The present invention relates to light fixtures. Particular embodiments relate to a light fixture for mounting light modules in a tool-less manner.
Typically, lighting equipment in public places uses lighting fixture such as screws or any other components requiring a tool for the installation of a light module. The need of a tool reduces the practicality of the light fixture and can be time-consuming. This becomes especially relevant as a large number of light modules needs to be installed and/or removed, which is often the case in public places. One needs a less costly lighting fixture in terms of installation time that also maintains the safety required for a use in a public environment.
Many solutions exist for indoor lighting equipment presenting a lighting fixture comprising holding hooks for example provided in the lighting housing for a tool-less installation. However tool-less lighting fixture mounted on the light module are not known at the time of the present invention, even though it would quicken the installation manipulation. At the same time it would lessen the number of parts in the lighting housing since most parts would be directly mounted on the light module. One can also take advantage of the supplementary retaining surfaces it requires in the lighting housing to design additional functionalities within the lighting housing. Hence there is a need for a tool-less lighting fixture presenting these characteristics.
The object of embodiments of the invention is to provide a lighting fixture easier to use and allowing faster installation and replacement of a light module. More in particular, embodiments of the invention aim to provide a lighting fixture which allow for a tool-less installation of a light module.
According to a first aspect of the invention there is provided a lighting fixture. The lighting fixture comprises:
Embodiments of the invention are based inter alia on the insight that a common solution to fix lighting equipment to a ceiling or any other surface is done with screws or any other components for which there is a need to use tools. In the case that there is a housing to house a light module, one has to fix the light module within the housing. An elongate housing is the preferred solution to be able to house several light modules for instance. To overcome the problem of having to use tools to fix the light module, a modification has first to be done to the elongate housing. A first wall and a second wall will be added to the elongate housing, extending towards the elongate opening through which the light module will be mounted. The first and second walls will serve several purposes, the main one being a support for the mounting of the light module. A plurality of retainer means is provided on the face of the light module opposite to the one transmitting light. The plurality of retainer means engages with the first and second wall in a way allowing easy installation of the light module by a “plugging and pushing” assembly. A stopper means is implemented to stop inward displacements of the light module past a predetermined boundary. This stopper means stops displacements to prevent “over-pushing” the light module in the housing during its installation and to keep the plurality of retainer means in their optimal positioning. It may also prevent inward displacements in the event of an accidental external impact happening, e.g. a person or object hitting the light module. In practice the stopper means can be implemented in various ways.
According to a preferred embodiment, the plurality of retainer means comprises at least a first spring element and a second spring element having a protruding portion snap-fitted behind a first ridge and a second ridge at the first wall and the second wall, respectively, when looking from the elongate opening in the direction of the inner surface.
In this manner, a reliable means of retaining the light module is achieved. Indeed snap-fitting, by its mechanical simplicity, ensures that there is a lower probability of unforeseen problems arising.
Additionally the spring element dimensions and protruding portion can be easily modified and manufactured to adapt to various needs regarding a certain force required for the mounting or removal of the light module for instance. A first and a second spring element are provided on both longitudinal sides of the light module to retain it in a balanced way such that the retaining forces are spread equally among the plurality of retainer means. The first and second spring element may be provided symmetrically and their positioning may be further optimized to improve the mounting balance of the light module. These two spring elements can be independent from each other or be two portions of a common element for ease of fabrication. The protrusion of the curved portion is designed depending on the weight of the light module, the number of retainer means used, the dimensions of the first and the second ridge, the fabrication method of the retainer means, and the material of the retainer means.
According to an exemplary embodiment, the spring element comprises a first portion extending upwardly from the second face of the light module. The protruding portion is a curved portion formed at an upper edge of the first portion.
In this way, the first portion of the spring element is better designed for an installation of the light module at the ceiling, the light module being suspended from the curved portion of each spring element engaged against the first and the second wall behind the first and the second ridge, respectively. A curved-shaped spring element is preferred with respect to a more acute shape because of simpler manufacturing.
According to a preferred embodiment, the stopper means comprises at least one element configured for engaging an edge of the first and the second wall.
In this manner, the first and second wall will also serve a second purpose. Their respective edge will be a limiting surface onto which the stopper means will engage.
According to an exemplary embodiment, the stopper means is configured to prevent further inward displacements of the light module when the protruding curved portion of each of the plurality of retainer means is behind the first and second ridge.
In this way, only minimal displacements of the light module within the housing are possible. Inward displacements are limited by the stopper means, and outward displacements are limited by the position of the protruding curved portion of each of the plurality of retainer means with respect to the first and second ridge.
According to a preferred embodiment, the light module has a first and a second longitudinal side extending in the longitudinal direction, and a first and a second lateral side extending between the first longitudinal side and the second longitudinal side. The at least one element of the stopper means comprises a first lateral edge at the first lateral side of the light module extending from the second surface of the light module in direction of the first and second wall, and a second lateral edge at the second lateral side of the light module extending from the second surface of the light module in direction of the first and second wall.
