NL1006619C2 - Double-glazed glass roof for greenhouse or warehouse - Google Patents

Abstract

Double-glazing is used in the roof, linked to the gutters by channels for introducing air into the gap between the glass panes. A greenhouse or warehouse has a roof (1) including at least one ridge profile (2) and gutters (3) mounted on bearings on either side of the ridge, the roof being constructed from glass panels (5) and rods (4). At least some of the glass panels are double-glazed, devices (15) being provided to fill the gap between the panes in the double glazing with a fluid (10) (e.g. air) that has roughly the same refraction index as the panes of glass in the double-glazing. An Independent claim is also included for a building element for the greenhouse or warehouse, comprising a gutter profile with a feed channel (15) linked to the cavity in the double-glazing.

Description

Greenhouse or department store

The invention relates to a greenhouse or department store, provided with upright side walls and a roof with at least one ridge profile and gutter profiles situated lower on either side thereof, the roof comprising glass panels and 5 glazing bars -

Such greenhouses or department stores are known in various embodiments, in which the glass panels usually consist of single glass plates. The use of double glass panels is desirable from the viewpoint of energy savings, but has the drawback that a double glass panel leads to a considerably lower light output in the greenhouse during the day.

The object of the invention is to provide a greenhouse or department store of the type mentioned in the preamble, on the one hand an important energy saving is achieved, while on the other hand the light output in the greenhouse is hardly, if at all, lower.

For this purpose, a greenhouse or department store of the type mentioned in the opening paragraph according to the invention is characterized in that at least part of the glass panels are designed as double-glass panels with two glass plates and an intermediate space and that means are provided for filling the intermediate space. with a liquid, the refractive index of which at least approximately corresponds to the refractive index of the glass plates of the glass panel, respectively. for emptying the gap.

In this way, a greenhouse or department store is obtained, whereby the space between the double-glass panels can be filled with the liquid during the day, so that the double-glass panel behaves as a single glass plate and the light output in the greenhouse is hardly lower than with a few glass panels, the gap can be emptied at night, so that the gap functions as an air cavity and the 1 oc er i :) 2 insulation of the greenhouse is significantly improved and energy consumption is greatly reduced.

According to a favorable embodiment, the means comprise a liquid circulation system with a heat exchanger for discharging the heat which is incorporated in the liquid in the glass panels into a heat storage. As a result, in the greenhouse or the warehouse according to the invention, the heat contained in the liquid can be usefully used, for instance for heating the greenhouse or the warehouse during the night.

According to an advantageous embodiment, the means, in addition to or instead of the said liquid, can supply a sun-blocking liquid to the glass panels. This embodiment has the advantage that a sunshade is possible, which can be completely removed, so that under normal circumstances no reduction of the light output in the greenhouse is caused, as is the case with the usual sunshades. The sun-resistant liquid is preferably such that the long-wavelength heat radiation is absorbed and the short-wavelength growth light is transmitted.

The invention also provides building material for a greenhouse or department store according to the invention.

The invention will be further elucidated hereinafter with reference to the drawing, in which some embodiments of the greenhouse or department store according to the invention are shown highly schematically.

Fig. 1 schematically shows in perspective the roof of a first embodiment of a greenhouse according to the invention.

Fig. 2 schematically shows a cross-section of part of the roof of FIG. 1.

Fig. 3 schematically shows part of the roof of FIG. 1, showing a liquid reservoir and a source of negative pressure.

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Fig. 4 schematically shows a part of an upright wall of an embodiment of a greenhouse or department store according to the invention.

Fig. 5 shows a section of part of the roof 5 of a second embodiment of a greenhouse or department store according to the invention.

Fig. 6 shows with FIG. 3 correspondingly an embodiment in which a liquid circulation system is applied.

FIG. 7 shows very schematically a variant of the embodiment according to FIG. 6.

In FIG. 1 is a highly diagrammatic perspective view of a roof 1 of a greenhouse or department store, which is provided in the usual manner in FIG. 1 not shown 15 uprights, cross trusses and upright side walls. The roof 1 comprises ridge profiles 2, on either side of each ridge profile two lower gutter profiles 3, glazing bars 4 and glass panels 5 extending between the ridge profiles 2 and the gutter profiles 3. In the greenhouse 20 shown, the glass panels 5 are designed as double-glass panels with two glass plates 6 and 7 and an interspace or air cavity 8, as in FIG. 2 is visible. In FIG. 3, the double-glass panels 5 are shown schematically, with spacers 9 being shown, which keep the glass plates 6, 7 at the desired distance from each other.

The use of double glass panels 5 has the important advantage that the insulation value of the glass panels is considerably increased, so that at low outside temperature, especially at night, a considerable energy saving, ie reduction of heating costs, can be achieved. The disadvantage of double glass panels, however, is that the presence of a second glass plate during the daytime causes a significant decrease in the light output in the greenhouse. In the greenhouse described, reduction of the light output is avoided, because means are provided for filling the spaces 8 of the glass panels 5 with a schematically indicated liquid 10, the refractive index of which corresponds at least approximately to the refractive index of the ββ1g 4 index of the glass plates 6, 7, so that with filled gap 8 each double glass panel 5 behaves as a single glass plate. The refractive index of the liquid 10 is preferably equal to the refractive index of the glass plates 6, 7.

