EP0200876A1 - Arrangement for lighting a room with daylight - Google Patents

Abstract

The daylight enters the room through at least one inner light port which is limited at the top by a flat upper reflector and at the bottom by a parabolic lower reflector. A diagonal beam having a diagonal angle passes through the upper edge of the inlet window and through the lower edge of the inner window. All of the light entering through the light port is emitted into the room above the diagonal beam. To accomplish this, the lower reflector represents, in cross-section, part of a parabola whose main axis passes through the upper edge of the inlet window, and which forms with the vertical an upwardly directed main axis angle. Also, the angle of inclination measured from the main axis of the upper reflector is equal to half the diagonal angle measured in relation to the main axis. By superimposing an outer light port, a given window surface can be better exploited and can be protected from interference light entering from below.

Description

The invention relates to an arrangement according to the preamble of claim 1.

Such an arrangement is known from DE-OS 14 97 348. Several flat reflectors are arranged at a distance one above the other between two window panes, two adjacent reflectors each forming a light shaft with a cross section that is constant over its width. The diagonal angle between a diagonal beam passing through the light well and a reference plane, e.g. the vertical plane is so large that even a person sitting directly at the window can look out through the light wells and their eyes are also hit by multiple reflected rays.

Such a window is practically very bright from all normal viewing angles of a person in the room, i.e. its luminance is in great contrast to the luminance of the walls surrounding the window.

From CH-PS 194 867 it is known to direct the bright zenith light to the work place by deflecting it via mirrors and / or light-refracting plates. As a result, the inner window has a particularly high luminance when viewed from the working position, which is particularly annoying in rooms with VDU workstations.

The invention is therefore based on the object to design each light well in an arrangement according to the preamble of claim 1 so that the entire light passing through it is emitted in a spatial area which is above a diagonal angle which is dimensioned such that the diagonal beam from one The person who is most distant from the window in a workplace is no longer visible.

The inventive solution to this problem is characterized in claim 1. In the invention, the light is emitted into the room at such angles that the inner windows appear dark even from the most unfavorable viewing position. In contrast, the reflective ceiling and the walls opposite the light wells are brightened so that they act as secondary emitters that reflect the light at favorable angles to the workplace. Such illumination not only saves energy but in particular creates a very favorable, glare-free work situation; this also prevents annoying reflections on screens.

The distribution of the luminous flux from a light shaft over the ceiling and the wall opposite the window and in particular also the angle of incidence of the light into the room above the diagonal angle can be varied within wide limits within the scope of the invention: for example, the luminous flux directed onto the window area near the window can be varied above all by setting a main axis angle that deviates from zero. On the other hand, the ceiling section lying further inside in the room receives a larger proportion of light, the smaller the angle of inclination of the flat top reflector.

Another degree of freedom is to choose the focal length of the sub-reflector to be the same, smaller or larger than the height of the entrance window.

It is within the scope of the invention to arrange the inner window of the inner light well or the inner windows of a plurality of inner light wells arranged one above the other in the same plane, which may run vertically or may include an acute angle open at the bottom with the vertical. In the same way, the entrance window of each light well can be arranged in a vertical plane or in a plane inclined towards it.

The invention achieves excellent shielding of the space beneath the diagonal beam. However, this only applies on the condition that no stray light enters the light wells from building reflections at an unfavorable angle. If this is to be expected due to the construction situation, it is advantageous, in accordance with the development of the invention characterized in subclaim 9, to place an outside light shaft in front of each inside light shaft, which shields out stray light coming from below. With this embodiment, a given window area can also be optimally utilized, since the light entry areas of the outside light wells abut one another without gaps. Analogous considerations apply to the parameters of the exterior light well and the light deflection and suppression that can be achieved with them, as explained with reference to the interior light well. The parameters of the light wells can be dimensioned such that the light that is incident in the angular range between the diagonal beam and the main axis of the outer light well is emitted into the interior in an angular range that is in turn limited by the diagonal beam and the main axis of the inner light well.

Light wells lying one above the other - which can also consist of an inner light well and an outer light well - are preferably formed by identical molded bodies arranged one above the other. These can be of such a small width that they can be accommodated in the space between the panes of composite windows. With these small dimensions, it is particularly advantageous to extrude the individual molded parts.

For most applications, it will be sufficient to create moldings which are symmetrical about a central plane, so that interior light wells and exterior light wells with a mirror-image cross section are the same.

In the context of the invention, it is expedient to arrange at least one viewing window below the light wells, for example at eye level of people sitting at workplaces, which enables contact with the outside world; however, this should be covered by a blind.

It is also expedient to arrange sun protection in front of the light wells, through which direct sunlight, e.g. with the help of retroreflection, is kept away from the light wells.

