CH708730A2 - Touch portable electronic object. - Google Patents

Abstract

The present invention relates to a portable electronic object (1) provided with a housing (10) comprising a middle (11) closed by a bottom and by an ice (13) and a bezel (14) fixed to the middle part, said housing enclosing at least one electronic module (20) consisting of a printed circuit (22) to which at least one microcontroller (23) sending information to display means is attached, said object further comprising tactile control means comprising at least one least one support (51) on which at least one electrode (52) is arranged, said electrode being electrically connected to the microcontroller by a conductive track. This portable object can be a mobile phone, a mobile GPS device, a laptop, a touch pad, a heart rate monitor for sports, a music player or a timepiece.

Description

Description

The invention relates to an electronic portable object provided with a housing comprising a middle part closed by a bottom and an ice and a bezel attached to the middle part, said housing enclosing at least one electronic module consisting of a printed circuit on which is fixed at least one control circuit sending information to display means, said object further comprising touch control means comprising at least one substrate on which at least one electrode is deposited, said electrode being electrically connected to the circuit control by a conductive track.

BACKGROUND TECHNOLOGY

An electronic portable object such as an electronic device or for example a portable timepiece comprises a box generally composed of a middle part closed by a bottom and by an ice. In this box, a watch movement is arranged, the latter being electro-mechanical or totally electronic. This watch movement is arranged to provide a time information, said time information being displayed via analog or digital display means. The timepiece further comprises control means allowing the user to interact with said timepiece.

In general, the control means are in the form of push buttons or a ring acting mechanically on said watch movement. But these buttons and crowns can be completed with a touch interface. This touch interface is used to improve the interactivity of the timepiece and to simplify handling especially when the timepiece offers a large number of menus and functions.

This touch interface can be a resistive touch interface or a capacitive touch interface. For the case of a capacitive touch interface, it may be in the form of an electrode placed on the underside of the ice, this ice representing an electrically non-conductive element. This electrode is subjected to an electric field. When the user wants to activate the interface, he makes contact on the outer face of the ice, preferably with his finger. By this we mean that this contact can be a support or a touch. This contact causes the appearance of an additional capacitance which is formed between said electrode and the finger which is an electrically conductive element. This variation of capacity is detected by the electronic watch movement which will act according to its programming. This touch interface is made on the ice of the watch and not on the housing because it is usually made of metal and is electrically conductive. It does not allow the appearance of a capacity.

However, these tactile interfaces arranged on the ice of the timepiece have the disadvantage of not allowing not optimal visibility of the information. Indeed, the fact of having a touch interface arranged on the ice of the timepiece implies that the user must regularly put his fingers on the ice. This has the consequence that the visibility of the information displayed on the dial is regularly reduced by the fingers of the user. The latter therefore has more difficulties to take knowledge of the information provided by the timepiece.

Moreover, these tactile keys are generally made by depositing a metal layer such as an ITO layer for Indium-Tin-Oxide on a substrate such as ice. However, a disadvantage of the application of such an ITO layer on the ice is that it is a complex and expensive operation. Therefore, extreme manufacturing rigor is necessary to have a good production yield.

SUMMARY OF THE INVENTION

The invention aims to overcome the disadvantages of the prior art by providing a portable electronic touch object that is simpler to produce and less expensive and more flexible to use.

To this end, the invention relates to a portable electronic object provided with a housing comprising a middle part closed by a bottom and an ice and a bezel attached to the middle part, said housing enclosing at least one electronic module consisting of a printed circuit board to which at least one microcontroller sending information is attached to display means, said object further comprising tactile control means comprising at least one support on which at least one electrode is arranged, said electrode being electrically connected to the microcontroller by a conductive track, characterized in that the substrate is flexible so that it can be deformed to adapt to the shape of the portable object.

In a first advantageous embodiment, the support is made of a plastic such as polyimide, the electrode being a layer of conductive material deposited on said support.

In a second advantageous embodiment, the tactile control means comprise a plurality of supports on each of which an electrode is arranged.

In a third advantageous embodiment, the tactile control means comprise a plurality of supports on each of which at least two electrodes are arranged.

In another advantageous embodiment, each support comprises a main section connected by one of its ends to the electronic module and two arms extending on either side of the free end of said main section, the electrodes being arranged on said arms.

In another advantageous embodiment, the tactile control means comprise a support on which a plurality of electrodes are arranged, said support comprising a peripheral section connected by a secondary section to the electronic module, the electrodes being arranged on said section. peripheral.

In another advantageous embodiment, said peripheral portion of the support has a shape identical to that of the box.

In another advantageous embodiment, the touch control means are arranged at the level of the telescope.

In another advantageous embodiment, the telescope is a fixed telescope.

In another advantageous embodiment, the telescope is a rotating bezel.

In another advantageous embodiment, the middle and the bezel are one piece to form a middle-bezel.

BRIEF DESCRIPTION OF THE FIGURES

The objects, advantages and characteristics of the portable electronic object or apparatus according to the present invention will appear more clearly in the following detailed description of at least one embodiment of the invention given solely by way of nonlimiting example. and illustrated by the accompanying drawings in which: FIG. 1 schematically represents a sectional view of a portable electronic object according to the invention; fig. 2 schematically represents a sectional view of a rotating bezel alternative of a portable electronic object according to the invention; fig. 3 schematically shows a sectional view of an alternative to the bezel-middle of a portable electronic object according to the invention; figs. 4 to 6 schematically represents variants of the tactile means according to the invention.

