CH649616A5 - Arrangement for illuminating a room with daylight by means of a reflecting ceiling - Google Patents

Description

The invention relates to an arrangement for illuminating a room with a reflective ceiling with daylight that enters through an opening in a window in an outer wall.

In conventional buildings, in which daylight enters the room through a normal window opening in the outer wall, there is a very uneven light distribution: near the window, the light intensity is very high, especially when exposed to sunlight; However, as the distance from the window increases, it drops very sharply. The resulting large differences in the luminance distribution result in glare for the room users. In order to achieve a sufficiently high level of lighting with satisfactory uniformity, artificial light is often required during the day.

This problem is exacerbated if you try to use the bright zenith light: According to FR-PS 1003 366, an awning made of very light, porous material is attached in front of the window, through which the zenith light is broken and scattered. The awning thus acts as a secondary radiator, but this also increases the contrast between the window opening and the neighboring walls.

The same applies to a solution according to GB-PS 287729: Here totally reflective prisms in front of the window direct the zenith light into the interior of the room.

Finally, from DE-PS 517 827 an arrangement for illuminating a room is known, in which the zenith light is reflected into the room via a reflecting plate and partly reflected against this reflecting ceiling.

But even with such an arrangement, characterized in more detail in the preamble of claim 1, a significant proportion of the light enters the room at such angles that high, disturbing luminance contrasts occur, which can even lead to glare. The invention is therefore based on the object of reducing the differences in luminance between the window opening and its surroundings and, in particular, of avoiding glare to persons in the room by daylight.

The achievement of this object according to the invention is characterized by the features specified in claim 1.

In the invention, the window openings for the people in the room appear relatively dark, since the incident light rays only hit wall and ceiling areas, but not the eyes of the people in the room.

The problem of reducing the differences in luminance between the window opening and the surroundings is known from DE-OS 1797168. There, however, a window with a prismatic lens is proposed which only transmits diffuse radiation, but which reflects directed radiation; however, the bright zenith light is not used.

The minimum value of the angle of the light rays entering the room through the inner prismatic lens depends on the room dimensions. This angle is preferably chosen so large that not only is complete freedom from glare guaranteed, but also all light rays are also reflected back into the room from the ceiling or, if appropriate, from a wall element opposite the window opening; in any case, this angle is at least 70 ".

The ceiling is preferably made of aluminum with a matt surface, which is designed so that there is a considerable amount of directionally reflected light. Its task is to capture the light entering through the window opening as completely as possible and to reflect it in such a way that the reflected light rays form a maximum angle of 45 ° with the vertical: This also completely prevents glare here. The optimal curvature of the ceiling can be calculated or constructed on the basis of this condition. In order to be able to fulfill the condition mentioned in rooms with a normal room depth, the ceiling would have to be pulled down relatively far. To avoid this, the resulting overall curve can be divided into individual sections and, after each section, an upward rear surface can be provided, which is then followed by the next section. These individual sections are preferably marked by nearly

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flat inclined surfaces approximated. With a correspondingly large room depth, there are therefore several inclined surfaces spaced apart from one another, the angle of which relative to the vertical is smaller and the vertical projection is greater, the greater their distance from the window opening.

The prismatic disks expediently extend over the entire length of the outer walls. In this case, a window opening of approximately 20% of the room height is sufficient to achieve uniform glare-free illumination of the entire room, the window opening expediently directly adjoining the ceiling of the room. In addition, customary windows can then be provided, which, however, only serve as visual contact outside and can accordingly be dimensioned small.

With the outer prismatic lens, the prisms lie on the inside, so that the prismatic lens has a flat outer surface. The angle between the underside of each prism of this outer prismatic lens and its flat outer side is advantageously chosen such that rays with an angle of incidence below a predetermined limit value are totally reflected. This limit is set in such a way that practically all direct rays of the sun are subject to total reflection, so that there is no heating of the rooms to be illuminated by the rays of the sun. For this purpose, the back of the prisms of the outer prismatic plate have a reflective coating on the inside, so that the sun's rays are redirected outwards.

According to a further expedient embodiment of the invention, the outer sides of the rear sides of the prisms can also be mirrored: Light rays striking these outer sides are then not refracted again by the prism, but instead are deflected directly into the window opening via this mirroring.

In the interest of the highest possible efficiency, the downward open acute angle between the outer prismatic lens and the vertical is chosen so that the undersides of the individual prisms of the outer prismatic plate form an angle between 80 ° and 100 ° with the vertical: In this case, the Most of the zenith light is directed directly into the window opening without additional reflection.

The invention is explained in more detail with reference to the embodiment shown in the figures. Show it:

Fig. 1 shows a portion of a ceiling and an adjacent outer wall in a schematic representation

Fig. 2 shows the formation of the prismatic discs in an enlarged view.

1 shows a section of an outer wall 1 of a room 2. The outer wall 1 has at its upper end a window opening 11, which is directly adjacent to the ceiling 4 of the room; it is made of matt aluminum, so that there is a diffuse reflection with directed component. The ceiling 4 can also have a perforation and can thus be designed as an acoustic ceiling.

At a distance a1 from the outer wall 1, the ceiling has a first inclined surface 44 inclined against the window opening 11, a second inclined surface 45 at a2 distance and a further inclined surface 46 at a3 distance; the associated angles of inclination with respect to the vertical are denoted by al, al and a3 and the smaller the greater the distance between an inclined surface and the outer wall 1. Conversely, the size of the vertical projection of each inclined surface increases with its distance from the outer wall 1. In front of each individual inclined surface, the ceiling 4 has a horizontal section 41, 42, 43 and a rear surface 47, 48 between such a horizontal section and the present inclined surfaces. The angles of inclination of this rear surface against the vertical are greater than the angles of inclination of the adjacent inclined surfaces: This largely prevents an unfavorable shadow formation.