Further refinements of the invention are characterized in the subclaims.

• FIG 1 den Querschnitt durch einen Raum mit erfindungsgemäß angeordneten und ausgebildeten Ihnenlichtschächten,
• FIG 2 einen vergrößerten Querschnitt durch solche Innenlichtschächte,
• FIG 3 einen schematischen Querschnitt durch ein Ausführungsbeispiel, bei dem dem Innenlichtschacht ein Außenlichtschacht vorgesetzt ist, und
• FIG 4 einen Querschnitt durch einen Teil eines Verbundfensters mit besonders einfachen und wirkungsvoll gestalteten Lichtschächten.

The invention is illustrated by the figures; show it

• 1 shows the cross section through a room with viewing light shafts arranged and designed according to the invention,
• 2 shows an enlarged cross section through such interior light wells,
• 3 shows a schematic cross section through an exemplary embodiment in which an inner light shaft is placed in front of an outer light shaft, and
• 4 shows a cross section through part of a composite window with particularly simple and effectively designed light wells.

• Zunächst ist etwa in Augenhöhe M einer an einem Tisch T sitzenden Person ein Sichtfenster Fio angeordnet, das durch eine Jalousie N verdunkelbar ist. Darüber befinden sich zwei Innenlichtschächte Lil, Li2, deren dem Raum zugewandten, vertikalen Lichtaustrittsflächen als Innenfenster Fil, Fi2 bezeichnet sind. Sinngemäß sind die nach außen gerichteten Lichteintrittsflächen als Eintrittsfenster Fml und Fm2 bezeichnet.

The space shown in cross-section in FIG. 1 has a window on its left outer wall, which is not described in any more detail and is divided into sub-areas by internals placed in front of it:

• First, a viewing window Fio is arranged approximately at eye level M of a person sitting at a table T and can be darkened by a blind N. Above are two interior light wells Lil, Li2, the vertical light exit surfaces of which face the room are referred to as interior windows Fil, Fi2. The outward-facing light entry surfaces are referred to as entry windows Fml and Fm2.

The diagonal beam Dil belonging to the light shaft Lil, which passes through the lower edge Uil of the inner window Fil and the upper edge 0ml of the entrance window Fml, includes a vertical diagonal angle α il, which is slightly larger than 90 ° and dimensioned such that this diagonal beam is no longer visible from the eye level M of a person sitting at a table T which is furthest from the window front. The diagonal beam Di thus delimits the area directly illuminated by a light well from an underlying blocking zone Z, which is only illuminated by daylight, which is reflective dete ceiling P and / or the vertical walls of the room has been reflected. This light produces practically no disturbing reflections on a display device G.

Education laws and effect of a light well according to the invention is explained in more detail with reference to FIGS. 2 and 3. In FIG. 2, the basis is first of all that the entrance windows Fml, Fm2 and the inner windows Fil, Fi2 lie in vertical planes V, which have the transverse distance b from one another.

Based on the spatial situation shown in FIG. 1, the diagonal beam Dil with the diagonal angle α il is now drawn in for the lowermost light well Lil: the position of the lower edge Uil of the inner window Fil and the upper edge 0ml of the entrance window Fml is thus determined.

The sub-reflector RUil is arranged here in such a way that the parabola according to which this reflector runs has a vertical main axis, and its focal point Bl lies in the lower edge Oml of the entrance window Fml: the diagonal beam Dil is therefore a focal point beam and thus the distance between the focal point Bl and the lower edge Uil of the inner window Fil is equal to the distance from Uil in the vertical direction from the associated guideline of the parabola. Half the distance of this guideline from the focal point Bl then gives the apex Sl.

Der Neigungswinkel ßil des ebenen Oberreflektors ROil ist gleich dem halben Diagonalwinkel α il, wobei beide Winkel von der vertikalen Hauptachse gemessen sind.The focal length, which is identical to the height of the entrance window Fm, is given by

The angle of inclination βil of the flat top reflector ROil is equal to half the diagonal angle α il, both angles being measured from the vertical main axis.

Using the upper light well Li2, which is constructed according to the same principle, it is shown how focal rays are deflected into the room in parallel at the diagonal angle α i2.

Light rays that hit the sub-reflector RUi2 and do not go through the focal point are all reflected into the room at an angle that is smaller than the diagonal angle α i2, as is illustrated by the dashed beam path.

Due to the location of the diagonal beam Di2, all light entering the room directly through the light shaft must also have an angle which is smaller than the diagonal angle α i2.

