NL1038139C2 - TILE WHICH LIGHT SOURCES INCLUDES. - Google Patents

Description

Tile which includes light sources

The present invention relates to a tile which comprises a housing, a light-transmitting cover and a plurality of light sources arranged in the housing 5.

Such a tile is known in the art, for example from US2005116667. This describes that there is a problem with the heat development within the tile, and some solutions are mentioned [0227]. This problem especially applies to tiles that have been laid in a place where the sun has relatively much access. Not only does the sun cause the temperature in the tile to rise further, but in order to be able to see the light sources properly (i.e. that sufficient contrast is present), these must be relatively bright, and this is accompanied by additional heat development. Heat development can have a negative effect on the service life of the electronic components in the tile, such as LEDs used as light sources, and electronics used to control the light sources.

The present invention has for its object to provide a tile in which the heat problem is effectively reduced.

For this purpose a tile of the type mentioned in the preamble is provided, which is characterized in that - the housing comprises a thermally conductive wall, which housing has a first chamber on the side of the light-transmitting cover and a second chamber which is remote from the light-transmitting cover is located, which second chamber is separated from the first chamber by an internal wall; - the light sources are in the second chamber and are connected to the housing via a thermally conductive contact element; and - the first chamber is light-absorbing over a part thereof and the inner wall is partly light-transmissive for transmitting light from the light sources in the second chamber to the light-transmitting cover.

With such a tile a high contrast is associated with a limited heat load of components present in the tile. In the present application, in connection with a thermally conductive wall and a thermally conductive contact element, "thermally conductive" is understood to mean a conductivity with a heat conductivity coefficient 1038139 2 cient> 10 W / (m * K). The thermally conductive contact element is, for example, in the form of a plate which is in (thermally conductive) contact with the thermally conductive wall. The tile is preferably an interactive tile, i.e. a tile that is equipped with a sensor for determining the presence of a person on or near the tile. Such tiles can be used with a variety of games. Although it is possible to solve the heat problem by the presence of a circuit which switches the tile off in case of too high a temperature, this limits the possibilities of use of the tile and / or leads to disappointment for those who want to use the tiles. play. It is also possible to reduce the light output, by not using one or more light sources in the tile or by having light of a lower intensity emit light, but this means that visibility is reduced, which can impair visibility and the fun of the game. The tile according to the invention makes it possible to combine good visibility with high availability.

To increase the contrast, it is preferable that the light-absorbing part of the first chamber absorbs at least 50% of the visible light falling on the light-absorbing part, preferably at least 75%.

For limiting the supply of heat from the first chamber to the second chamber, it is preferable that the light-absorbing part of the first chamber is at least a part thereof at a distance from the inner wall.

In order to further limit the supply of heat from the first chamber to the second chamber, it is preferable that a heat radiation be reflected between the light-absorbing part of the first chamber which is remote from the wall and the wall element is present.

The heat radiation reflecting element is, for example, aluminum foil.

To further limit the supply of heat from the first chamber to the second chamber, it is preferable that the internal wall is made of a thermally insulating material.

When heat radiation reflecting foil and / or a layer of thermally insulating material are used, these too are designed such that light from the LEDs can exit the tile 200 via the opening 213.

3

In the present application, a thermally insulating material is understood to mean a material with a heat conductivity coefficient <1 W / (m * K).

According to a favorable embodiment, the internal wall 5 comprises a light-transmitting material selected from the group consisting of plastic and glass.

These materials make it possible to substantially limit heat transfer from the first chamber to the second chamber, while on the other hand light can exit the tile relatively unhindered from the second chamber and the light-transmitting cover.

For limiting heat conduction through flow, it is preferable that the first chamber is airtightly separated by the inner wall of the second chamber.

For limiting the amount of heat development, it is preferred that at least a portion of the light sources are LEDs.

For dissipating heat from the tile in a simple and efficient manner, it is preferable that the thermally conductive wall is a metal wall.

