NL2001271C2 - Reflecting device of solar collector, has lower regulating layer which is provided with duct provided between intermediate wall and lower wall and is provided with structure which is prismatic in cross section - Google Patents

Abstract

The reflecting device (1) has an intermediate wall which is arranged parallel to and at distance from upper wall (3). An upper regulating layer (7) provided with a duct (10) allows light which impinges on upper wall through intermediate wall when duct is filled with transparent resin and reflects light which impinges on upper wall when duct is empty. A lower wall is arranged parallel to and at distance from intermediate wall. A lower regulating layer is provided with structure which is prismatic in cross section.

Description

Title: Reflection device, solar collector, and sloping roof with such a solar collector

The invention relates to a reflection device for controllably reflecting light, such as sunlight, comprising a transparent layer, an absorbent layer which is arranged substantially parallel to the transparent layer, and a control layer which is provided with a liquid channel and which control layer transmits light incident on the transparent layer substantially to the absorbent layer when the liquid channel is filled with a transparent liquid and reflects light incident on the transparent layer when the liquid channel is empty.

US 4270517 discloses a solar collector which automatically switches off when a maximum temperature is exceeded. The solar collector comprises a frame with a bottom and upright walls, which are closed off by a transparent cover plate. A solar energy-absorbing layer has been applied to the bottom. Between the absorbent layer and the cover plate there is an optical scattering layer and a transparent liquid with a refractive index that is approximately equal to the refractive index of the scattering layer. In the presence of transparent liquid, the scattering layer lets in incident sunlight on the cover plate. When the temperature of the solar collector rises above the evaporating temperature of the liquid, the liquid evaporates. Part of the sunlight is then reflected by the scattering layer, as a result of which the temperature of the solar collector falls.

However, the scattering layer is insufficiently effective with significant incident solar energy. As a result, the risk remains that the solar collector reaches the stagnation temperature, i.e. the heat absorption of the solar collector by incident sunlight is greater than the heat dissipation of the solar collector, so that the temperature of the solar collector and / or parts thereof rises until overheating occurs. The solar collector and / or its components can thereby be damaged.

US 4056 094 discloses a solar collector which is provided with a transparent panel and an absorbent plate, which are arranged substantially mutually parallel and spaced apart. There is a channel between the transparent panel and the absorbent plate. The lower surface of the transparent panel has a cross-sectional prismatic structure. In the presence of o z.

liquid in the channel, the sunlight incident on the transparent panel is transmitted to the absorbent plate. If a gas is present in the channel, the sunlight is reflected. A disadvantage, however, is that the reflection of sunlight depends on the time of day. Although the reflection of sunlight at noon 5 works well, especially in the early morning and late afternoon there is a risk that insufficient sunlight can be reflected. The sunlight then has light beams that fall obliquely, which are transmitted to the absorber plate despite the presence of gas in the channel.

From US 4 148 563 a reflection panel is known, which can be used, for example, with solar collectors and greenhouses. The reflection panel comprises two layers of transparent material. The outer surfaces of the reflection panel are flat, while the inner surfaces of the two layers are provided with mating structures that are prismatic in cross-section. If a vapor is present between the layers, the layers are spaced apart and the light incident on the reflection panel 15 is reflected. Cooling condenses the vapor and creates a vacuum that pulls the two layers together. There is then a thin liquid film between the two layers, so that the light incident on the reflection panel is transmitted through the two layers. A disadvantage of this reflection panel is that light is poorly reflected if the light does not fall perpendicularly or not substantially perpendicularly into the reflection panel. Furthermore, for the operation of the reflection panel, the layers must be precisely matched to each other. In addition, the two layers of the reflection panel form moving parts, which adversely affects reliability.

It is an object of the invention to provide an improved reflection device

This object is achieved according to the invention in a reflection device as defined in claim 1, a solar collector as defined in claim 12 and a sloping roof as defined in claim 13.

The liquid channels are provided with a structure that is predominantly prismatic in cross-section. The cross-sectional prismatic structure is, for example, arranged substantially parallel to the transparent layer and the absorbent layer 30 between them. The reflection of sunlight on the reflection device according to the invention is controllable by means of the cross-sectional prismatic structure in cooperation with the transparent liquid, for example water or alcohol. The structure has protrusions that are prismatic in cross-section. When the prismatic structure in cross-section is in contact with the transparent liquid, this structure essentially transmits light from the transparent layer to the absorbent layer. If the cross-sectional prismatic structure borders on a vacuum, vapor or gas, such as air, light incident from the transparent layer is substantially reflected. It has been found that such a prismatic structure can reflect light particularly effectively - so-called "total reflection" occurs when light rays are incident.

