FR3146192A1 - OPTICAL BLOCK WITH CAVITY PREVENTING THE PASSAGE OF PHOTONS - Google Patents

Abstract

An optical unit, for example of a vehicle, comprises a housing housing a light device (DL) delivering photons ensuring a first photometric function, and a support (SG) produced by molding and comprising at least one wall (PS) delimiting a groove (G1) in which is installed a light guide (GL1) delivering photons ensuring a second photometric function, and comprising a part (PP) defining a separation wall with this light device (DL) and housing one end (E22) of the light guide (GL1). This part (PP) comprises a terminal sub-part (SPT) defining a single-piece cavity (CM) fixedly housing, by masking it, this end (E22), and arranged so as to prevent a passage of photons between this groove (G1) and this light device (DL). Figure 3

Description

OPTICAL BLOCK WITH CAVITY PREVENTING THE PASSAGE OF PHOTONS Technical field of the invention

The invention relates to optical blocks which provide at least two different and similar photometric functions, and more precisely the sealing between these photometric functions.

State of the art

In some areas, such as vehicles, possibly of the automobile type, optical units are used which provide at least two different and similar photometric functions.

In the following, the term "photometric function" means a photometric signaling function, a photometric lighting function or a photometric lighting effect function, possibly decorative.

The invention relates more specifically to optical units which comprise a housing housing:

- a light device capable of delivering first photons ensuring a first photometric function, and

- a support produced by molding and comprising at least one wall, on the one hand, delimiting a groove in which is installed a light guide capable of delivering second photons ensuring a second photometric function, and, on the other hand, comprising a part defining a separation wall with the lighting device and housing one end of this light guide.

Typically, the end of the light guide (located in the immediate vicinity of the light fixture) includes a clipping tab that passes through a clipping hole defined in the part of the support wall that defines the separation wall. Furthermore, due to the technical clearances required for assembling the various elements of the optical unit, there are small passages at the end of the part of the support wall that defines the separation wall.

Therefore, first photons of the first photometric function can reach the groove comprising the light guide and then into the latter, just as second photons of the second photometric function can reach the light device, by passing through the clipping hole or one of the aforementioned passages.

This lack of sealing between the support (of the light guide(s)) and the lighting device proves to be problematic. Indeed, it can generate stray light at the level of at least one of the first and second photometric functions, which can prove to be unsightly and/or make at least one photometric function non-compliant with a regulation in force. In addition, when the first and second photons have wavelengths corresponding to different colors (for example white and amber (or red)), it can generate by mixing a slight modification of the base color of at least one of the first and second photometric functions, which can make it non-compliant with a regulation in force.

The invention is therefore intended in particular to improve the situation.

Presentation of the invention

For this purpose, it offers in particular an optical unit comprising a housing housing:

- a light device capable of delivering photons ensuring a first photometric function, and

- a support produced by molding and comprising at least one wall, on the one hand, delimiting a groove in which is installed a light guide capable of delivering photons ensuring a second photometric function, and, on the other hand, comprising a part defining a separation wall with the lighting device and housing one end of this light guide.

This optical block is characterized by the fact that the part of its support comprises a terminal sub-part defining a single-block cavity fixedly housing, by masking it, the end of the light guide, and arranged so as to prevent a passage of photons between the groove and the lighting device.

Thanks to the invention, there is no longer any need to clip the end of the light guide to the part of the wall and therefore the photons cannot pass through this part, and at the same time the passages resulting from the technical games at the level of the terminal sub-part and the lighting device are no longer annoying because the photons can neither exit the end of the light guide nor penetrate this end, and therefore there is no longer any risk of generating stray light or mixing of colors.

