Backlit Floor Construction

Abstract

An aspect of the invention relates to a floor construction, comprising: o plural layers, the plural layers comprising at least one top layer and at least one subjacent layer underneath the at least one top layer, o and light sources arranged in one or more patterns in the at least one subjacent layer; o wherein the at least one top layer is translucent so as to hide the light source as well as the patterns when the light sources are off and to reveal the one or more patterns when the light sources are on.

Claims

1. Floor construction, comprising: plural layers, the plural layers comprising at least one top layer and at least one subjacent layer underneath the at least one top layer, and light sources arranged in one or more patterns in the at least one subjacent layer; wherein the at least one top layer is translucent so as to hide the light source as well as the patterns when the light sources are off and to reveal the one or more patterns when the light sources are on.

2. Floor construction as claimed in claim 1, wherein the light sources are connected to a controller having a user interface allowing a user to switch one or more of the patterns on and off.

3. Floor construction as claimed claim 1, wherein the light sources are LEDs.

4. Floor construction as claimed in claim 3, wherein the light sources comprise red, green and blue LEDs, and/or white LEDs.

5. Floor construction as claimed in claim 4, wherein the LEDs are or comprise OLEDs.

6. Floor construction as claimed in claim 1, wherein the light source are protected from pressures exerted on the top layer.

7. Floor construction as claimed in claim 1, wherein the light sources are individually controllable.

8. Floor construction as claimed in claim 1, wherein the at least one subjacent layer comprises a concrete layer, the light sources being arranged in the concrete layer.

9. Floor construction as claimed in claim 1, wherein the one or more patterns include at least one of emergency path indications, game lines, orientation helps, a logo, a pictogram, a traffic sign, an icon.

10. Floor construction as claimed in claim 1, comprising a controller connected to the light sources for controlling the light sources and the revealing of the one or more patterns, and one or more pressure sensors connected to the controller, the pressure sensors being preferably arranged in or underneath the at least one top layer in the vicinity of and/or overlapping with the one or more patterns, the controller being configured to control the light sources and the revealing of the one or more patterns depending on signals received by the controller from the one or more pressure sensors.

11. Floor construction as claimed in claim 1, wherein the light sources are arranged in one or more two-dimensional arrays forming the one or more patterns, wherein the floor construction comprises a controller connected to the light sources the controller being configured to dynamically control the light sources in such a way as to reveal dynamical patterns as pixel images.

12. Floor construction as claimed in claim 1, wherein the at least one top layer is translucent but not transparent.

13. Floor construction as claimed in claim 1, wherein the at least one top layer comprises a resilient multilayer floor covering comprising a foam layer, a calendered polymer sheet, a printed layer and a wear layer.

14. Floor construction as claimed in claim 13, wherein the foam layer is PVC-based open-cell or closed-cell foam.

15. Floor construction as claimed in claim 13, wherein the printed layer comprises a pigmented plastisol-based printing substrate carrying one or more layers of ink.

16. Floor construction as claimed in claim 13, wherein the printed layer comprises a PVC-based printing substrate carrying one or more layers of ink.

17. Floor construction as claimed in any one of claim 14, wherein the calendered polymer sheet is PVC-based.

18. Floor construction as claimed in claim 14, wherein the calendered sheet comprises a fibre glass veil.

19. Floor construction as claimed in claim 1, wherein the at least one subjacent layer comprises one or more through-shaped channel profiles accommodating the light sources.

20. Floor construction as claimed in claim 19, wherein the through-shaped channel profiles are aluminium profiles.

21. Floor construction as claimed in claim 19, wherein the through-shaped channel profiles are glued or screwed to the underground.

22. Floor construction as claimed in claim 19, wherein a through-shaped channel profile comprises a base, a first side wall and a second side wall delimiting a channel, wherein said light sources are accommodated.

23. Floor construction as claimed in claim 22, wherein each of the first side wall and the second side wall comprises a ledge or protrusion supporting a translucent cover element covering the light sources, the top surface of the translucent cover element being flush with the top surface of the subjacent layer so as to form a substantially flat support surface for the at least one top layer.

24. Floor construction as claimed in claim 23, wherein the translucent cover element is a light diffuser, e.g. made of PMMA.