In this manner, the light module has a similar shape as the elongate opening to fit in the elongate housing. The first and second lateral edge comprised in the stopper means permit a more secure protection against external impact since it provides additional stopping contacts in a balanced way against the first and second wall. Additionally it prevents direct contact of the second face of the light module against the first and second wall, adding supplementary protection to the contents of the light module.
According to an exemplary embodiment, the light module comprises:
Optionally the light module further comprises:
In this way, a light source in the way of a printed circuit board with at least one LED is contained by a lighting housing. The printed circuit board may be mounted on a lighting plate to diffuse any excessive heat produced by the light source. The light source could also be a source other that a LED, e.g. halogen, incandescent, or fluorescent lamp. The surface onto which the printed circuit board is mounted can be made reflective to improve the light emission. To enclose and protect the light source, a cover is positioned over the at least one LED by, for instance, snap-fitting it to the base portion of the lighting housing. This cover may be in a transparent or translucent material depending on the use of the light module and the quality of lighting required. The base portion is designed to contain the lighting plate and the printed circuit board with at least one LED. The light module comprises a first face through which light is emitted and an opposite second face. The light module may also be designed in such a way that the second face of the light module can serve as a mounting surface for different elements, e.g. retainer means, stopper means, electronic components, etc.
According to a preferred embodiment, at least one electric component is mounted on the second face of the light module such that the at least one electric component is located in a space within the bounds of the inner surface of the elongate housing, the first and second walls, and the second face of the light module.
In this manner, the first and the second wall will serve one more purpose. They will become part of an enclosed space protecting the at least one electric component. The space within the bounds of the inner surface of the elongate housing, the first and second walls, and the second face of the light module thus effectively define a protected channel against unwanted external intrusions. One could modify the first and second lateral edge of the stopper means to a peripheral edge extending from the perimeter of the second surface of the light module in direction of the first and second wall. This peripheral edge would be more effective at preventing water intrusion for example.
According to an exemplary embodiment, a second light module is retained longitudinally adjacent to a first light module by another plurality of retainer means within the elongate housing.
In this way, a same elongate housing can be used to house several light modules thus being a more economical solution and allowing a less time-consuming installation of the light modules. For safety reasons, in the case where several light modules are adjacently mounted, removal of the first light module may require the use of a tool, preferably a suction tool. Subsequent light modules may be removed by a simple application of force. A gap may be provided on a light module side to allow an operator to remove the first light module by hand only.
According to a preferred embodiment, a lighting driver is mounted on the second face of the first light module, wherein the lighting driver is configured to control the provision of power to the at least one LED of the first light module and the second light module.
In this manner, less electronic components are necessary for longitudinally adjacent light modules. Only additional connections between the first and second light modules are needed without having to install more electronic components on the second surface of the second light module. Having only one driver driving the first and second light modules may be more economical and less time-consuming. One could also use the lighting driver mounted on the first light module to drive more than two light modules.
According to an exemplary embodiment, at least the first or second wall is composed of a first portion of the elongate housing extending towards the elongate opening and joining to another second portion of the elongate housing extending at an angle of the first portion.
In this way, the first and second wall used to support the plurality of retainer means can be integrated in the outer profile of the elongate housing to save material. By adding housing portions to the elongate housing and integrating the first and second wall in the outer profile, one can multiply the uses of the first and second wall and create an external compartment to hide power cables and other wires. This would improve the aesthetics of the light equipment.
According to a preferred embodiment, the first face of the light module is designed to align with the outer edges of the elongate opening when mounted within the elongate housing.
In this manner, the light equipment is both more aesthetically pleasing and offers less salient external aspects for an improved safety.
According to an exemplary embodiment, the elongate housing is an extruded profile, preferably in metal.
According to an exemplary embodiment, the elongate housing has a length of more than 1 meter, preferably more than 2 meters, even more preferably more than 3 meters.
In this way, the manufacturing of the elongate housing is simplified and its length can be adjusted easily. Moreover, being in metal, the elongate housing will have a higher durability and an easier maintenance.
According to a preferred embodiment, the cover extends between outer edges of the elongate opening. According to an exemplary embodiment, the cover is located at least partially within the elongate housing. According to a preferred embodiment, the base portion is located entirely within the elongate housing. According to an exemplary embodiment, the cover is located at least partially out of the elongate housing. According to a preferred embodiment, the support substrate is located entirely within the elongate housing.