According to the invention, the control layer comprises at least two partial layers which are arranged adjacent to each other. The sublayers are herein provided with a first structure and a second structure, each of which is prismatic in cross-section. In this case, two prismatic structures are placed one above the other. As a result, the effectiveness of the reflection device increases with obliquely incident light rays. The angle of incidence changes as the upper partial layer passes. The lower sublayer can refract the light rays transmitted through the upper sublayer. When applied for the reflection of sunlight, the reflection device spread over the day is effective, and not only around noon.

In use, the liquid channel is provided with a transparent liquid which is in contact with the cross-sectional prismatic structure for substantially transmitting light through the control layer, the transparent liquid being able to evaporate from the liquid channel for substantially reflecting light through heating due to the cross-sectional prismatic structure of the control layer.

When the prismatic structure is filled with the transparent liquid, sunlight that falls on the transparent layer is transmitted through the control layer substantially unimpeded. This gives rise to warming of the absorbent layer. If the temperature rises above a limit value, evaporation of the transparent liquid occurs. The prismatic structure then no longer borders on the transparent liquid, so that the incident light rays reflect against the surfaces of the cross-sectional prismatic structure. The reflection device according to the invention hereby makes intrinsic protection against overheating possible.

Optionally, the reflection properties of the reflection device according to the invention can be adjusted by actively removing or applying the transparent liquid. In this case, the reflection device not only provides intrinsic protection, but the reflection device can be controlled.

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In one embodiment, the prismatic structure is facing the absorbent layer and is spaced therefrom, the liquid channel for the transparent liquid being formed between the prismatic structure and the absorbent layer. In this case, the prismatic surface of the structure 5 faces the absorbent layer, which is favorable for the reflectivity of the structure in the absence of transparent liquid.

It is possible for the control layer to have an upper surface that faces the light, the upper surface being substantially flat. If the light falls straight on the upper surface, such as around 12 o'clock in the case of sunlight, the light is transmitted to the absorbent layer. If the transparent liquid has disappeared from the prismatic structure due to evaporation or otherwise, the light rays are substantially completely reflected.

Preferably, the first structure and second structure of the partial layers are each facing the absorbent layer, the prismatic first structure of the first partial layer being spaced apart from the absorbent layer to form a first liquid channel for the transparent liquid between them, and wherein the prismatic second structure of the second sublayer is spaced apart from the first sublayer to form a second fluid channel for the transparent fluid therebetween.

The prismatic structure can be implemented in various ways.

For example, the structure is provided with elongated ridges that are prismatic in cross-section. In addition, the structure may have pyramid-shaped protrusions or may be formed differently.

The ridges of the prismatic structure are connected via intermediate walls to a support layer that rests against the absorbent layer. The intermediate walls extend in the longitudinal direction of the ridges. The partitions not only provide structural strength, but also form part channels for the transparent liquid. A subchannel is formed between the ribs or a plurality of ridges, the opposite support layer and two intermediate walls. The adjacent sub-channels together form the liquid channel. This is favorable for the flow of liquid through the liquid channel.

It is possible that the ridges of the control layers each comprise a top, the tops of the ridges of the first structure being aligned with respect to the tops of the ridges of the second structure. Alternatively, it is possible that the ridges of the control layers each comprise a top, the tops of the ridges of the first structure being offset from the tops of the ridges of the second structure. In a particular embodiment, the tops of the ridges of the first structure lie substantially midway between the tops of the second structure.

The reflection of sunlight in the absence of fluid is therefore relatively high even with obliquely incident light rays.

In one embodiment, the transparent layer comprises a cover plate which is arranged at a distance from the upper surface of the control layer facing the sunlight. The cover plate forms, for example, the outside of the reflection device on which light is incident. The cover plate is spaced above the upper surface of the adjacent control layer. Between the cover plate and that top surface there is an air-filled or vacuum gap. This gap ensures that convection cannot or hardly occur - the gap forms an insulating layer. This reduces heat losses.

It is possible that the transparent layer and / or the absorbent layer and / or the control layer comprise plastic. The transparent layer and / or the absorbent layer and / or the control layer are, for example, made of polycarbonate. The intrinsic protection against high temperatures makes the use of relatively inexpensive plastics possible.

For example, the transparent layer and / or the absorbent layer and / or the control layer is extruded. The transparent layer, the control layer and the absorbent layer can also be integrally formed by co-extrusion. The manufacture of a single panel in which the transparent layer, the control layer and the absorbent layer are integrated is relatively inexpensive. However, the prismatic structure can also be designed differently - for example, the prismatic structure is formed by a foil layer.