25. Floor construction as claimed in claim 19, wherein the through-shaped channel profile comprises anchoring elements for anchoring the through-shaped channel profile in the subjacent layer.

26. Floor construction as claimed in claim 19, wherein the anchoring elements comprise at least one protrusion or indentation for interlocking the through-shaped channel profile with the subjacent layer.

27. Floor construction as claimed in claim 19, wherein the subjacent layer comprises screed concrete, the top surface of the screed concrete being substantially flush with the upper edges of the one or more through-shaped channel profiles.

28. Floor construction as claimed in claim 19, wherein the light sources are encapsulated in one or more translucent polymer blocks arranged in the one or more through-shaped channel profiles, the top surface of the one or more translucent polymer blocks being substantially flush with the upper edges of the one or more through-shaped channel profiles.

29. Floor construction as claimed in claim 18, wherein the light sources are encapsulated in one or more translucent polymer blocks embedded in the subjacent layer, the subjacent layer comprising screed concrete, the top surface of the screed concrete being substantially flush with the top surface of the one or more translucent polymer blocks.

30. Floor construction as claimed in claim 29, wherein the one or more translucent polymer blocks are glued or screwed to the underground.

31. Floor construction as claimed in claim 29, wherein the subjacent layer comprises a layer of closed-cell foam, the top surface of the closed-cell foam being substantially flush with the top surface of the one or more translucent polymer blocks.

32. Floor construction as claimed in claim 31, wherein the shore hardness of the closed-cell foam is at least approximately equal to the shore hardness of the one or more translucent polymer blocks.

33. Floor construction as claimed in claim 32, wherein the shore A or shore D hardness of the closed-cell foam differs from the shore A or shore D hardness, respectively, of the one or more translucent polymer blocks by not more than 5 units.

34. Floor construction comprising: plural layers, the plural layers comprising at least one top layer and at least one subjacent layer underneath the at least one top layer, and light sources arranged in one or more patterns in the at least one subjacent layer; wherein the at least one top layer is translucent so as to hide the light source as well as the patterns when the light sources are off and to reveal the one or more patterns when the light sources are on; wherein the light sources are connected to a controller having a user interface allowing a user to switch one or more of the patterns on and off; wherein the light sources are LEDs; where the light sources comprise red, green, and blue LEDs, and/or white LEDs; wherein the LEDs are or comprise OLEDs; wherein the light source are protected from pressures exerted on the top layer; wherein the light sources are individually controllable; wherein the at least one subjacent layer comprises a concrete layer, the light sources being arranged in the concrete layer; wherein the one or more patterns include at least one of emergency path indications, game lines, orientation helps, a logo, a pictogram, a traffic sign, an icon; a controller connected to the light sources for controlling the light sources and the revealing of the one or more patterns, and one or more pressure sensors connected to the controller, the pressure sensors being preferably arranged in or underneath the at least one top layer in the vicinity of and/or overlapping with the one or more patterns; the controller being configured to control the light sources and the revealing of the one or more patterns depending on signals received by the controller from the one or more pressure sensors; wherein the light sources are arranged in one or more two-dimensional arrays forming the one or more patterns, wherein the floor construction comprises a controller connected to the light sources the controller being configured to dynamically control the light sources in such a way as to reveal dynamical patterns as pixel images; wherein the at least one top layer is translucent but not transparent; wherein the at least one top layer comprises a resilient multilayer floor covering comprising a foam layer, a calendered polymer sheet, a printed layer and a wear layer; wherein the foam layer is PVC-based open-cell or closed-cell foam; wherein the printed layer comprises a pigment plastisol-based printing substrate carrying one or more layers of ink; wherein the printed layer comprises a PVC-based printing substrate carrying one or more layers of ink; wherein the calendered polymer sheet is PVC-based; wherein the calendered sheet comprises a fibre glass veil; wherein the at least one subjacent layer comprises one or more through-shaped channel profiles accommodating the light sources; wherein the through-shaped channel profiles are aluminium profiles, wherein the through-shaped channel profiles are glued or screwed to the underground; wherein a through-shaped channel profile comprises a base, a first side wall and a second side wall delimiting a channel, wherein said light sources are accommodated; wherein each of the first side wall and the second side wall comprises a ledge or protrusion supporting a translucent cover element covering the light sources, the top surface of the translucent cover element being flush with the top surface of the subjacent layer so as to form a substantially flat support surface for the at least one top layer; wherein the translucent cover element is a light diffuser, e.g. made of PMMA; wherein the through-shaped channel profile comprises anchoring elements for anchoring the through-shaped channel profile in the subjacent layer; wherein the anchoring elements comprise at least one protrusion or indentation for interlocking the through-shaped channel profile with the subjacent layer; wherein the subjacent layer comprises screed concrete, the top surface of the screed concrete being substantially flush with the upper edges of the one or more through-shaped channel profiles; and wherein the light sources are encapsulated in one or more translucent polymer blocks arranged in the one or more through-shaped channel profiles, the top surface of the one or more translucent polymer blocks being substantially flush with the upper edges of the one or more through-shaped channel profiles.

