flow-through channel for a heat-transfer fluid and an inlet and an outlet for this fluid having communicating with each other through the flow-through channel, the solar collector also comprising a housing surrounding the absorbing plate, at least locally transparent and filled with a thermally insulating gas.

A solar collector of this kind is described in FR-A-2 .343,208. However, the thermally insulating gas in the housing is at atmospheric pressure.

This is also the case with the solar collector according to DE-A-2,610,370.

An object of the invention is to provide a solar collector of the intended type which has an even greater efficiency than the known collectors referred to above.

For this purpose, the housing is filled with a gas having a heat conduction coefficient of at most 0.015 W / m ° C at a lower than atmospheric pressure.

In a special embodiment of the invention, the pressure of the gas is in the order of 10 to 100 millibars.

In a preferred embodiment of the invention, the absorbent plate is coated on both sides with a selectively absorbent layer, the housing on both sides is at least locally made of translucent material and is situated on either side of the absorbing plate between this plate and the housing thermally insulating gas under a lower than atmospheric pressure.

The above-mentioned known solar collectors operate on one side. The absorbing plate is covered on one side by insulating material and the thermal insulating gas 8300793 2 * ♦ * r * is only on the other side, which has a heat insulating layer. Obviously, thanks to a double-sided operation, the solar collector in the presence of white reflectors or specular reflectors can be subjected to a 50 to 80% higher exposure, compared to a single-sided working collector, both in diffuse light and in direct radiation.

Solar collectors with a double-sided absorbing plate are known per se, inter alia from 10 FR-A-2.357.832 (embodiments according to figures 10 and 11). However, the collectors are not filled with a thermally insulating gas at reduced pressure, which is necessary for a double-sided solar collector to have a higher yield than a single-sided one.

Other particularities and advantages of the invention will become apparent from the following description of a connector collector according to the invention; this description is given by way of example only and does not limit the invention; the reference numerals refer to the accompanying drawings.

Figure 1 is a side view of a solar collector according to the invention.

Figure 2 represents a section according to the line II-II of figure 1.

Figure 3 is a front view of the solar collector from the previous figures, but drawn on a smaller scale and with partial cut-outs.

Figure 4 represents a section along line IV-IV of Figure 3, drawn to a larger scale.

Figure 5 represents a section according to the line V-V of figure 3, drawn on the same scale as figure 4.

In the different figures, the same reference numerals refer to the same elements.

The solar collector according to the figures consists of 8300793 * * 3 an absorbing plate 1 and a housing 2 therefor.

The housing 2 is mainly formed by a rectangular frame 3 and two plates 4 of tempered glass. The frame 3 is formed by four mild steel omega-shaped 5 profile frames with their opening facing outwards and welded together in the corners. With their outwardly directed edges, these profile strips are situated opposite the side walls of the plates 4. These plates 4 are glued to the frame 3 in an airtight manner by means of thiocol and silicone rubber 5.

This housing 2 is arranged vertically with its longitudinal direction horizontally above a bottom, for example a roof. This bottom and this roof are preferably covered with reflective material and next to the solar collector, reflectors can be arranged on this bottom, so that the solar collector would receive as much sunlight as possible. The housing 2 is provided on the outside of the two upper corners of its frame 3 with two welded brackets 6. These brackets 6 serve for gripping the collector during its displacement, 20 for connecting the electrodes during an electrochemical treatment of the absorber plate 1 mounted in the frame 3 during the manufacture of the collector and for fixing the collector ^ to a vertical wall, for example.

On the inside of the frame 3, supports 7 are welded at various locations for the absorbing plate 1. These supports 7 are angle irons, the corner rib of which is perpendicular to the plates 4. With their edges parallel to this rib, the angle irons 7 are welded to the inside of the frame 3, so their angle is turned inwards. This corner 30 is crossed by a slot 8 in which an edge of the absorbing plate 1 fits.

8300793 f.

• - 4 ___ In the lower horizontal profile strip of the frame 3, two more openings 9 and 10 are provided for an inlet 11 and an outlet 12 of the absorbing plate __ 1, respectively.

