This invention relates to lighting products that can be attached in a modular fashion to create a variety of lighting effects.
Lighting products, such as lamps or lights, for residential or commercial environments, are commonplace. Generally, lighting products are designed for use in either the residential or commercial environment, it is uncommon for lighting products to be designed for both environments.
Typically, there are different lighting products for particular purposes (e.g. ambient lighting versus accent lighting) or tasks within a given environment. For example, in the residential environment there are stand-up lamps (i.e. a lamp at the top of a pole), smaller lamps such as would be placed on a side table, desk lamps, fixtures, pendants, etc. While these can be purchased from the same source and thus look like an assorted set, these are often purchased at different times from different manufacturers and resulting in a collection of varied lighting styles.
Each piece of lighting is usually fixed in its physical and luminary properties—i.e. in its physical design and the character of the emitted light. Where there is variation, it tends to be limited to directing the light, or varying the intensity of the light (i.e. a lamp and bulb that can switch between low medium and high settings).
Often, the character of the emitted light is controlled through the use of a shade, which can soften or diffuse light, direct light, or even block the light in particular directions.
The system and devices presented here are a variable modular lighting system that contains shade elements, light emitting devices and structural components. The shade elements are designed with specific intrinsic geometric relations such that they can interlink in various formations—i.e. the shade elements can be nested to one another so that one or more surfaces or adjacent shapes are flush with no gap in between. As long as the geometric relations are maintained the shade elements can be scaled to any size without losing their ability to interlink.
This results in a flexible lighting system, where the user can more easily adjust the system for various purposes than traditional lighting systems, whether making changes on a short term (i.e. changes throughout the day) or on a more long-term basis.
The shade elements may be constructed from non-rigid materials, such as paper, thin cardboard, plastic film, and similar materials of varying translucency. The light emitting devices discussed in this application are LEDs or light emitting diodes, although other light emitting devices can be used as long as they are compatible with the material of the shade elements. The light emitting devices can be configured to illuminate individual or multiple shades from within.
The structural components are designed to support individual or multiple shades in a variety of configurations. Some designs integrate the structural and lighting components into a single unit, resulting in fewer components (for ease of use) and less use of material.
In accordance with the present invention, there is provided a device comprising: a hollow box, wherein the box comprises: a central rectangular cuboid comprising a first edge, second edge and a third edge, where the first, second and third edges are perpendicular and meet at a first vertex and so define the cuboid in three dimensions, the central rectangular cuboid further comprising a fourth edge and a fifth edge, where the second edge and the fourth edge and the fifth edge are perpendicular and meet at a second vertex and the first edge and the fourth edge are parallel and approximately equal in length and the third edge and fifth edge are parallel and approximately equal in length, and the central rectangular cuboid further comprising four faces, where the first, second and fourth edge define the first face and the second, third and fifth edges define the second face; and the first and third edges do not define a face and the fourth and fifth edges do not define a face; and two opposed irregular triangular prism-shaped wings with the first irregular triangular prism-shaped wing attached to the first edge and the third edge of the central rectangular cuboid and having a sixth edge not attached to the central rectangular cuboid and defining the peak of the irregular triangle; and the second irregular triangular prism-shaped wing attached to the fourth edge and fifth edge of the central rectangular cuboid, and having a seventh edge not attached to the central rectangular cuboid and defining the peak of the irregular triangle.
In another aspect of the invention, the first, second and third edges are approximately equal in length, and the sixth edge and seventh edges are each approximately twice the length of the first edge. In another aspect, the first, second and third edges are equal in length, and the sixth edge and seventh edges are each twice the length of the first edge, within a manufacturing tolerance. In one embodiment, the manufacturing tolerance is +/−2 mm. In one embodiment, the manufacturing tolerance is +/−1 percent of the length of the third edge. In yet another aspect, the first, second and third edges are equal in length, and the sixth edge and seventh edges are each twice the length of the first edge.
In still another aspect of the invention, there is provided a plurality of devices, where each irregular triangular prism has a third face and a fourth face, and the devices are arranged so the faces of the wings of at least two of the devices abut. In another aspect, the central rectangular cuboid has a first hole on a face of the cuboid and a second hole the opposed face of the cuboid.
In another aspect of the invention, there is provided a device comprising a plurality of devices as described above, where the plurality of devices are arranged so that the plurality of holes form a tunnel.
In another aspect of the invention, there is provided a kit further comprising a structural element to support at least one device. In another aspect of the invention, the kit has a structural element comprising a base and a column extending therefrom.
In another aspect of the invention, the structural element incorporates at least one light emitting device. In another aspect of the invention, the device further comprises at least one light emitting device.
In a further aspect of the invention, the device can be collapsed and re-assembled.
In another aspect of the invention, the first hole contains a male electrical connection element and the second hole contains a female electrical connection element and when powered the female connection element powers at least one light emitting device and the male electrical connection element.
In another aspect of the invention, a plurality of devices are arranged so that the fourth edges of the plurality of devices form a continuous edge.
In order to better understand various exemplary embodiments, reference is made to the accompanying drawings, wherein:
The system and devices presented here are a variable modular lighting system that contains shade elements, light emitting devices and structural components.