35. Floor construction comprising: plural layers, the plural layers comprising at least one top layer and at least one subjacent layer underneath the at least one top layer, and light sources arranged in one or more patterns in the at least one subjacent layer; wherein the at least one top layer is translucent so as to hide the light source as well as the patterns when the light sources are off and to reveal the one or more patterns when the light sources are on; wherein the light sources are connected to a controller having a user interface allowing a user to switch one or more of the patterns on and off; wherein the light sources are LEDs; wherein the light sources comprise red, green and blue LEDs, and/or white LEDs; wherein the LEDs are or comprise OLEDs; wherein the light source are protected from pressures exerted on the top layer; wherein the light sources are individually controllable; wherein the at least one subjacent layer comprises a concrete layer, the light sources being arranged in the concrete layer; wherein the one or more patterns include at least one of emergency path indications, game lines, orientation helps, a logo, a pictogram, a traffic sign, an icon; a controller connected to the light sources for controlling the light sources and the revealing of the one or more patterns, and one or more pressure sensors connected to the controller, the pressure sensors being preferably arranged in or underneath the at least one top layer in the vicinity of and/or overlapping with the one or more patterns; the controller being configured to control the light sources and the revealing of the one or more patterns depending on signals received by the controller from the one or more pressure sensors; wherein the light sources are arranged in one or more two-dimensional arrays forming the one or more patterns, wherein the floor construction comprises a controller connected to the light sources the controller being configured to dynamically control the light sources in such a way as to reveal dynamical patterns as pixel images; wherein the at least one top layer is translucent but not transparent; wherein the at least one top layer comprises a resilient multilayer floor covering comprising a foal layer, a calendered polymer sheet, a printed layer and a wear layer; wherein the foam layer is PVC-based open-cell or closed-cell foam; wherein the printed layer comprises a pigmented plastisol-based printing substrate carrying one or more layers of ink; wherein the printed layer comprises a PVX-based printing substrate carrying one or more layers of ink; wherein the calendered polymer sheet is PVC-based; wherein the calendered sheet comprises a fibre glass veil; wherein the light sources are encapsulated in one or more translucent polymer blocks embedded in the subjacent layer, the subjacent layer comprising screed concrete, the top surface of the screed concrete being substantially flush with the top surface of the one or more translucent polymer blocks; wherein the one or more translucent polymer blocks are glued or screwed to the underground; wherein the subjacent layer comprises a layer of closed-cell foam, the top surface of the closed-cell foam being substantially flush with the top surface of the one or more translucent polymer blocks; wherein the shore hardness of the closed-cell foam is at least approximately equal to the shore hardness of the one or more translucent polymer blocks; and wherein the shore A or shore D hardness of the closed-cell foam differs from the shore A or shore D hardness, respectively, of the one or more translucent polymer blocks by not more than 5 units.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0028] By way of example, preferred, non-limiting embodiments of the invention will now be described in detail with reference to the accompanying drawings, in which:

[0029] FIG. 1: is a partially cut-away cross-sectional view of a floor construction according to a first preferred embodiment of the invention;

[0030] FIG. 2: shows the channel profile as used in the embodiment of FIG. 1 and the LEDs arranged therein;

[0031] FIG. 3: schematically shows variant of the floor construction according to the first preferred embodiment of the invention;

[0032] FIG. 4: is a perspective view of a polymer block with embedded LEDs as used in a second preferred embodiment of the invention;

[0033] FIG. 5: is a perspective view of a channel profile having arranged therein a polymer block with embedded LEDs;