The optical unit according to the invention may include other characteristics which may be taken separately or in combination, and in particular:

- the (each) single-block cavity may have the general shape of a parallelepiped having a front face facing outwards and at least partially closed, an open face substantially perpendicular to this front face and crossed by the end of the light guide, and four other closed faces including a rear face opposite this front face, an end face opposite this open face and defining a sub-part of the separation wall, and two lateral faces opposite each other and substantially perpendicular to the front face and rear face;

- in the presence of the first option, each of the side faces can make an obtuse angle with the end face in order to facilitate lateral demolding by drawer of the support;

- its support may comprise two walls respectively delimiting two grooves in which are respectively installed two light guides each having their end housed in a single-block cavity and masked by the latter;

- it may include in a front part a mask masking the front face of the (each) single-block cavity;

- the first photometric function may be a lighting function or a signaling function. For example, this first photometric function may be a direction change indication function (or flashing light);

- the second photometric function may be a signaling function. For example, this second photometric function may be a daytime running light (or DRL) function.

The invention also proposes a vehicle, possibly of the automobile type, and comprising at least one optical unit of the type presented above.

Brief description of the figures

Other features and advantages of the invention will appear on examining the detailed description below, and the attached drawings (obtained in CAD/CAM (“Computer Aided Design/Computer Aided Drawing”)), in which:

schematically illustrates, in a cross-sectional view in a horizontal plane, part of an exemplary embodiment of an optical block according to the invention,

schematically illustrates, in a front view from the front side, the support of the optical unit of the , equipped with two light guides,

schematically illustrates, in a sectional view in a horizontal plane, the terminal sub-part of the first wall of the support of the defining a first groove, with the end of the first light guide,

schematically illustrates, in a perspective view from the front face side, the terminal sub-part of the first wall of the support of the defining a first groove, in the absence of the first light guide, and

schematically illustrates, in a sectional view in a vertical plane, the terminal sub-part of the first wall of the support of the defining a first groove, in the absence of the first light guide.

Detailed description of the invention

The invention aims in particular to propose an optical block BO ensuring at least first and second different and similar photometric functions, and with single-block cavity(ies) CM preventing the passage of photons.

It is considered in the following, as a non-limiting example, that the optical unit BO is intended to be part of a vehicle of the automobile type, such as for example a car. However, the invention is not limited to this application. Indeed, the optical unit BO can be equipment that can be added and used in many systems or that can be part of other equipment that is itself part of a system. Thus, the optical unit BO can be part of any system, and in particular a vehicle (land, sea (or river), or air), an installation (possibly industrial), a device (possibly general public), or a building.

Furthermore, it is considered in the following, as a non-limiting example, that the optical unit BO constitutes a headlight (or projector) of a vehicle. But it could constitute a front light or a rear light of a vehicle.

Finally, taking into account the preceding choices, it is considered in the following, by way of non-limiting example, that the optical unit BO is intended to provide at least first and second photometric signaling functions. By way of example, in the case of an application to a motor vehicle, the first photometric signaling function may be a direction indicator function (or turn signal) and the second photometric signaling function may be a daytime running light function (or DRL). However, the first photometric signaling function could be a position light function or a stop light function, and the second photometric signaling function could be a stop light function.

It should be noted, however, that the invention is not limited to photometric signaling functions. Indeed, the optical unit BO, according to the invention, is a light device capable of providing at least a first photometric signaling or lighting or light effect function (possibly decorative) and a second photometric signaling or lighting or light effect function (possibly decorative).

In the above and the following, the notion of "front" is defined in relation to the place where the photons participating in the (a) photometric function exit, and the notion of "back" is defined in relation to the place which is opposite to that where the photons participating in the (a) photometric function exit. Consequently, the front face of an element is oriented towards the outside, while the back face of this element is oriented towards the inside and opposite the front face.

We have schematically illustrated on the a part of an exemplary embodiment of an optical unit BO according to the invention, here intended to equip a front part of a vehicle.

As illustrated in the , an optical block BO, according to the invention, notably comprises a housing BB, a light device DL, a support SC and at least one light guide GLj.

The BB housing delimits, preferably with a GP glass, an internal housing in which the DL lighting device and the SC support are fixedly installed, and at least partially, as well as possibly at least one MB mask responsible for masking the technical parts in a front part of the BO optical unit.