5 This absorber plate is a flat radiator plate made of mild steel or copper, which is covered on both sides with a selective absorbent layer with a high absorption coefficient and low emissivity. The absorbing plate is formed by two rectangular plates 13 which are welded together with their edges 14 over the entire circumference. Between the longitudinal edges 14 transverse indentations 15 are provided in the plates 13, at the location of which the plates 13 are also welded together. In this way, an inlet space 16 is formed in the aussorbear plate 1 at the top and a discharge space 17 at the bottom 15, which spaces 16 and 17 are connected to each other by channels 18 which are formed between the indentations 15. With the welded edges 14, the absorbing plate 1 protrudes into the supports 7. In the case of thermal expansion and contraction, the plate 1 with its edges can slide back and forth in the supports 7. The inlet 11 opens onto the inlet space 16 and runs in the housing 2, along the absorbing plate 1 upwards from the opening 9. At the location of the opening 9, the inlet 11 is provided with a connecting piece 19 for a conduit of a solar energy installation.

The outlet 12 extends between the discharge space 17 and the opening 10 and is also provided at the location of opening 10 with a connecting piece 19 for connecting the outlet 12 to the pipe of a solar energy installation. The connectors 19 are welded to the frame 3 so that they ensure the hermetic seal 30 of the openings 9 and 10. They are used as electrical contact in the aforementioned electrochemical treatment of the absorbing plate 1.

8300793 Λ »5

The selectively absorbent layer with which the absorbent plate 1 is coated depends on the metal from which the plates 13 are made. This layer preferably has an absorption coefficient higher than 0.9 and an emissivity lower than 0.1. This layer should be heat resistant to temperatures of about 300 ° C. The plates 13 can be made of steel, in which case a suitable absorbent coating is formed by a layer of copper which has undergone a slight chemical oxidation to black matt Cu20 by zinc chromate on zinc, or by chromium on nickel or on copper. The plates 13 can be made of copper i, in which case a suitable absorbent layer is a layer of chromium oxide or copper oxide.

The space between the absorbing plate 1 and the housing 15 2 is a completely hermetically closed space. This space is filled with a gas with a heat conduction coefficient of at most 0.015 W / meC at a pressure noticeably lower than atmospheric. The pressure of the gas is, for example, between 10 and 100 millibars and is preferably approximately equal to 20 millibars.

Suitable gases are: krypton, xenon, hydrocarbon compounds such as C-H_, C..H and chlorinated hydrocarbons such as CHC1_, O o o L2 3

Freon and CC1 ,.

4

In order to avoid deformation and even breaking of the glass plates 4 due to the underpressure prevailing in the housing 2, these plates 4 are kept apart from each other within the frame 3 by means of spacers 20.

These spacers 20 are formed by a central body which is narrowing widening and by two conical feet which fit against it and which connect with their large round base against the inside of the glass plates 4.

With their body the spacers 20 protrude through openings 21 in the absorbing plate 1. These openings 21 are located at the location of an indentation 15, which indentation at the location of an opening 21 is slightly widened. The openings 21 8300793 «6 4 ft therefore do not face the inside, this is on the channels 18 of the absorbing plate 1. The openings 21 and thus also the spacers 20 are arranged according to a square grid.

The number of apertures 21 and the diameter of the base of the footing of the spacers 20 depend on the thickness of the glass plates 4. The conical feet of the spacers 20 are made of transparent heat-resistant polymethylmetacrylate or polycarbonate or glass. Its central body is made of steel. The spacers 20 are held in place by the glass plates 4 themselves which are pushed together by the higher pressure on the outside of the housing 2.

The openings 21 have a diameter greater than the cross section of the protruding part of the spacers 20, such that the spacers 20 have no contact whatsoever with the absorbing plate 1 and the absorbing plate 1 can also expand freely under influence of temperature changes. This expansion can be quite large, since the temperature of the absorbing plate 1 can reach about 300 ° C at maximum solar radiation and without cooling of the plate. Since the absorbing plate 1 with its edges inserts with a certain play in the slots 8 of the supports 7 and is therefore slightly displaceable relative to the supports 7, these supports 7 do not prevent this expansion either.