[0034] FIG. 6: is a perspective view of a floor construction according to a further preferred embodiment of the invention;

[0035] FIG. 7: is a perspective view of the crossing of channel profiles as used in the embodiment of FIG. 1;

[0036] FIG. 8: is a perspective view of the crossing of channel profiles as used in the embodiment of FIG. 1, wherein it is illustrated how the LEDs in the zone of the intersection cooperate with the LEDs of the interrupted profile series in order to display an apparently continuous or nearly continuous line;

[0037] FIG. 9: is an illustration of a first application (indoor navigation) of a floor construction according to the invention;

[0038] FIG. 10: is an illustration of a second application (pedestrian traffic management in private or public transportation facilities) of a floor construction according to the invention;

[0039] FIG. 11: is an illustration of a third application (interactive sports ground) of a floor construction according to the invention;

[0040] FIG. 12: is an illustration of an application (player tracking motion) that may be made available as an option in the third application;

[0041] FIG. 13: is a schematic cross-section of a translucent resilient multilayer floor covering usable on top of the subjacent layer comprising the light sources.

DETAILED DESCRIPTION OF PREFERRED EXEMPLARY EMBODIMENTS

[0042] FIG. 1 shows a floor construction 100 according to a preferred embodiment of the invention. The floor construction 100 comprises a subfloor 102 and a decorative synthetic (polymer-based) floor covering 104 arranged on top of the subfloor 102. The subfloor 102 comprises a screed concrete layer 106 and a having trough-shaped channel profiles 108 arranged therein. The trough-shaped channel profiles 108 are preferably made of aluminium and are glued or screwed to the underground. The channel profiles serve to accommodate LED bands 110 with individually addressable and controllable LEDs 112. A light diffuser 114 protects the LED bands 110 against impacts and supports the decorative floor covering 104 where the decorative floor covering 104 extends over the channel profiles 108.

[0043] The channel profile 108 comprises a base 116, a first side wall 118 and a second side wall 120 delimiting the channel, wherein the LED bands are arranged. Each of the first side wall 118 and the second side wall 120 comprises a ledge 122 supporting the light diffuser 114. FIG. 2 is a perspective view of only the channel profile and the light diffuser 114.

[0044] The light diffuser 114 is dimensioned so that its top surface is flush with the top surface of the upper edges of the side walls 118, 120 and with the top surface of the screed concrete.

[0045] The channel profile 108 further comprises anchoring elements for anchoring the through-shaped channel profile in the concrete 106. In the illustrated embodiment, the anchoring elements are indentations 124 in the first and second side walls, into which the concrete 106 may penetrate while fluid.

[0046] The channel profiles and thus the LEDs are arranged in so as to form line patterns in the subfloor. The decorative synthetic floor covering 104 is translucent so as to hide these patterns when the LEDs are off and to reveal them when LEDs are on.

[0047] The LEDs are connected to a controller (not illustrated in FIGS. 1 and 2) having a user interface allowing a user to switch one or more of the patterns on and off. As the LEDs are individually addressable, not only the overall pattern of the entirety of the LED can be illuminated, any sub-pattern consisting of any sub-set of the LEDs may be illuminated. The user interface preferably comprises several predefined patterns among which the user may select. According to a preferred embodiment, the user interface may be configured to allow the user to define and to save illumination patterns himself and to add these custom patterns to those that are selectable. The user interface may also be configured to give the user the possibility to define dynamic illumination patterns, i.e. illumination patterns that evolve in time.

[0048] FIG. 3 shows a variant of the floor construction of FIG. 1. For the sake of brevity, elements already discussed with regard to FIGS. 1 and 2 are not discussed again. Reference number 126 designates a controller connected to the LED bands 110. The controller 126 comprises a communications interface (preferably a WLAN or Ethernet module, not shown in FIG. 3) and is configured to make its user interface available over a network, e.g. a local area network, a wireless local area network or the Internet. The floor construction of FIG. 3 comprises sheet-type pressure sensors 128 arranged in or underneath the floor covering 104 and extending alongside the channel profile 108. Each pressure sensor 128 is configured to detect pressure exerted on the floor covering. Optionally, the pressure sensors 128 are configured to detect pressure as a function one or more position coordinates (i.e. in a one- or two-dimensional coordinate system). In this case, several parameters may be detected, such as, e.g., a one- or two-dimensional pressure profile (or pressure distribution), the centroid of a pressure profile, the force associated with a pressure profile (i.e. the integral over the area of the pressure profile), etc. The pressure sensors may be arranged in a two-dimensional (array or matrix) pattern so that a large-scale touch-sensitive surface is formed. In combination with a similarly dimensioned array or matrix pattern of LEDs, a large-scale “touchscreen” may be formed.