Preferably said means comprise a source of negative pressure 11, such as a pump or the like, which is connected to the high side of the glass panels 5, as shown in Figs. 3 is shown schematically. The low side of the glass panels 5 is connected to a supply line which is connected to a schematically indicated reservoir 12 for the liquid 10. The connection line for the source 11 and the connection line for the reservoir 12 are shown in FIG. 3 schematically indicated. In a practical embodiment, the negative pressure source 11 can for instance be connected to a negative pressure channel 13 which is formed in the ridge profile 2 and which is connected via connecting stubs 14 to the interstices 8 of adjacent glass panels 5. The supply of the liquid 10 takes place via a supply channel 15 which is formed in the channel profiles 3 and that through openings 16, of which in fig. 2, only one is visible, is connected to a rod receiving chamber 17 of the gutter profile 3, into which the adjacent glass panels 5 protrude. By generating an underpressure in the interstices 8, the interstices are filled with liquid 10 without air bubbles being formed thereby.

In the case of the greenhouse described, the ones shown in FIG. 4, side walls 18 with double glass panels 5 with glass plates 6, 7 and an intermediate space 8 are schematically shown. These glass panels are separated from each other by intermediate profiles 19. A foot profile 21 is mounted on a foundation 20, which is provided with a supply channel 22 for the liquid 10. This supply channel 22 is connected to the liquid reservoir 12 in a manner which is not shown in more detail. The intermediate profiles 19 are connected to the pipe via a pipe 23 indicated schematically. top side of a glass panel 5 connected to a negative pressure channel 24 of a purlin 25.

The purlin 25 also has a supply channel 26 for the liquid 10, which is connected to the underside of the glass panel 5 that follows in height. The purlin 25 follows another purlin 25, which is constructed in the same manner. the side walls with double-5 glass panels 5 are equipped without loss of light output during the day and with the advantage of a high insulation value at night.

In larger sized greenhouses or department stores, the roof may include a number of purlins 27, as shown in FIG. 5 is 10. When shown in FIG. 5 shown, three successive double-glass panels 5 are used between the gutter profile 3 and the ridge profile 2. The channel profile 3 is designed in the same manner as in the embodiment according to Figs. 1 and 2, wherein the top side of the double glass panel 5 connecting to the gutter profile 3 is connected via an intermediate profile 28 to an underpressure channel 29 of the purlin 27. For supplying the liquid 10 to the next double glass panel 5 the purlin 27 comprises a supply channel 30 which is connected via the intermediate profile 28 to the intermediate space 8 of the glass panel 5.

Similarly, the top of this glass panel 5 is connected to the underpressure channel 29 of the next purlin 27 and the supply channel 30 of this purlin is again connected to the next double glass panel 5. The upper purlin 27 only comprises an underpressure channel 29 for the upper glass panel 5.

It will be clear that in the described embodiments of the greenhouse advantageous use can be made of the higher insulating value of double glass panels, the application of the described means for supplying the liquid 10 to the interstices 8 of the glass panels 5. allows these spaces 8 to be filled with the liquid 10, so that the glass panels 5 behave as a single glass plate and the light output is not reduced. This enables significant energy savings without reducing the light output.

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According to a favorable variant of the greenhouse described, the heat absorbed during the day in the liquid 10 located in the interstices 8 can be utilized by extending the described means with a liquid circulation system, which is schematically shown in FIG. 6 is shown. In this case, the negative pressure source designed as pump 31 is connected with a discharge side to a schematically indicated heat exchanger 32, where the heat is delivered to a storage facility (not shown in more detail). Subsequently, the liquid is fed back into the liquid reservoir 12. In order to further increase the heat yield, according to a favorable variant, each glass plate 6 of the double glass panels 5 located on the outside is provided with a spectrally selective coating layer 33 on the inside. 15 shown in FIG. 7 is schematically indicated by a dashed line. This coating absorbs the long-wave radiation, so that the heat from the sunlight is better dissipated through the circulating liquid 10, while fully transmitting the grow light useful for the products in the greenhouse.

20 The heat stored in the energy storage facility can, for example, be used at night to heat the greenhouse.

In a variant of the greenhouse described, which is not shown in more detail, the means can comprise a second liquid reservoir containing a sun-repellent liquid, for instance a light-reflecting liquid. This sun-resistant liquid can be supplied to the interspaces 8 of the glass panels 5 via the same supply channels or separate supply channels if the sunlight becomes too bright and the temperature in the greenhouse would rise too high. In this variant too, the means can comprise a liquid circulation system for dissipating the heat absorbed by the sun-resistant liquid. In this case, too, the glass plates 6 can be provided with a spectrally selective coating. For example, the light-reflecting properties of the sun-resistant liquid can be obtained by incorporating light-reflecting particles in the liquid.