This is, for example, made of aluminum, which material is not only heat-conducting but also very durable (corrosion-resistant).

For dissipating heat from the tile in a simple and efficient manner, it is also preferable for the same reason that - the housing is of thermally insulating design at the top; And - the housing is thermally conductive on the underside.

According to a favorable embodiment, the thermally conductive connection of the printed circuit board to the housing is passed through a water-tight and flexible plate.

Thus, the housing can move slightly around the electronics, making pressure sensitivity possible in a simple manner.

The present invention will now be elucidated with reference to the drawing, in which Figs. 1a-c respectively represent a top view, a side view and a bottom view of a tile according to the invention; and Fig. 2 shows a cross-section along the line II-II of Fig. 1; and Fig. 3 shows a cross-section along the line III-III of Fig. 2.

4

In the figures and the description thereof, the first digit of a reference number indicates the figure number. FIG. 1a-c shows a tile 100, which as housing comprises an aluminum outer tray 101. Within that outer tray 101 there is a transparent cover of polycarbonate 102. Housing part 102 is partly covered at the top with aluminum tear plate 103. At the bottom three power and data cables 104 can be seen. Between the polycarbonate cover 102 and outer tray 101 there is a rubber sealing edge 105, which also makes it possible for the polycarbonate housing 102 to have some freedom of movement relative to aluminum outer tray 101. The polycarbonate cover 102 together with the electronic content is rubber feet with threaded ends 106 connected to the aluminum outer tray 101, with the aid of nuts 107. The interior of the tile is thermally conductively connected to the aluminum outer tray via the threaded ends 110 mounted on the printed circuit board holder 108. The threaded ends 110 are also connected with four nuts 107 against the aluminum outer tray 101. The power and data cables 104 are passed through the housing in a watertight manner with the aid of swivels 109.

FIG. 2 shows a section along line II-II of FIG. 1. The tile 200, the aluminum outer tray 201, the polycarbonate cover 202, polycarbonate insulation plate 209, aluminum light distributor 211 and polycarbonate insulation plate 212 are recesses. In the aluminum light distributor are recesses 213, for the purpose of transmitting light from high power light sources into the tile, preferably LEDs.

FIG. 3 shows a section along line III-III of FIG. 2. Tile 300, the aluminum outer tray 301, the polycarbonate cover 302, aluminum tear plate 303, power and data cables 304, rubber sealing edge 305, rubber feet with threaded ends 306, nuts are shown. 307, aluminum printed circuit board holder 308, cable glands 309, threaded ends of printed circuit board holder 310, aluminum light distributor 311, polycarbonate insulation plate 312, holes through printed circuit board holder 313, printed circuit board 314, LEDs 315, heat-conducting paste 316, printing surface 317, rubber plate 318, spring-loaded pressure edge 319 , spacer rings 320, limiters pressure edge 321 and pressure edge inside 322.

The tile 300 has a first chamber 323 and a second chamber 324, which chambers are separated from each other by an optically transparent insulating plate 312. This insulating plate 312 provides a thermal separation between the first chamber 323 and the second chamber 324. In the In the first chamber 323 there is a box-shaped aluminum light distributor 311. The bottom of the box is provided with a light-absorbing (black) coating at the top. The aluminum light distributor 311 is designed to reflect light and heat in all other respects.

Apertures 313 are provided in the aluminum light distributor 311 for transmitting light emitted by the LEDs 315 located in the second chamber 324. The light-absorbing side of light distributor 311 is intended to increase the contrast, i.e. to make the light emitted by the LEDs 315 come out better. The light-absorbing side of the light distributor 311 does, however, result in incoming sunlight also being absorbed via the transparent top side of cover 302, and the thermal load increasing. However, the invention provides the solution, by means of the first chamber 323 and second chamber 324, which are thermally separated from each other. Thus, the thermal load of the LEDs 315 and electronic circuits present in the second chamber 324 remains limited.