[0049] The controller 126 may be configured to control the LEDs depending on the signals received from the pressure sensors 128 and on the selection (user preference) entered by a user via the user interface. The user interface is preferably configured to allow the user to switch between different modes, which determine how the LEDs are controlled when certain pressure events are detected by the pressure sensors. For instance, the user interface may offer the user the option to make the LEDs highlight areas in which a pressure was sensed. The intensity of the highlighting could be depending on the amount of pressure detected. The interface could also offer the user the possibility to make the highlighting fade out less rapidly than the pressure decreases. If the illuminated pattern is a sports line marking, the user interface could propose the option of changing a part of the line pattern (e.g. in colour or by varying the intensity of the illumination) when an impact (pressure), e.g. exerted by a ball 130, is detected on a particular side of the line pattern. That functionality could e.g. help to detect an out-of-bounds situation during a sports game.

[0050] The installation of the floor constructions of FIGS. 1 and 3 is preferably carried out by first gluing, screwing or otherwise fixing the channel profiles to the underground. When the profiles are in place, the leveling concrete is installed (by casting or posing prefabricated slabs) and the LED bands are arranged in the channel profiles. The wiring necessary for the LEDs is also put in place. Preferably, the LEDs are also tested at this stage of the installation. When the LEDs are in place, the diffuser is arranged in the channel profiles. Finally, the decorative floor covering is installed on top of the subfloor formed by the concrete and the channel profiles.

[0051] FIG. 4 relates to an embodiment of the invention, wherein the LEDs 212 are embedded (cast) in a translucent polymer block 232. Such a polymer block 232 could be directly embedded in the subfloor (i.e. without an intermediate channel profile as in the embodiment of FIGS. 1-3). Compared with the embodiment of FIG. 1, the embodiment of FIG. 4 presents the advantage that less height is required for the installation of the LEDs under the decorative floor covering. The translucent polymer block may be directly embedded in leveling concrete, the top surface of the concrete being substantially flush with the top surface of the polymer block.

[0052] Installing a floor construction using polymer blocks as illustrated in FIG. 4 preferably comprises, in a first step, gluing, screwing or otherwise fixing the blocks to the underground and connecting the LEDs. Preferably, the LEDs are tested at this stage. Once the polymer blocks are in place, the leveling concrete is installed. Finally, the decorative floor covering is installed on top of the subfloor formed by the concrete and the polymer blocks. Instead of using concrete to fill the areas between the polymer blocks, other materials could be used. As one possibility, it may be worthwhile mentioning calendered PVC sheets or tiles having the same height as the polymer blocks.

[0053] FIG. 5 illustrates an alternative use of the polymer blocks of FIG. 4: instead of directly placing the polymer blocks 232 on the underground, channel profiles 208 are first glued, screwed or otherwise fixed on the underground. Then the polymer blocks with the LEDs are put in place and the LEDs are connected. The areas between the profiles are filled with subfloor material 206 (e.g. concrete or calendered PVC sheets or tiles, etc.) and, finally, the decorative floor covering is installed on top of the subfloor.

[0054] FIG. 6 relates to a floor construction 300 according to yet another preferred embodiment of the invention. The floor construction 300 comprises a multilayer decorative floor covering 304 comprising a closed-cell foam backing 334 supporting an assembly of transparent layers 336. The LEDs 312 are encapsulated in a translucent polymer block 332, which is arranged in a space (e.g. recess, clearance, slot, etc.) provided in the closed-cell foam backing 334. The floor construction 300 may be provided as a set of prefabricated sheets or tiles, which are disposed on the underground 338. The closed-cell foam backing 334 and the polymer block 332 are configured so as to have the same or at least similar mechanical features, especially in terms of hardness or resiliency.