In the variant with additional fluid reservoir for sun-resistant fluid, such an assembly of supply channels and underpressure channels can be used in the ridge and gutter profiles 2, 3 5 that, for instance, the sun-facing side of the roof 1 is filled with sun-resistant fluid. side facing away from the sun is only filled with the liquid 10.

In the described embodiments, the emptying of the interspaces 8 takes place by switching off the negative pressure source 11 and 10, respectively. the pump 31, whereby the liquid 10 or the sun-protecting liquid automatically flows back via the supply channels 15, 22, 26 and 30 to the relevant reservoir. In order to promote emptying of the intermediate spaces 8, it may be advantageous to coat the inner surfaces of the glass plates 6, 7 with a liquid-repellent layer.

Filling the gaps 8 resp. the emptying thereof can take place by manually switching on or off the described means, in particular the negative pressure source 11 or the pump 31. It is also possible to use a control unit (not shown in more detail) which, depending on the sunlight and possibly the temperature in the greenhouse, fills the gaps 8 with the liquid 10 or the sun-resistant liquid.

It is noted that although in the foregoing there are glass panels and glass plates, the panels resp. plates may also be made of suitable transparent materials other than glass. It is further noted that the liquid 10 and / or the sun-resistant liquid can be chosen such that heat radiation is absorbed as much as possible and the growth light is transmitted as well as possible.

The invention is not limited to the embodiments described above, which can be varied in different ways within the scope of the claims.

1006619

Claims (16)

1. Greenhouse or department store, provided with upright side walls and a roof with at least one ridge profile and gutter profiles situated on either side thereof, the roof comprising glass panels and glazing bars, characterized in that at least part of the glass panels is designed as double glass panels with two glass plates and an intermediate space and that means are provided for filling the intermediate space with a liquid, the refractive index of which corresponds at least approximately to the refractive index of the glass panels of the glass panel, respectively. for emptying the gap. 2. Greenhouse or department store according to claim 2, wherein the means comprise a liquid circulation system with a heat exchanger for discharging the heat which is incorporated in the liquid in the glass panels, to a heat storage. 3. Greenhouse or department store according to claim 2, wherein the glass plates located on the outside of the greenhouse are provided with a coating adapted to absorb long-wave radiation. Greenhouse or department store according to any one of the preceding claims, wherein the means, in addition to or instead of said liquid, can supply a sun-resistant liquid to the glass panels. Greenhouse or department store according to claim 4, wherein the means comprise a reservoir for storing the liquid and / or a reservoir for storing the sun-resistant liquid. Greenhouse or department store according to any one of the preceding claims, wherein the side walls comprise glass panels, which at least partly consist of double glass panels with two glass plates and an intermediate space, which can be filled with the liquid and / or the liquid by said means. sun protection liquid. 1006619 7. Greenhouse or department store according to any one of the preceding claims, wherein the means are provided with supply means for supplying liquid on the low-side of the double-glass panels and of a source of underpressure connected on the high-side. of the double-glass panels. 8. Greenhouse or department store according to claim 7, in which the glass panels extend between a gutter profile and a ridge profile, the gutter profile comprising a supply channel for liquid and the ridge profile comprising a negative pressure channel which is connected to the source of negative pressure, which channels are connected to the interstices of the double-glass panels. Greenhouse or department store according to claim 7, wherein the glass panels extend between a gutter profile and a purlin. between successive purlins, wherein the channel profile is provided with a supply channel for liquid and the purlins are provided with a supply channel for liquid and / or a negative pressure channel which is connected to the source of negative pressure, which channels are connected to the interstices of the double glass panels. Greenhouse or department store according to claims 6 and 8 or 9, wherein a side wall comprises a foot profile with a liquid supply channel, which is connected to the interspace 25 of double glass panels mounted in the foot profile, the top side of these glass panels being included in an intermediate profile which is connected to a negative pressure channel of said means. 11. Greenhouse or department store according to claim 10, wherein the side wall comprises purlins with a liquid supply channel and an underpressure channel connected to the interstices of adjacent double glass panels. Greenhouse or department store according to any one of the preceding claims, wherein the means for filling resp. emptying the gap can be operated manually. Greenhouse or department store as claimed in any of the foregoing claims 1-11, wherein a control unit is arranged 1006619, which fill or resp. emptying the space with liquid or solar control liquid. Building material for a greenhouse or department store according to any one of the preceding claims, comprising a gutter profile with a supply channel, which communicates with a receiving space for a double glass panel. 15. Building material according to claim 14, comprising a ridge profile with a negative pressure channel, which communicates with a receiving space for a double glass panel. Building material according to claim 14 or 15, comprising purlins with a supply channel and a negative pressure channel with connecting means for supplying liquid 15 and 15 respectively. a source of negative pressure. 1006619