The thickness of the control layer is determined by the height of the structure or structures arranged one above the other. The height of each structure is, for example, between 10 µm and 5 mm. If the structure is formed by a foil which is arranged in the control layer, the height thereof can be in the order of pm. For example, when extruding a plastic control layer, the height of each structure is 2 or 3 mm.

The invention also relates to a solar collector for converting solar energy into heat, comprising a transparent layer, a solar energy-absorbing layer, which is arranged substantially parallel to the transparent layer, and a control layer which is provided with a liquid channel, and which control layer substantially transmits light incident on the transparent layer to the absorbent layer if the liquid channel is filled with a transparent liquid and reflects light incident on the transparent layer when the liquid channel is empty.

According to the invention, the liquid channel is provided with a structure that is prismatic in cross-section. As long as the prismatic structure of the solar collector control layer is filled with the transparent liquid, the control layer lets the sunlight through. The solar collector heats up under the influence of the incident sunlight. When the temperature has risen such that the transparent liquid evaporates, the prismatic structure forms a reflection surface for the incident sunlight. This makes the solar collector intrinsically protected against overheating. The solar collector is possibly designed in such a way that the transparent liquid can be removed by the intervention of an operator. The reflection properties are therefore adjustable.

The heated transparent liquid in the solar collector can be used as a heat carrier, i.e. the heated transparent liquid can for instance be collected in a storage vessel and subsequently used for space heating and / or tap water heating.

In one embodiment, the absorbent layer is provided with channels for a heat-bearing fluid. Instead of directly applying the transparent liquid in the liquid channel for heating, it is possible that this liquid is in heat-exchanging contact with a heat-bearing fluid in the channels of the absorbent layer. The heat-carrying fluid, such as water, is then, for example, collected in a storage vessel and subsequently used as hot tap water or in a heating installation.

In this case, since the transparent liquid in the liquid channel is separated from the heat-bearing fluid in the absorbent layer, the transparent liquid in the liquid channel can be adapted to the desired properties for reflecting and transmitting light in combination with the material of the control layer .

The features of the dependent claims relating to the reflection device are also applicable to the solar collector according to the invention.

The invention also relates to a sloping roof comprising a solar collector as described above, wherein the or each structure is provided with elongated ridges 7 which are prismatic in cross-section, and wherein said ridges extend in the roof slope direction. As a result, the influence of the height of the sun is minimal, i.e. the efficiency of the solar collector is hardly, if at all, dependent on the season. However, the reflection varies with the time of day - at 12 o'clock in the afternoon the incident solar energy is maximized and the solar collector reflects sunlight almost completely without the transparent fluid in the fluid channel.

To give the solar collector an attractive appearance, the solar collector can, for example, have the shape of a roof tile. As a result, the solar collector can be discreetly incorporated into the sloping roof.

The invention will now be further elucidated with reference to the accompanying drawing.

Figure 1 shows a cross-sectional view of a first embodiment of a reflection device according to the invention.

Figure 2a shows the reflection of a light beam through the prismatic structure of the reflection device shown in Figure 1.

Figure 2b shows the passage of a light beam through the prismatic structure of the reflection device shown in Figure 1.

Figure 3 shows a cross-sectional view of a second embodiment of a reflection device according to the invention.

Figure 4 shows a cross-sectional view of a third embodiment of a reflection device according to the invention.

Figure 5 shows a sloping roof, which is provided with a reflection device according to the invention.

Figure 6 shows schematically a heating system with a solar collector according to the invention.

Figure 1 shows a reflection device 1, which can also be used as a solar collector. The reflection device 1 comprises a transparent layer 3 for receiving sunlight. The transparent layer 3 is formed by a panel. The transparent layer 3 has a cover plate 4 which defines the outer side 30 of the reflection device 1 facing the sun. An insulating layer 2 is formed between the cover plate 4 and the upper surface 8 of the control layer 7. On the opposite side of the control layer 7 there is an absorbent layer 5 for absorbing solar energy. The absorbent layer 5 forms the so-called absorber plate and is usually black.

In this exemplary embodiment, the cover plate 4 is arranged remotely by means of intermediate walls 15 of a control layer 7 for controlling the reflection of sunlight. However, the partition walls 15 can be omitted (not shown).