[0055] FIGS. 7 and 8 illustrate the crossing of two lines defined by LEDs arranged in channel profiles as shown in FIGS. 1 to 3. At the location of the crossing, the channel profiles belonging to a first line 140 are arranged directly adjacent each other such that a continuous channel is formed. The channel profiles belonging to the second line 142 abut against the side walls of the channel profiles belonging to the first line. In order to avoid that the second line appears interrupted at the crossing (when the first line is switched off), the LEDs 144 lying in the intersection of the lines are allocated to both the LED pattern corresponding to the first line and the LED pattern corresponding to the second line. That is possible due to the fact that each LED is individually digitally addressable (e.g. by means of a unique identifier) and therefore individually controllable. When the light patterns are programmed, the LEDs in the intersection of two or more patterns are assigned to each of the patterns. In FIGS. 7 and 8, the patterns corresponding to the first line 140 and the second line 142, respectively, are shaded grey. The LEDs may be controllable as regards colour, brightness, duration of activation, etc.

[0056] FIGS. 9 to 12 illustrate different applications (among others) of floor constructions as presented herein, in combination with a mobile device application.

[0057] FIG. 9 shows a building interior equipped with a floor construction configured for displaying guiding markers on the floor. The controller of the LEDs is coupled with a mobile device application (“app”) allowing the user to enter a destination. Based upon the user's position and the destination, a path from the current position is calculated and displayed on the floor. The guiding marker could have the form of a line from the starting point to the end point. Alternatively, if the user's position is available in real time from an indoor positioning system, the guiding marker could be a “follow me” sign that moves with the user one or a few meters ahead of him on the computed path. The system could also be used for guiding people to the emergency exits in the event of an evacuation of a building due to an emergency (e.g. fire, earthquake, danger of explosion, etc.) Preferably, the controller is connected to an alarm system and is configured to display the pathways to the emergency exits when the alarm system is triggered.

[0058] FIG. 10 shows a public transportation area equipped with a floor construction according to the invention. The floor construction could be used for different functions, such as, e.g., wayfinding, passenger flow regulation, advertising, passenger information, etc.

[0059] FIGS. 11 and 12 show a sports ground equipped with a floor construction as presented herein. The floor construction comprises a two-dimensional array of LEDs arranged underneath the decorative floor covering and stretching out over the whole area of the sports ground, thereby forming a large-scale interactive display. The controller of the LEDs is coupled with an app that allows the user to choose among different line court markings (e.g. of a basketball court, a handball court, a tennis court, a volleyball court, a badminton court, etc., see FIG. 11) and, preferably, also among optional functionalities (e.g. out-of-bounds highlighting, player position highlighting, player motion tracking, etc., see FIG. 12). As an optional feature, the controller may comprise an interface for coupling with an indoor positioning system, capable of tracking the position of the players and the ball. The controller may be interfaced with the sports facility's agenda software (scheduling tool) in order to automatically change the displayed patterns depending on the data (scheduled events) registered in the agenda software. With such implementation, patterns could be automatically switched e.g. from basketball court to tennis court, etc. The application could also display statistical information about the facility's usage, like the number of players, number of hours of game per sport, and then optimize the facility's usage. As an option, the application could also be configured to as to allow the users to book the sports facility online for a certain time interval and, optionally, for a certain sport, and allow him to pay for the booking of the sport facility with credit card or another online payment means (e.g. via PayPal™, near field communication (NFC), etc . . . )

[0060] FIG. 13 schematically shows a resilient multilayer floor covering 404 as it may be used in the context of the present invention, in particular but not exclusively, in the illustrated embodiments. The resilient multilayer floor covering 404 comprises a foam backing layer 444, a calendered polymer sheet 446, a printed layer 448 and a wear layer 450. The foam layer 444 is preferably PVC-based open-cell or closed-cell foam. The printed layer 448 is preferably a pigmented plastisol-based printing substrate or a PVC-based printing substrate carrying one or more layers of ink. The calendered polymer sheet 446 is preferably PVC-based and preferably comprises a fibre glass veil 452.

[0061] While specific embodiments have been described herein in detail, those skilled in the art will appreciate that various modifications and alternatives to those details could be developed in light of the overall teachings of the disclosure. Accordingly, the particular arrangements disclosed are meant to be illustrative only and not limiting as to the scope of the invention, which is to be given the full breadth of the appended claims and any and all equivalents thereof.