If there are several light wells one above the other, it is possible to design these light wells identically, in the same way as the lowest. On the basis of the spatial situation explained with reference to FIG. 1, a different diagonal angle results for each light well. Since this diagonal angle is greater, the higher the light well is, the result is larger entrance and inner windows Fm2, Fi2.

A light well is also indicated on the basis of FIG. 2, which is delimited by a sub-reflector RUi '- shown in dotted lines, the inner window Fi' lying in a plane which, with the vertical V, forms an acute angle which is open at the bottom. Obviously, with such a design, it is possible to create larger window areas with the same shielding conditions.

In the embodiment according to FIG. 2, the entrance window of each light well receives light from an angular range of 180 °. This can be disruptive if lower parts of the building are considered as secondary radiators. It is then expedient to limit the angular range for incident light by means of an outer light shaft placed in front of the inner light shaft, as is shown with reference to FIG. 3: inner window Fi and entry window Fm of the inner shaft Li lie - as in FIG. 2 - in two mutually parallel vertical planes V 2, the main axis Hi of the sub-reflector RUi is inclined by the main axis angle εi with respect to the vertical plane S.

The outside light shaft La is located between an outer window Fa with the upper edge Oa and the lower edge Ua and the entry window Fm of the inside light shaft Li runs, whose focal point B lies in the upper edge 0m of the entrance window Fm and whose main axis Ha is inclined by the main axis angle ε a against the vertical plane S.

Between the upper edge Oa of the outer window Fa and the upper edge Om of the entrance window Fm is a flat upper reflector R0a with an angle of inclination βa towards the main axis Ha.

The diagonal beam Da runs through the lower edge Ua of the outer window Fa and the upper edge Om of the entrance window Fm, which includes an angle of inclination α a with the main axis Ha. The outside light well La only absorbs light and directs it into the inner light well, insofar as its angle of incidence lies in the angular range α a. This light is then emitted into the room in an angular range α i between the diagonal Di and the main axis Hi of the interior light well Li.

In the embodiment of the invention according to FIG. 4, part of a composite window is shown in cross-section, the two window panes which are parallel to one another being designated by 1 and 2. Shaped bodies 3 with an identical cross-section are arranged at an equal distance above one another between these panes, which are also mirror images of a vertical plane S - parallel to the window panes. The surfaces of the shaped bodies are designed to be reflective, in particular reflective, so that an outer light well La and an inner light well Li are formed between the superimposed shaped bodies. The diagonal angle 0 <for the diagonal beam D for the outside light well and the inner light well is identical to 90 ° with respect to the vertical plane S, in which the main axes of the parabolas of the lower reflectors lie: This means that the upper reflectors also have an identical inclination angle ß of 45 °.

An arrangement with shaped bodies of this type receives light from an angular range of 90 ° - between D and S - and emits it over the same angular range - between D and S - against the ceiling and opposite walls of the room.

To suppress direct solar radiation between the light wells and the outer window pane 1 a known sunshade 4 is arranged in the form of rotatable prismatic lenses, which can always be adjusted so that - regardless of the position of the sun - no sunbeam can penetrate the light wells.

List of terms

• Oa, om, oi
• Ua, Um, Ui
• B
• Ha, hi
• ε a, ε i
• There, Tue
• αa, αi
• fa
• Fm
• Fi
• Fio
• G
• La
• Li
• M
• N
• ROa, ROi.
• ßa, ßi
• P
• K
• T
• RUa, RUi
• V, S
• Z
• b
• 1, 2
• 3rd
• 4th
• room
• Top edge
• Lower edge
• Focus
• Main axis
• Major axis angle
• Diagonal beam
• Diagonal angle
• Outside window
• Entry window
• Interior window
• Viewing window
• Data display device
• Outside light well
• Interior light well
• Eye level of a person
• louvre
• Top reflector
• Angle of inclination
• blanket
• Curve point
• table
• Bottom reflector
• Vertical plane
• Exclusion zone
• Transverse distance
• Windowpanes
• Molded body
• Sun protection

Claims (17)