The light device DL is capable of delivering first photons which provide a first photometric function (here a direction change indicator function (or flashing light)). For this purpose, it comprises a first photon source SP capable of generating first photons, at least one optical element RP, such as for example a reflector RP (possibly parabolic), as well as possibly a first translucent screen EC1 to allow the first photons to pass through a front part, upstream of the window GP. For example, the first photon source SP may be a bulb (possibly xenon) or at least one light-emitting diode (or LED) or at least one laser diode or even a gas laser.

The support SG is made by molding, for example from a plastic or synthetic material, preferably rigid and resistant. In addition, it comprises at least one wall PS which delimits a groove Gj in which is installed a light guide GLj suitable for delivering second photons ensuring the second photometric function. This wall PS comprises a part PP which defines a separation wall with the light device DL and houses a (second) end E22 of the light guide GLj. In the example illustrated non-limitingly on the , this PP part defines a separation wall in the forward extension of the RP reflector of the DL lighting device.

It should be noted that in the example illustrated without limitation on the the SG support comprises two walls (one lower and the other upper) delimiting respectively first G1 (j = 1) and second G2 (j = 2) grooves in which are respectively installed first GL1 (j = 1) and second GL2 (j = 2) light guides. But the SG support could comprise only one wall PS.

Each groove Gj comprises first E11 and second E12 opposite ends respectively housing first E21 and second E22 opposite ends of a light guide GLj.

The first end E21 of each light guide GLj is supplied with second photons by a second photon source (not shown). For example, the second photon source may be at least one light-emitting diode (or LED) or at least one laser diode or a bulb (possibly xenon) or even a gas laser.

As illustrated without limitation on the , the BB housing can also accommodate, downstream of each GLj light guide and upstream of the GP glass, a second translucent EC2 screen to allow the second photons exiting this GLj light guide to pass through in a front part.

As it appears better on the , the PP part of the PS wall of the SG support comprises a terminal sub-part SPT which defines a single-piece cavity CM fixedly housing, by masking it, the second end E22 of the light guide GLj (here the first GL1). This single-piece cavity CM is arranged so as to prevent the passage of photons between the groove Gj (here the first G1) and the light device DL.

It will be understood that the terminal sub-part SPT is here located in the immediate vicinity of the first screen EC1 of the lighting device DL.

Thanks to this single-block cavity CM, which completely or almost completely surrounds and immobilizes the second end E22 of the light guide GLj (located in the immediate vicinity of the lighting device DL), there is no longer any need to clip this second end E22 to the PP part of the PS wall. There is therefore no longer any need to define a clipping hole in this PP part of the PS wall, which prevents the passage of first and second photons through this PP part. In addition, the passages resulting from the technical clearances essential for assembling the various elements of the optical block BO at the level (here) of the terminal sub-part SPT and the first screen EC1 of the lighting device DL, are no longer a problem because the second photons can no longer exit the second end E22 and head towards these passages, just as the first photons can no longer penetrate the second end E22. There is therefore no longer any risk of generating stray light or mixing of colours (of photons) at the level of at least one of the first and second photometric functions.

For example, and as illustrated non-limitingly and at least partially in FIGS. 3 to 5, the single-block cavity CM may have a general parallelepiped shape having a front face FV opposite a closed rear face FR, two closed and opposite side faces FL, a closed end face FE, and an open face FO.

The front face FV is oriented towards the outside and at least partially closed. In the example illustrated without limitation on the , the FV front face is partially closed, but it could be completely closed.

The open face FO is substantially perpendicular to the front face FV and crossed by the second end E22 (see ).

The rear face FR is opposite the front face FV, and substantially perpendicular to the open face FO.

The end face FE is opposite the open face FO and defines a sub-part of the dividing wall. It therefore comprises an external sub-face, which is located at the interface with the light device DL in the vicinity of the first screen EC1, and an internal sub-face, which is located at the interface with the second end E12 of the groove Gj.

The two side faces FL are substantially perpendicular to the front face FV and rear face FR (see figures 4 and 5).

It should be noted that the CM single-block cavity could have other general shapes, notably cylindrical, possibly with a circular section.