The solar collector is suitable for the usual heat transfer fluids such as water. Distributors connecting to inlet 11 may be mounted in the inlet space 16. Because the solar collector is arranged vertically and the absorbing plate 1 is coated on both sides with an absorbing layer, it receives a relatively large amount of solar energy in both direct irradiation and diffuse light. This amount of energy can be increased even further by placing the solar collector 8300793 tr h 7 * *% perpendicular to a white reflector or aiming reflectors at the solar collector.

Because the space between the absorbing plate 1 and the housing 2 is filled with gas with low heat conductivity coefficient and under low pressure and because the absorbing plate 1 has almost no contact with the housing 2, the heat transfer between the absorbing plate 1 and the housing is extremely small, which means that the efficiency of the solar collector is also high at high operating temperatures. When using a mild steel absorbing plate, which is nickel-plated and is provided with a layer of chromium oxide and which has an absorption coefficient of 0.94 and an emissivity of 0.1 and at a space between the absorbing plate filled with CHCl 2 at 20 millibars. 1 and the housing 2, the heat transfer coefficient between the 2 15 absorber plate 1 and the outside air only 0.9 watts per m

V

housing and per 0 C, which corresponds to a total 2 heat loss coefficient of 2 watts per m absorber and per ® C.

It goes without saying, however, that the solar collector 20 can also be used single-sided, for example on sloping roofs. In such a case, the heat losses can be reduced by aluminum foil and / or opposed glass plate 4 opposite the unused sides of the absorbent plate 4. place a glass wool mat.

The invention is by no means limited to the above-described embodiment and within the scope of the patent application many changes can be made to the described embodiment, including as regards the shape, the composition, the arrangement and the number of the parts which are to be realized. the invention.

. j 8300793

Claims (9)

1. Solar collector containing an absorbing plate, which absorbing plate is provided on at least one side with a light-absorbing layer, internally provided with at least one flow-through channel for a heat transfer fluid and which has an inlet and an outlet for this fluid passing through the flow-through channel communicating with each other, which solar collector also comprises a housing surrounding the absorber plate, which is at least locally transparent and is filled with a thermally insulating gas, characterized in that the housing comprises a gas with a heat conductivity coefficient of at most 0.015 W / m ° c is filled at a pressure below atmospheric. Solar collector according to the preceding claim, characterized in that the pressure of the gas is in the order of 10 to 100 millibars. Solar collector according to the preceding claim, characterized in that the pressure of the gas is of the order of 20 millibars. Solar collector according to any one of the preceding claims, characterized in that the absorbing plate is coated on both sides with a selectively absorbent layer, the housing on both sides is made at least locally of translucent material, and on both sides of the absorbing plate, between this plate and the housing, thermally insulating gas is under a less than atmospheric pressure. 5. Solar collector according to previous claim, characterized in that the housing comprises a frame, two translucent plates mounted next to each other, which together with the frame define a hermetically closed space, and spacers which keep the two translucent plates at a distance from each other. while the absorbent plate of 8300793 * 9 is provided with fully spaced openings for these spacers, through which the spacers extend without any contact with the absorbent plate. ! 5. Solar collector according to one of the preceding claims, characterized in that the absorbing layer has an absorption coefficient higher than 0.9 and an I emissivity lower than 0.1. Solar collector according to previous claim, characterized in that the absorbing plate is made of steel and the absorbing layer consists of one of the following combinations: copper oxide on copper, zinc chromate on zinc, chromium on nickel and chromium on copper . j Solar collector according to claim 6, characterized in that the absorbing plate is made of copper and the absorbing layer is a layer of chromium oxide or copper oxide. Solar collector according to one of the preceding claims, characterized in that the absorber plate is mounted in the housing with the possibility of free thermal expansion. 8300793