Embodiments of the invention aim at providing a lighting fixture with a reliable and secure installation of the light module within the elongate housing. To achieve that, the skilled person will understand that careful positioning of the different elements of the light module relative to the elongate housing is needed. The cover being generally the most vulnerable external element of the light module, placing it between outer edges of the elongate opening and/or such that part of the cover is located within the elongate housing allows to take advantage of the lateral protection offered by the elongate housing as well as reducing its exposure to external damaging elements. Placing it at least partially out of the elongate housing allows to increase the possibilities of diffusing light from the light module. Moreover, attention to the base portion may also be needed since it may hold and/or carry critical electronic elements of the light module as well as the support substrate. As such, placing them both entirely within the elongate housing permits to limit unwanted access to these critical electronic elements.
The skilled person will understand that the hereinabove described technical considerations and advantages for fixture embodiments also apply to the below described corresponding module embodiments, mutatis mutandis.
According to an exemplary embodiment, there is provided a light module for use in a lighting fixture. The light module comprises:
This and other aspects of the present invention will now be described in more detail, with reference to the appended drawings showing a currently preferred embodiment of the invention. Like numbers refer to like features throughout the drawings.
The light module 120 comprises a first face 121 through which light is emitted, and a second face 122 opposite of the first face 121. The plurality of retainer means 130 are provided at the second face 122 of the light module and are configured for engaging the first wall 114 and the second wall 116. A stopper means 140 is implemented to prevent inward displacements of the light module 120 past a predetermined boundary. The housing 110 may comprise a planar support surface 111 to fix the housing to a wall, a first side wall extending from the support surface 111, a second side wall extending from the support surface 111 opposite of the first side wall. The first side wall comprises a first upper wall 112 extending outward and away from the mounting surface, and a first lower wall 113 extending inward and away from the first upper wall 112 and joining to the first upper wall 112. The second side wall comprises the first wall 114 extending away from the support surface 111, a second portion 115 extending outwardly at an angle of the first wall 114 and joining to the first wall 114, and a second lower wall 117 extending in a symmetrical manner as the first lower wall 113. Thus an elongate opening is formed by the edges of the first lower wall 113 and the second lower wall 117. An external compartment 180 is defined by the first wall 114, the second portion 115 of the second side wall, and a portion of the outer casing. This external compartment 180 may be used to contain additional electronic or non-electronic devices, e.g. wires. A second wall 116 extends from the support surface 111 towards the elongate opening and parallel to the first wall 114. There may be a first ridge 118 at the joining of the first wall 114 and the second portion 115, and a second ridge 119 at the extremity of the second wall 116. As will be explained below, the first ridge 118 and the second ridge 119 are intended for cooperating with the plurality of retainer means 130. The elongate housing 110 shown in
The light module 120 has a first face 121 through which light is emitted. The first face may be a plate composed of a transparent or translucent material. A second face 122 of the light module opposite of the first face 121 may be a cup-shaped plate, e.g. made of plastic.
A plurality of retainer means 130 may be provided at the second face of the light module 122.
The stopper means 140 role is to prevent inward displacement of the light module past a predetermined boundary. The stopper means 140 comprises at least one element for engaging an edge of the first wall 114 and the second wall 116. The stopper means 140 may be configured to prevent further inward displacements of the light module 120 when the protruding curved portion 133 of each of the plurality of retainer means 130 is behind the first ridge 118 and the second ridge 119. The stopper means 140 may have a first and a second longitudinal side 141 extending in the longitudinal direction, and a first and a second lateral side 142 extending between the first longitudinal side and the second longitudinal side 141. The stopper means may comprise a first and a second lateral edge 143 at the first and the second lateral side 142 of the stopper means, respectively. The first and the second edge 143 engage with the edge of the first wall 114 and the edge of the second wall 116. The first and the second edge 143 may be designed so that the engagement occurs when the protruding curved portion 133 of each of the plurality of the retainer means is past the first ridge 118 and the second ridge 119.
At least one electronic component may be mounted to the second face 122 of the light module. A driver 151 to drive at least one light module 120 might be the at least one electronic component. The at least one electronic component is mounted such that it may be located in a space within the bounds of the mounting inner surface 111 of the elongate housing, the first wall 114, the second wall 116, and the mounting surface 144 of the stopper means. The at least one electronic component may be fixed in a gear tray 150 provided to the mounting surface 144 of the stopper means or to the second face 122 of the light module.
To adjust the longitudinal position of the light module 120 within the elongate housing, a spacer block 160 may be used. The spacer block 160 can be mounted within the elongate housing using a similar stopper means 140 and retainer means 130 as the light module 120. To complete the enclosure of the light module within the elongate housing, cover plates 170 may be fixed to each open end of the elongate housing extruded profile. The spacer block 160 may be designed in extruded metal, preferably aluminum, to align with the outer edges of the elongate opening when mounted within the elongate housing 110.
Number | Date | Country | Kind |
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20175362 | May 2017 | BE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2018/061908 | 5/8/2018 | WO | 00 |