The present invention relates to a method for mounting functional elements in a lens.
Miniaturization of cameras and other optical elements provide fields for new applications relating to the vision of users.
US 2015/0009309 shows an optical frame for glasses with an build-in camera and an actuator for said camera. The camera is positioned on the frame outside of the lenses.
US 2017/0090564 discloses systems and methods for providing a display of a wearable device and is related to elements for an eye-tracking device. Such devices need illumination; usually provided by LEDs and cameras directed towards the eye for determining the gaze. It is disclosed that the illuminating elements can be provided on or in a lens of glasses. These LEDs as well as sensors for sensing the light reflected from an illuminated eye can be provided on flexible printed circuits which are oriented to minimize the visible profile thereof.
WO 2006/091873 shows manufacturing methods for embedded optical systems, wherein different optical elements as mirrors, etc. are integrated within a glass body being prepared by providing a mould assembly, attaching the optical elements to a wall of the mould cavity and introducing an optical polymerizable casting compound into the mould cavity to obtain the optical component after curing.
WO 2015/162498 discloses an eyewear lens production using multi-layer additive techniques, where radiation polymerizable material is applied to the lens substrate and irradiated later on with controlled radiation so that an additive layer is formed at the selected irradiated areas according to the intended layer design.
EP 2 848 979 provides disclosure for different methods and apparatuses for providing variable optic inserts into ophthalmic lenses.
US 2017/0074494 provides over-moulded LEDs in virtual reality headsets.
US 2014/273316 A1 discloses methods and apparatus to form organic semiconductor transistors upon three-dimensionally formed insert devices. The three-dimensional surfaces incorporate with organic semiconductor-based thin film transistors, electrical interconnects, and energization elements into an insert for incorporation into ophthalmic lenses. The formed insert may be directly used as an ophthalmic device or incorporated into an ophthalmic device.
U.S. Pat. No. 9,636,050 B1 discloses a body-mountable device with two polymer layers and a structure with a sensor between these polymer layers. Forming the body-mountable device involves positioning the structure on the first polymer layer and then forming, in a molding piece, the second polymer layer over the structure positioned on the first polymer layer. The molding piece includes a surface that supports the second polymer layer during its formation and a protrusion that extends from the surface to the sensor through the second polymer layer in formation. The body-mountable device that is removed from the molding piece has a channel to the sensor formed by the protrusion.
Based on the prior art it is an object of the invention to provide an improved method for placing and orienting functional elements in lenses. Such functional elements can be light sources as LED's and miniature cameras as well as passive functional elements as crystals, e.g. diamonds or other light reflecting or diffracting elements as mirrors or gratings.
Such a method for mounting functional elements in a lens comprises the steps of: mounting the functional elements on a foil, applying a closed contour alignment surface of an alignment tool having a central opening surrounded by the closed contour on the foil portion opposite to the mounted function elements, applying underpressure on the central opening to maintain the foil portion with the mounted functional elements on the alignment tool, cutting a flap comprising the foil portion and supporting the functional elements out of the foil, positioning and aligning the flap through actuators, fixing the position of the flap against the adjacent foil surface, embedding the foil with the mounted functional elements in a predetermined distance to the front surface of a casting mould, and casting and curing the lens with the embedded foil. Here, no specific FPCB is provided on the mould opposite to the mould supporting the foil and having the central opening for positioning and aligning the functional elements in view of the foil. Then passive functional elements can be contacted directly and active functional elements are to be contacted through the foil portion, e.g. by contact elements passing through the foil.