The control layer 7 has a structure that is prismatic in cross-section. In this exemplary embodiment, the prismatic structure is formed by elongated ridges 14 that face the absorbent layer 5. The ridges 14 extend substantially straight over the lower surface of the control layer 7. In cross-section, the ridges 14 are prismatic, i.e. the ridges 14 each define a triangle in cross-section. If the solar collector 1 is placed on a sloping roof, the ridges 14 run in the roof slope direction.

The ridges 14 each comprise a tip 17 that faces the absorbent layer 5. The ridges 14 are arranged at a distance from the absorbent layer 5. A fluid channel 10 is formed between the ridges 14 and the absorbent layer 5. The prismatic structure of the control layer 7 defines the fluid channel 10. During normal operation, the fluid channel 10 is filled with a transparent fluid 9. The refractive index of the transparent fluid 9 is preferably substantially equal to the refractive index of the material of the prismatic structure of the control layer 20 7. However, this is not necessary for the operation of the control layer 7.

In this exemplary embodiment, one or more ridges 14 are bounded by further intermediate walls 15, which extend in longitudinal direction therebetween. As a result, the liquid channel 10 is divided into sub-channels 16. The intermediate walls 15 between the ridges 14 and the absorbent layer 5 are optional.

The operation of the control layer 7 is shown in figures 2a and 2b. If the transparent liquid 9 is included in the liquid channel 10, the incident light rays are transmitted through the ridge 14 (see figure 2b). The incident sunlight heats the absorbent layer 5, so that the temperature rises. When the evaporating temperature of the transparent liquid is exceeded, it evaporates from the liquid channel 10. The ridge 14 then forms a transition between the material of the control layer 7 and the air present in the liquid channel 10. FIG. A light beam incident directly from above then reflects on the surfaces of the ridge 14 (see Fig. 9 2a). Switching from pass through to reflect is also possible by deliberately removing the transparent liquid from the liquid channel 10.

Figure 3 shows a second embodiment of the reflection device or solar collector 1 according to the invention, in which the same or similar parts are indicated with the same reference numerals. The control layer 7 has two partial layers, each of which is provided with a structure 11, 12 which is prismatic in cross-section. In this exemplary embodiment, each prismatic structure 11, 12 has elongated ridges 14 facing the absorbent layer 5. Liquid channels 10 for receiving transparent liquid are situated between the ridges 14 of the lower structure 12 and the absorbent layer 5 and between the ridges 14 of the upper structure 11 and the upper surface of the lower structure 12.

The tops 17 of the ridges 14 of the prismatic structures 11, 12 are aligned with respect to each other in this exemplary embodiment. However, the tops 17 may be offset relative to each other (not shown).

Figure 4 shows a third embodiment of the reflection device or solar collector 1 according to the invention, in which the same or similar parts are indicated with the same reference numerals. The absorbent layer 5 is provided with internal channels 20 for receiving a heat-carrying fluid. The transparent liquid in the liquid channel 10 is hereby separated from the heat-bearing fluid.

The parts of the reflection device or solar collector 1 can be made of plastic, such as polycarbonate. The production costs are therefore relatively low, in particular if extruding is used.

Figure 5 shows schematically a sloping roof 80, which is provided with a reflection device or solar collector 1 as described above. The elongated ridges 14 of the prismatic structure extend in the roof slope direction, which is indicated by arrow P. As a result, the influence of the height of the sun is minimal, i.e. the efficiency of the solar collector is not or hardly dependent on the season. The reflection does, however, vary with the time of day.

Figure 6 shows schematically a heat system for converting solar energy into heat. The heat system comprises a solar collector 1, which is, for example, designed as described above. The solar collector 1 has a fluid inlet 22 and a fluid outlet 23 for supplying and discharging the transparent fluid. The fluid inlet 22 and the fluid outlet 23 are mutually connected outside of the solar collector 1 by a circulation conduit 24.

The circulation line 24 extends through a heat exchanger 27. The heat exchanger 27 has a heat-absorbing line 28 which is in heat-exchanging contact with the circulation line 24 in the heat exchanger 27. Incidentally, the transparent liquid from the liquid channel can optionally be used directly without intervention of a heat exchanger (not shown). In this exemplary embodiment, a circulation pump 26 is included in the circulation line 24. However, the circulation can also take place as a result of natural convection, i.e. the circulation pump is then superfluous.

An open reservoir 25 is connected via a conduit 30 to the solar collector 1. The open reservoir 25 and the conduit 30 are filled with the transparent fluid 9. When evaporating and condensing the transparent fluid 9, the level in the open reservoir 25 changes. It is possible that instead of an open reservoir, another system for compensating for pressure difference is used, such as a closed reservoir or expansion vessel.