In the window opening 11 of the outer wall 1, an inner prismatic disc 6 with a vertically running, flat outer side 61 and sawtooth-shaped prisms 62 is arranged on the inner side. The prisms 62 have a substantially horizontally extending upper side 63 which, with the obliquely downwardly extending lower side 64, encloses an angle of approximately 35 °. The length of the upper sides 63 and thus the number of prisms in the window opening 11 is chosen so that the tolerances of the corners and edges associated with mass production have a negligible influence on the overall light control.

In front of the window opening 11 there is an outer prismatic lens 3 with a flat outer side 31, which includes an acute angle u which is open at the bottom with the vertical. On the inside of this outer prismatic disc 3, triangular prisms 32 are arranged in cross section, which run directly next to one another and parallel to one another and parallel to the outer wall 1. They each have an underside 321, which includes an angle co with the flat outer side 31, the size of which is selected such that light rays with an angle of incidence β measured against the horizontal are totally reflected below a limit value g of, for example, 45 °. This angle co is calculated using the formula

(1) 0) = 90 ° - (el + 82)

where the angles el and e2 are calculated according to formulas (2) and (3):

n

1

(3) cose2 =

n

In it n means the refractive index of the material of the prism plate and q the previously mentioned limit value of the angle of incidence β.

The angle i between the outer prism plate 31 and the vertical is selected such that the undersides 321 of the prisms 32 run essentially horizontally. The rear sides 322 of the prisms are vertical on the undersides and are mirrored on the inside of the prism: In this way, totally reflected sun rays are redirected outwards (see beam S2).

A flat plate 5 with a mirrored top 51 is arranged between the outer end of the outer prismatic lens 3 and the lower edge of the window opening 11.

1 shows the course of a beam S with the angle of incidence β: it is first broken against the plate 5 by a prism 32 and deflected by the latter into the window opening 11. The beam is refracted there several times by a prism of the inner prism plate 6 and finally enters space 2 at an angle of approximately 90 °; the beam then strikes the inclined surface 46 and is reflected by it as a beam S 'with an angle of incidence e of less than 45 ° into the room. Rays with a smaller angle of incidence may be directed by the prisms of the outer prismatic lens directly into the window opening 11 without going through the plate 5. At a critical angle g, total reflection finally occurs: beam S1 in FIG. 2. If the angle of incidence becomes even smaller, then the totally reflected beam (S2 in FIG. 2) is reflected outwards again on the mirrored rear side 322 of the prism 32. By appropriately dimensioning the angles p., Q, cü, it can be achieved that practically no direct sun rays enter space 2.

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A total reflection for rays below the mentioned limit angle will expediently only be provided for those prismatic panes which are located in the area of the south side of a building and are therefore exposed to direct sunlight. If this requirement is not met, the prism angle will of course be selected so that as far as possible all incident light rays are broken into the room regardless of their angle of incidence.

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1 sheet of drawings

Claims (8)

649 616 1. Arrangement for illuminating a room with a reflecting ceiling with daylight that enters through a window opening in an outer wall, with an outer prismatic lens arranged in front of the window opening, which has a flat outer side that forms an acute angle with the outer wall that is open at the bottom, and with a flat plate which is formed with a mirror on the upper side and which is arranged between the outer end of the outer prismatic lens and the lower edge of the window opening, characterized in that that the outer prismatic disc (3) on the inside has parallel prisms (32) running parallel and horizontally without gaps, that each prism (32) has a triangular cross-section that extends from the outside (31), a bottom (321) and a back (322 ) is limited, that only the rear side (322) is mirrored, that the underside (321) with the outside (31) encloses an acute angle (co) which is open towards the window opening (11) and which is selected such that rays with a Angle of incidence (β) below a critical angle (q) can be deflected outwards again by total reflection on the underside (321) and reflection on the back (322), that in the window opening (11) an inner prismatic lens (6) with triangular cross-section, parallel and horizontal prisms (62) are arranged such that the light rays incident from the outside on the inner prismatic lens (6) are refracted against the ceiling of the room (2) in such a way that the angles (6) d he light rays in the room - measured below these light rays against the vertical - is equal to or greater than 70 °. 2. Arrangement according to claim 1, characterized in that the ceiling (4) of the room (2) has at least one of the window opening (11) facing flat or curved inclined surface (44, 45, 46), the vertical projection of the window opening (11) parallel runs. 2nd PATENT CLAIMS 3. Arrangement according to claim 2, characterized in that a plurality of inclined surfaces (44, 45, 46) are provided, the vertical projection of which is greater, the greater the distance of such an inclined surface from the window opening (11). 4. Arrangement according to claim, characterized in that the angles of the inclined surfaces in each point are selected so that the light rays reflected by them form at most an angle (e) of 45 ° with the vertical. 5. Arrangement according to claim 2, characterized in that the ceiling (4) between the window opening (11) and the adjacent first inclined surface (44) and between adjacent inclined surfaces (44, 45, 46) has horizontal sections (41, 42, 43) . 6. Arrangement according to claim 5, characterized in that the ceiling between each inclined surface (44,45) and a subsequent horizontal section (42,43) has an inclined rear surface (47,48), the angle of inclination of which is greater than that of the vertical each adjoining inclined surface (44.45). 7. Arrangement according to one of claims 1 to 6, characterized in that the ceiling (4) consists of aluminum with a matt surface. 8. Arrangement according to claim 1, characterized in that the angle on the one hand between the underside (321) of each prism (32) and the vertical and on the other hand between the back (322) and underside (321) is 90 ° in each case.