The step of mounting the functional element on a foil can be preceded by placing the functional element on a flexible printed circuit board (FPCB) and affix it there. The flexible printed circuit board can be provided near and at the edges of the lens to be fabricated and comprise contact plates for active functional elements as cameras and light sources as LEDs. Then the method for mounting functional elements in a lens comprises the steps of: mounting the functional elements on a FPCB and affix it there, mounting the FPCB with the affixed functional elements on a foil and affix it there, applying a closed contour alignment surface of an alignment tool having a central opening surrounded by the closed contour on the foil portion opposite to the mounted function elements, applying underpressure on the central opening to maintain the foil portion with the mounted functional elements on the alignment tool, cutting a hole in the foil portion with the functional elements supported by the FPCB or cutting a flap comprising the foil portion and the functional elements supported by the FPCB out of the foil, respectively, positioning and aligning the functional elements supported by the FPCB on the cut-out foil portion or the flap with the functional elements supported by the FPCB through actuators, respectively, fixing the position of the cut-out foil portion with the functional elements on the FPCB or the position of the flap against the adjacent foil surface, embedding the foil with the mounted functional elements on the FPCB in a predetermined distance to the front surface of a casting mould, and casting and curing the lens with the embedded foil.
The method can have a step of placing the functional element on a flexible printed board circuit and affix it there with positioning the flexible printed board circuit on the surface of a mould, especially in complementary recesses, and applying underpressure from the mould side through at least one vacuum channel in the mould, wherein the functional element is positioned by a functional element alignment tool through the vacuum channel on the flexible printed board circuit.
A further method for mounting functional elements in a lens comprises the steps of mounting a functional element on a flexible printed board circuit, providing an alignment element on a foil having a predetermined mounting surface for the functional element, positioning the functional element on the alignment element, fixing the position of the functional element on the alignment element, embedding the foil with the mounted functional elements in a predetermined distance to the front surface of a mould, and casting and curing the lens with the embedded foil.
Mounting a functional element on a flexible printed circuit board can comprise providing a vacuum channel in a mould holding the flexible printed circuit board and within which vacuum channel the functional element is held with play before being positioned on the alignment element.
The functional element to be placed can comprise at least one camera or a light emitting element or a passive element.
When the functional element to be placed comprises at least one camera, then the alignment step comprises connecting the camera to a visualizing unit and providing a light source emitting light in a predetermined direction and positioning and aligning the camera based on the images obtained on the visualizing unit from the camera.
When the functional element to be placed comprises at least one light source, then the alignment step comprises providing a camera and a visualizing unit, wherein the camera receives light from the light source, and positioning and aligning the light source is based on the images obtained on the visualizing unit from the camera.
Finally, when the functional element to be placed comprises a passive element reflecting or diffracting incoming light, then the alignment step comprises providing a light source, a camera and a visualizing unit, wherein the camera receives light from the passive element illuminated by the light source, and positioning and aligning the passive element is based on the images obtained on the visualizing unit from the camera.
Further embodiments of the invention are laid down in the dependent claims.
Preferred embodiments of the invention are described in the following with reference to the drawings, which are for the purpose of illustrating the present preferred embodiments of the invention and not for the purpose of limiting the same. In the drawings,
One advantage of the method according to the invention is based on the predetermined correct positioning and alignment according to a predefined angle in relationship to the lens geometry. Passive functional elements 230 can be mounted directly on the foil 216 and aligned afterwards in an alignment step similar to step 115 explained later through alignment tool with vacuum sleeve 225. The following description explicitly allows placement of active and passive functional elements, since a FPCB is involved, provided on the mould 212 opposite to mould 211 supporting the foil 216. The method steps of the method without a FPCB are—beside the use of the FPCB as intermediate external contact element provided directly between the functional element 230 and the foil 216—identical.
The method as shown in
The next step in the method relates to mounting the functional elements on a flexible printed circuit board (FPCB). This step 112 mentions functional elements, which could be electronic elements such as cameras and/or LEDs as active elements.
At the position of the opto-electronic elements at least one through-going hole 215 is prepared in mould 212 to fix the flexible printed circuit board 220 by means of vacuum from the opposite side of the tool mould 212. The second mould 212 can comprise the same alignment pin bores 214 as the first mould 211 to precisely align on one side the flexible printed circuit board 220 with the opto-electronic elements 230 with respect to the foil 216 and the second mould 212 face to the first mould 211 as shown in
Method step 114 is related to applying a cut-out around the cameras 230 by using a die cutting tool from the foil. This step can be performed earlier in the process sequence. It can be seen in
The flexible conductor 221 can be positioned in the according recess and the cameras/LEDs are placed in the vacuum bore holes to attach the flex on the foil.