A side view of this shade element is shown in
The wings 6 and 8 are irregular triangular prisms, which means that the wings are triangular prisms (i.e. when seen from the side as in
To allow the interlinking of the shade elements (as discussed below), length A=length B=length C=(length D divided by 2), which is the “geometric relation”. In a practical embodiment, this relationship is approximate. At a minimum, this geometric relation is only maintained within the manufacturing error or margin of the method of manufacture. In one embodiment, the manufacturing tolerance is +/−2 mm. In another embodiment, the manufacturing tolerance is +/−1 percent of the length A. Also, in a physical embodiment the interlinking nature of the shade elements is maintained even if the geometric relation is only roughly maintained, so in alternative embodiments the geometric relation is length A being approximately equal to length B which is approximately equal to length C which is approximately equal to (length D divided by 2).
The shade elements are designed with this specific intrinsic geometric relation so that they can interlink in various formations. By interlink, it is meant that the shapes can be nested to each other in different orientations in a form-locking way, by making one or more surfaces of adjacent shapes flush. As long as the geometric relations are (approximately) maintained the shade elements can be scaled to any size without losing their ability to interlink.
Turning to the side view shown in
In an alternative embodiment, wings 6 and 8 can be stretched by moving edges 14 and 16 of wings 6 and 8 perpendicularly away from central rectangular cuboid 4 to form isosceles triangles, so that the lengths of sides 18 and 20 are equal, and the lengths of sides 22 and 24 are equal. This alternative maintains a line of symmetry (through edges 14 and 16), but also changes the properties of the interlinking, so that while the specific example in
The connection strips 10 and 12 are optional, but may be included to allow the easier creation of permanent or detachable connections of the shade elements when interlinked, or if the shade elements are shipped flat the connection strips 10 and 12 may aid (as discussed below) in holding the shape of the shade elements in use. Connection strips 10 or 12 can be used to make connections using glue, two-sided tape, a hook and loop (Velcro™) system, or any other system for permanent or detachable attachment.
As illustrated in
As may be seen in
As illustrated in
As shown in
Shade elements 2 and 28 may be interlinked in a stack while maintaining a continuous tunnel in numerous patterns, creating a variety of different lights as illustrated in
In an exemplary embodiment, due to the geometric relation, edges 14 and 16 of the shade elements 2 and 28 form a continuous edge in the specific interlinks illustrated in
Through use of the interlinks available through use of the geometric relation, formations can also be achieved that undulate into three dimensions. Furthermore, in
For example, the triangular modules 29 depicted in
As may be seen in the Figures as discussed above, the use of the geometric relation for the shade element allows for interlinking to create many different forms of lighting shapes.
The interlinked shade elements illustrated in the Figures discussed above are complemented by a variety of structural components and/or light emitting devices. For example, the interlinked configurations illustrated in
A different structural element is illustrated in
A wide variety of lighting effects can be achieved by varying the configuration of the interlink between shade elements.
A wide variety of lighting effects can also be achieved by varying the materials from which the shade elements are constructed. By varying the translucency and/or colour of the materials of different parts of a shade element, light may be directed (in some cases, a mirror in the interior of the shade element may be used), softened, diffused, or coloured.
In cases where the shade elements are not permanently attached (i.e. are detachably attached or simply resting on a central column), shade elements may be swapped out by the user to achieve different lighting effects. For example, when working at a desk, a columnar structural element as seen in
The shade elements are constructed from nonrigid materials such as paper, thin cardboard, plastic film and similar materials of varying translucency. The materials do require a certain stiffness to weight ratio and weight-wise can go up to the equivalent of a light cardboard. A slight cotton content is possible. HDPE and PVC are potential material options. PVC, however, is environmentally less preferable. Other possibilities are a polyester film such as Mylar™ or polyethylene film such as Tyvek™.
The shade elements may be designed to be shipped flat and folded into shape before use. Turning to
Connection strips 86 are optional, but preferred, when used to ensure that the shade element retains its shape once folded into shape. Connection strips 86 may create permanent or detachable connections, and may make connections using glue, two-sided tape, a hook and loop (Velcro™) system, or any other system for permanent or detachable attachment.
Connection strips 88 are also optional but preferred, and may also be used to ensure that the shade element retains its shape once folded into shape. In an exemplary embodiment, connection strips 88 may also be used to connect interlinked shade elements. Connection strips 88 may create permanent or detachable connections, and may make connections using glue, two-sided tape, a hook and loop (Velcro™) system, or any other system for permanent or detachable attachment.
Optionally, a mirror may be placed on one of the inside surfaces of the shade element to direct light.
The light emitting devices discussed in this application are LEDs or light emitting diodes, although other light emitting devices can be used as long as they are compatible with the material of the shade elements. The light emitting devices can be configured to illuminate individual or multiple shades from within.
The structural components are designed to support individual or multiple shades in a variety of configurations. In an alternative set of embodiments, the structural and lighting components may be integrated into a single unit, resulting in fewer components (for ease of use) and less use of material.
In an alternative set of embodiments, lighting components (and associated electronics) are integrated into a shade element. This would work best with a rigid shade element, such as a shade element made of blow-molded plastic. Each shade element may have an independent source of power (whether batteries or a cord and plug), or in another embodiment a structural element may be used to deliver power to the shade elements.
As a result, multiple shade elements 90 can be connected or stacked to transmit power through the stack, and power any light elements connected to the stack. Turning to
In a further embodiment, the male and female elements are pivotable, so that the shade elements can be rotated. Turning to
The invention is not intended to be limited to the embodiments described herein, but rather the invention is intended to be applied widely within the scope of the inventive concept as defined in the specification as a whole including the appended claims.