The invention is of course not limited to the exemplary embodiments represented in the figures. The person skilled in the art can make various modifications that fall within the scope of the invention. For example, the reflection device 20 is not only suitable for a solar collector, but also for a solar cell or other applications where it is desirable to limit incoming solar energy when a maximum temperature is exceeded. Also, the reflection device according to the invention is not limited to sunlight applications - the reflection device is also suitable for controlling the reflection of light from other light sources.

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Claims (13)

A reflecting device (1) for controllably reflecting light, such as sunlight, comprising a transparent layer (3), an absorbent layer (5), which is arranged substantially parallel to the transparent layer (3), and a control layer (7), which is provided with a liquid channel (10), and which control layer (7) transmits light incident on the transparent layer (3) substantially to the absorbent layer (5) when the liquid channel (10) is filled with a transparent liquid (9) and light incident on the transparent layer (3) when the liquid channel (10) is empty, the liquid channel (10) having a structure (11) that is prismatic in cross-section, characterized in that: that the control layer (7) comprises at least two sub-layers, which are arranged adjacent to each other, and that the sub-layers are provided with a first structure (11) and a second structure (12), each of which is prismatic in cross-section. 15 Reflective device according to claim 1, wherein the liquid channel (10) is provided with a transparent liquid (9) which is in contact with the cross-sectional prismatic structure (11) for substantially transmitting light through the control layer (7) and wherein the transparent liquid (9) can evaporate from the liquid channel (10) by heating to substantially reflect light through the cross-sectional prismatic structure (11) of the control layer (7). 3. Reflective device according to claim 1 or 2, wherein the prismatic structure (11) is facing the absorbent layer (5) and is arranged at a distance therefrom, the liquid channel (10) for the transparent liquid (9) being formed between the prismatic structure (11) and the absorbent layer (5). 4. Reflecting device according to one of the preceding claims, wherein the control layer (7) has an upper surface (8) that faces the light, the upper surface (8) being substantially flat. Reflective device according to one of the preceding claims, wherein the prismatic structure (11) is provided with elongated ridges (14) which are prismatic in cross-section. The reflecting device according to claim 5, wherein the first structure (11) and second structure (12) of the sublayers are each facing the absorbent layer (5), and wherein the prismatic first structure (11) of the first sublayer is spaced from the absorbent layer (5) to form a first fluid channel for the transparent fluid (9) therebetween, and wherein the prismatic second structure (12) of the second sublayer is spaced apart from the first sublayer to form a second fluid channel for the transparent fluid (9) between them. 7. Reflecting device according to claim 6, wherein each structure (11, 12) is provided with elongated ridges (14) which are prismatic in cross-section, the ridges (14) each comprising a top (17), and wherein the tops (17) of the ridges (14) of the first structure (11) are aligned with respect to the tops (17) of the ridges (14) of the second structure (12). A reflective device according to claim 6, wherein each structure (11, 12) is provided with elongated ridges (14) which are prismatic in cross-section, the ridges (14) each comprising a tip (17), and wherein the tips ( 17) of the ridges (14) of the first structure (11) are offset from the tops (17) of the ridges (14) of the second structure (12). 25 Reflecting device according to one of the preceding claims, wherein the transparent layer (3) comprises a cover plate (4) arranged at a distance from the upper surface (8) of the control layer (7) facing the sunlight. Reflecting device according to one of the preceding claims, wherein the transparent layer (3) and / or the absorbent layer (5) and / or the control layer (7) comprises plastic. The reflecting device according to claim 10, wherein the transparent layer (3) and / or the absorbent layer (5) and / or the control layer (7) is extruded. 12. Solar collector for converting solar energy into heat, comprising a transparent layer (3), a solar energy-absorbing layer (5), which is arranged substantially parallel to the transparent layer (3), and a control layer ( 7), which is provided with a liquid channel (10), and which control layer (7) substantially transmits light incident on the transparent layer (3) to the absorbent layer (5) when the liquid channel (10) is filled with a transparent liquid (9) and reflects light incident on the transparent layer (3) when the liquid channel (10) is empty, the liquid channel (10) having a structure that is prismatic in cross-section, characterized in that the control layer (7) ) comprises at least two sub-layers, which are arranged adjacent to each other, and that the sub-layers are provided with a first structure (11) and a second structure (12), each of which is prismatic in cross-section. 13. Sloping roof comprising a solar collector (1) according to claim 12, wherein the structure is provided with elongated ridges (14) that are prismatic in cross-section, and wherein said ridges (14) extend in the roof slope direction.