1. Arrangement for illuminating a room with daylight, with an interior light well (between an entrance window (Fm) with an upper edge (0m) and a lower edge (Um) and an inner window (Fi) with an upper edge (0i) and a lower edge (Ui) Li) is arranged with a constant cross-section over its width, which is formed by a lower reflector (RUi) running between the parallel lower edges (Um, Ui) of the entrance and inner window and a flat upper reflector (ROi) extending between the upper edges (0m, Oi) limited and characterized by a diagonal beam (Di) with a diagonal angle (αi), which runs through the lower edge (Ui) of the inner window (Fi) and the upper edge (0m) of the entrance window (Fm), characterized in that that the lower reflector (RUi) is part of a parabola in cross-section, the main axis (Hi) of which runs through the upper edge (0m) of the entrance window (Fm) and with a. Vertical plane (V) includes an acute main axis angle (εi) open towards the ceiling (P) of the room, that the angle of inclination (ßi) of the top reflector (R0i) of the interior light well (Li) is at most equal to half the diagonal angle (αi), the angle of inclination (ßi) and diagonal angle (αi) being measured from the main axis (Hi) of the parabola, that the tangent to the lower reflector (RUi) in the lower edge (Ui) of the inner window (Fi) runs parallel to the upper reflector (ROi),
and that the ceiling of the room is designed to be reflective. 2. Arrangement according to claim 1, characterized in that the inner window (Fi) lies in a plane which includes a downward open acute angle with the vertical plane (V). 3. Arrangement according to claim 2, with a plurality of stacked inner light shafts, characterized in that all the inner windows (Fi) lie in a plane which includes an acute downward open angle with the vertical (V). 4. Arrangement according to claim 1, characterized in that the inner windows (Fi) lie in the vertical plane (V). 5. Arrangement according to one of claims 1 to 4, characterized in that the entrance window (Fm) of the interior light shaft lies in a vertical plane. 6. Arrangement according to one of claims 1 to 4, characterized in that the entrance window (Fm) lies in a plane which includes an acute downward open angle with the vertical. 7. Arrangement according to claim 4, characterized in that the inner window (Fi) and the entrance window (Fm) lie in different vertical planes (V) with the transverse distance (b). 8. Arrangement according to claim 7, characterized in that the main axis angle (εi) of the parabola, according to which the sub-reflector (RUi) runs, is zero and the focal length is given by the relationship

where αi is the diagonal angle, b is the transverse distance of the vertical planes (V), and that the angle of inclination (ßi) of the top reflector (ROi) is equal to half the diagonal angle (αi). 9. Arrangement according to claim 5 or 8, characterized in that between an outer window (Fa) with an upper edge (Oa) and a lower edge (Ua) and the entrance window (Fm) of the inner light shaft (Li), an outer light shaft (La) with a flat Top reflector (ROa) and a bottom reflector (RUa) is arranged, that the lower reflector (RUa) extends between the lower edge (Ua) of the outer window (Fa) and the lower edge (Um) of the entrance window (Fm) and is part of a parabola in cross-section, the main axis (Ha) of which is through the upper edge (0m) of the entrance window (Fm) and includes with the vertical (V) an acute main axis angle (εa) open towards the sky, that the upper reflector (ROa) extends between the upper edge (Oa) of the outer window (Fa) and the upper edge (Om) · of the entrance window (Fm), that the angle of inclination (ßa) of the top reflector (ROa) - measured from the main axis (Ha) - is equal to half the diagonal angle (αa) of a diagonal beam (Da) of the outside light well (La), wherein the diagonal beam (Da) runs through the lower edge (Ua) of the outer window (Fa) and the upper edge (0m) of the entrance window (Fm) and the diagonal angle (αa) is measured from the main axis (Ha). 10. The arrangement according to claim 9 with a plurality of light wells one above the other, characterized in that the outer windows (Fa) lie in a plane which includes a downward open acute angle with a vertical plane. 11. The arrangement according to claim 9 with a plurality of light shafts one above the other, characterized in that the outer windows (Fa) lie in a vertical plane which runs parallel to the plane of the entrance windows (Fm) at a distance, and in that the focal point of the sub-reflector (RUa) the upper edge (Om) of the entrance window (Fm). 12. The arrangement according to claim 11, characterized in that the cross sections of the inner light shaft (Li) and outer light shaft (La) are mirror images of the same to a vertical plane of symmetry (S) in which the entrance windows (Fm) of the inner light shafts (Li) are. 13. The arrangement according to claim 12, characterized in that the main axis angles (εa, εi) of the sub-reflectors (RUa, RUi) are equal to zero. 14. Arrangement according to one of claims 1 to 13, with a plurality of light wells one above the other, characterized in that the inner light wells (Li) are arranged and have such a diagonal angle (αi) that a person who is at one of the window on the most distant work place, sees at eye level (M) no beam of light coming from an interior window (Fi). 15. The arrangement according to claim 14, characterized in that there is a viewing window (Fio) under the light wells at eye level (M) of people sitting at workplaces, which can be covered by a blind (N) or the like. 16. Arrangement according to one of claims 1 to 15, characterized in that a sun protection is arranged in front of the entrance windows (Fm) or the outer windows (Fa). 17. Arrangement according to one of claims 1 to 16, characterized in that the light wells are delimited by superimposed shaped bodies (3) with an identical cross-section and reflecting surfaces.

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