Then, this method step 116 is followed by embedding method step 117, wherein the foil 216 with the attached aligned opto-electronic element(s), as e.g. camera 230, LEDs or passive elements, is mounted to the front of a back mould at a defined distance.
Then, the mould cavity itself is formed by aligning front and back mould 211 and 212, i.e. first and second mould, with the attached foil 216 by applying a tape or gasket to seal the mould cavity when the usual production step 118 follows, wherein the mould cavity is filled with curable resin and cured e.g. by applying UV-irradiation or heat.
In
Same features receive the same reference numerals. This is also true for identical or very similar steps in the method step of
The initial steps 111 and 112 of forming the foil and mounting the opto-electronic elements on a flexible PCB are still the same as explained in connection with
The method according to the flowchart of
In a different approach the printed conductor is printed directly on the surface of the wedge 350 or it can be printed on the flat foil 216 wherein the surface mount of the optoelectronic element 230 is done on the printed conductors and finally in step 119 the mould cavity is filled with a curable resin and cured by a UV radiation. Reference numeral 353 would either be a FPCB or—in case printed conductors are used—would be directly placed on the conductor on the wedge (e.g. by MID technology). Here, step 313 comprises positioning of the FPCB 353 with the camera 230 in the corresponding opening 351 which is a vacuum channel having a front part enclosing the camera 230 with play avoiding imposing a specific orientation of camera 230. The front part of the vacuum channel 351 is an indentation 352 with a central hole to steadily apply suction on the camera 230 in the indentation to maintain it prior to fixation in a still orientable way.
The camera 230 can be angled applying a cut out as explained in connection with
Within an alternative process sequence the foil forming step 111 to match the curvature of the lens is preceded by two further steps. One step 411 is related to printing the conductors on a flat foil, e.g. by screen printing and curing the conductors. The second step 412 is related to mounting of optoelectronic elements such as cameras 230 and/or LEDs on the prepared flat foil with conductors.
Then as in the previously described method, in a positioning step 413, a cut-out is created in the foil for a flap with the camera mounted thereon and a following positioning and alignment procedure with the alignment tool or the element as camera 230 is placed on the wedge or prism wherein the conductors can be e.g. applied according to MID Technology to conform to the additional form of the prism 350 allowing for direct alignment of the camera on the wedge.
Then the steps of foil embedding 117 and lens casting 118 follow as explained above.
Number | Date | Country | Kind |
---|---|---|---|
01167/18 | Sep 2018 | CH | national |
18214660 | Dec 2018 | EP | regional |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2019/075939 | 9/25/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2020/064879 | 4/2/2020 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
9636050 | Etzkorn et al. | May 2017 | B1 |
20060126698 | Blum et al. | Jun 2006 | A1 |
20060192306 | Giller | Aug 2006 | A1 |
20070069418 | Liao | Mar 2007 | A1 |
20120148820 | Okuya | Jun 2012 | A1 |
20140273316 | Pugh et al. | Sep 2014 | A1 |
20150009309 | Heinrich et al. | Jan 2015 | A1 |
20150183173 | Linhardt et al. | Jul 2015 | A1 |
20150293375 | Pfeffer et al. | Oct 2015 | A1 |
20160144582 | Ihara et al. | May 2016 | A1 |
20170074494 | Thomas | Mar 2017 | A1 |
20170090564 | Gustafsson et al. | Mar 2017 | A1 |
Number | Date | Country |
---|---|---|
101646968 | Feb 2010 | CN |
101821085 | Sep 2010 | CN |
104149260 | Nov 2014 | CN |
105980910 | Sep 2016 | CN |
107438515 | Dec 2017 | CN |
2848979 | Mar 2015 | EP |
2006091873 | Aug 2006 | WO |
2015162498 | Oct 2015 | WO |
2018087011 | May 2018 | WO |
Entry |
---|
First Office Action, CN Application No. 201980063169.2, dated Aug. 1, 2022, pp. 1-6. |
International Search Report issued in PCT/EP2019/075939 dated Feb. 13, 2020, pp. 1-4. |
Number | Date | Country | |
---|---|---|---|
20210339490 A1 | Nov 2021 | US |