Also for example, and as illustrated non-limitingly and at least partially in figures 4 and 5, each of the side faces FL can make an obtuse angle (or open or even a draft angle) with the end face FE in order to facilitate lateral (or transverse) demolding by drawer of the support SG.

In fact, the single-block cavity CM is demolded in a transverse direction, perpendicular to the main demolding axis of the SG support, which preferentially requires that the side faces FL make an obtuse angle with the end face FE and therefore with the transverse demolding direction. During demolding, the main part of the mold is first opened in the main demolding direction, then, once the main part of the mold is released, the drawer is translated in the transverse demolding direction (perpendicular to the main demolding direction), which allows the injected part, which then constitutes the SG support, to be completely removed from the mold.

It should be noted that the use of a drawer in the mold can generate a visible parting plane between the parts which demold respectively according to the main demolding direction and transverse demolding direction. This parting plane and the draft (obtuse angles) of the single-block cavity CM being visible, it is advantageous to provide the second screen EC2 in front of the (each) light guide GLj to make them invisible or at least make them blurred. This second screen EC2 can then include optics/prisms (or an opaline material).

For example, each obtuse angle can be between 2° and 5°.

Also for example, and as illustrated non-limitingly and at least partially in FIGS. 1 and 3, the optical block BO can also comprise in a front part a mask MB arranged so as to mask the front face FV of the single-block cavity CM, because it constitutes a technical part.

It should be noted, as illustrated without limitation on the , that when the support SG comprises two PS walls delimiting respectively first G1 and second G2 grooves in which are respectively installed first GL1 and second GL2 light guides, the upper PS wall (here), which is remote from the lighting device DL, can also comprise an end sub-part SPT defining a single-piece cavity CM housing, masking and immobilizing the second end E22 of the second light guide GL2. This makes it possible to avoid having to add a clipping tab to this second end E22 and to define a clipping hole in the PP part of the upper PS wall.

Claims (10)

Optical block (BO) comprising a housing (BB) housing i) a light device (DL) capable of delivering photons ensuring a first photometric function, and ii) a support (SG) produced by molding and comprising at least one wall (PS) delimiting a groove (Gj) in which is installed a light guide (GLj) capable of delivering photons ensuring a second photometric function, and comprising a part (PP) defining a separation wall with said light device (DL) and housing one end (E22) of said light guide (GLj), characterized in that said part (PP) comprises a terminal sub-part (SPT) defining a single-piece cavity (CM) fixedly housing, by masking it, said end (E22), and arranged so as to prevent a passage of photons between said groove (Gj) and said light device (DL). Optical block according to claim 1, characterized in that said single-block cavity (CM) has the general shape of a parallelepiped having a front face (FV) facing outwards and at least partially closed, an open face (FO) substantially perpendicular to said front face (FV) and crossed by said end (E22), and four other closed faces including a rear face (FR) opposite said front face (FV), an end face (FE) opposite said open face (FO) and defining a sub-part of said separation wall, and two lateral faces (FL) opposite each other and substantially perpendicular to said front face (FV) and rear face (FR). Optical block according to claim 2, characterized in that each of said lateral faces (FL) makes an obtuse angle with said end face (FE) in order to facilitate lateral demolding by drawer of said support (SG). Optical unit according to one of claims 1 to 3, characterized in that said support (SG) comprises two walls (PS) respectively delimiting two grooves (Gj) in which are respectively installed two light guides (GLj) each having their end (E22) housed in a single-block cavity (CM) and masked by the latter (CM). Optical unit according to one of claims 1 to 4, characterized in that it comprises in a front part a mask (MB) masking said front face (FV) of the single-block cavity (CM). Optical unit according to one of claims 1 to 5, characterized in that said first photometric function is a lighting function or a signaling function. Optical unit according to claim 6, characterized in that said first photometric function is a direction change indication function. Optical unit according to one of claims 1 to 7, characterized in that said second photometric function is a signaling function. Optical unit according to claim 8, characterized in that said second photometric function is a daytime running light function. Vehicle, characterized in that it comprises at least one optical unit (BO) according to one of claims 1 to 9.