To further reduce the thermal load, heat-reflecting foil, such as aluminum foil, may be provided between the light-absorbing (black) side of the light distributor 311 and polycarbonate insulation plate 312. A layer of insulating material can also be provided between the heat-reflecting foil and polycarbonate insulating plate 312.

The LEDs 315 and the electronic circuits that control them generate heat during use. That heat is dissipated to the aluminum-25 µm circuit board holder 308. To this end, the LEDs 315 may be mounted on a printed circuit board 314, which printed circuit board 314 is in heat-conducting contact with aluminum printed circuit board holder 308 at various locations. The printed circuit board holder 308 is thermally connected to the metal housing 301. 308 with the printed circuit board 314 and / or the aluminum housing 301, use can be made of thermally conductive paste 316.

The polycarbonate housing 302 is glued on the underside with a pressure surface 317. On that surface, the polycarbonate housing 302 is sealed watertight with a rubber plate 318, which is tightened against the pressure surface 317 with a resilient pressure edge 318.

The rubber plate 318 has a hole in the middle through which the printed circuit board holder 308 can make thermal contact with the aluminum outer tray 302. The hole in the rubber plate 318 is sealed around with the help of inner edge 321 which is pressed against the aluminum printed circuit board holder 308. For the watertight connection, additional use can be made of a kit or a rubber string.

The underside of the printed circuit board holder is provided with cable feed-through openings, which are sealed watertight with swivels 309. With the aid of the power and data cables 304, the tiles can be supplied with power and data.

The invention is not limited to the embodiment described above. For example, the tile can also be a pressure-sensitive tile, in which case the tile will be equipped with one or more pressure sensors, as is known in the art.

1038139

Claims (11)

Tile (100) comprising a housing (101), a light-transmitting cover (102) and a plurality of light sources (315) arranged in the housing (101), characterized in that - the housing (101) comprises a thermally conductive wall, which housing (101) has a first chamber (323) on the side of the light-transmitting cover (102) and a second chamber (324) which is spaced from the light-transmitting cover (102), which second chamber (324) is separated from the first chamber (323) by an internal wall (312); - the light sources (315) are located in the second chamber (324) and are connected via a thermally conductive contact element (308) to the thermally conductive wall of the housing (101); and - the first chamber (323) is light-absorbing over part of it and the inner wall (312) is partially light-transmitting to allow light from the light sources (315) into the second chamber (324) to the light-transmitting cover (102). 20 The tile of claim 1, wherein the light-absorbing portion of the first chamber (323) absorbs at least 50% of the visible light falling on the light-absorbing portion, preferably at least 75%. 25 The tile of claim 1 or 2, wherein the light-absorbing portion of the first chamber (323) is spaced from the inner wall (312) for at least a portion thereof. A tile according to claim 3, wherein a heat radiation reflecting element is located between the light-absorbing part of the first chamber (323) spaced from the wall and the wall. A tile according to any one of the preceding claims, wherein the inner wall (312) is made from a thermally insulating material. 1038139 δ A tile according to any one of the preceding claims, wherein the inner wall (312) comprises a light-transmitting material selected from the group consisting of plastic and glass. A tile according to any one of the preceding claims, wherein the first chamber (323) is airtightly separated from the second chamber (324) by the inner wall (312). A tile according to any one of the preceding claims, wherein at least a portion of the light sources (315) are LEDs. Tile as claimed in any of the foregoing claims, wherein the thermally conductive wall is a metal wall. A tile according to any one of the preceding claims, wherein - the housing (101) is thermally insulating at the top; and - the housing (101) is thermally conductive at the bottom. 20 11. Tile as claimed in any of the foregoing claims, wherein the thermal conductive connection of the printed circuit board to the housing (101) is passed through a water-tight and flexible plate, whereby the housing (101) can move somewhat around the electronics, which makes pressure sensitivity possible . 1038139