DETAILED DESCRIPTION

In FIG. 1, a portable electronic device 1 or portable electronic object according to the invention is shown. This portable electronic object can be a mobile phone or a mobile GPS device or a laptop or a touch pad, a cardio-frequency meter for sports or a music player or a timepiece.

This electronic device comprises a box 10 also called a box, consisting of a middle part 1 1 closed by a bottom 12 (not shown in FIG 1 but visible in FIG 2) and by a glass 13. In this housing 10, an electronic module 20 is arranged. This electronic module 20 is configured to provide at least one information to be displayed to display means 30. This electronic module 20 is for example an electronic watch movement 11.

This module 20 itself comprises a plate 21, a compartment or housing is arranged for receiving an accumulator of electrical energy, including a battery.

This module 20 also comprises at least one printed circuit 22 or PCB fixed on said plate. On this printed circuit 22, at least one microcontroller 23 is placed and configured to provide at least one piece of information. The microcontroller 23 may also be a specific integrated circuit (ASIC) with equivalent functions. This information is sent to the display means 30 which can be analog as needles or digital as an LCD screen. These display means are located between the lens 13 and the electronic module 20, a spacer or flange 31 being arranged between the lens 13 and the display means 30.

This module 20 may further comprise different sensors such as a pressure sensor to provide information on altitude or depth or on the weather. A temperature sensor or a sensor for a compass function can also be arranged. In addition, it is conceivable that a plurality of electronic modules 20 are arranged in the box 10, each of them providing at least one piece of information for the display means 30.

In the case where the portable electronic device is a timepiece, the module 20 or one of the modules 20 will be an electronic watch movement.

The timepiece 1 further comprises control means 40 used for the user to interact with said module 20. This allows the user to select the various functions and activate them. The control means 40 comprise at least tactile control means 50. The control means may also comprise push buttons or buttons arranged on the middle part 11.

Advantageously according to the invention, these tactile control means 50 comprise a flexible support 51 fixed to the electronic module 20 and on which at least one electrode 52 is arranged. This flexible support 51 is advantageously a flexible printed circuit, that is to say a high performance plastic substrate, such as polyimide (Kapton) or

3 polyester. The electrode 52 deposited is in the form of a layer of conductive materials forming a connection point. For example, the flexible printed circuit board 51 as a support can be silkscreened with silver on polyester or the flexible printed circuit board 51 can be screen printed with copper on Kapton. The electrode 52 has a circular or parallelepipedal shape see triangular.

To electrically connect the electrode 52 to the microcontroller 23, the touch control means 50 further comprise at least one connection track 53 arranged on said flexible support 51. This connection track 53 cooperates with at least one electrical track 23a. printed circuit board 22 connected to said microcontroller. It is possible to use connection points on the printed circuit 22 and on the support 51 to ensure electrical continuity. An adhesive can be used to fix the support 51 to the printed circuit 22.

An advantage of using these flexible printed circuits 51 is that they allow an assembly that can be performed with the components used for conventional printed circuits, while allowing the circuit to respect a particular shape, or by folding in use.

Another advantage of the use of a flexible support 51 is that the cost of such a flexible printed circuit is less than that of the deposition of an ITO layer on a substrate such as watch ice.

Finally, another advantage is the simplicity of the flexible printed circuit 51. In fact, not only does the use of a flexible printed circuit 51 impose no restriction on the level of the usable components, but the present invention makes it possible to have a single piece to support the electrode 52 and to connect the electrode 52 to the control circuit.

To have a use close to that of existing touchscreen watches, it is necessary to have a plurality of electrodes 52. In an advantageous arrangement, the touch control means 50 comprise twelve electrodes 52 each disposed on a support 51, twelve supports 51 are therefore necessary. These electrodes 52 are located at the middle of the middle so that the user can manipulate them. Of course, it is possible to choose the number of electrodes 52 and, for example, it is possible to have only one electrode 52 or to have only 6 or 7.

The housing 10 comprises for this purpose a bezel 14 for the arrangement of the electrodes 52. This bezel 14 is located at the middle 1 1 and surrounds the ice 13. It may be a rotating bezel 14c or a fixed telescope 14b. The bezel 14 may also be arranged so that the middle part 1 1 and the bezel 14 form a single piece that is to say a middle-telescope 14a. The middle 1 1 and the bezel 14 have an outer wall which is the face visible by the user and an inner wall. So that the electrodes 52 of the tactile control means 50 are effective, this bezel 14 is made of a non-conductive material so that the capacitive effect can take place. It is possible that the entire bezel is not made of a non-conductive material but that only the area on which the user acts is non-conductive. The sensitivity of the system is reduced but it still works if the size of the electrodes 52 is adapted, that is to say large enough.

Preferably, the supports 51 and 52 electrodes are arranged on the hour turn so as to be easily manipulated. These electrodes 52 are then arranged at the level of the telescope 14, that is to say at the middle-bezel 14a, the fixed bezel 14b or the rotating bezel 14c.

In an alternative where the electrodes 52 are arranged at the middle-bezel 14a, the flexible printed circuits 51 are bent so that the electrode 52 is in contact with the inner wall of the middle-bezel 14a as visible at fig. 3. It is conceivable that this inner wall is hollowed so that the flexible printed circuits 51 can be stalled. It is also possible to glue said flexible printed circuit 51 on this inner wall.

In another alternative with a fixed bezel 14b visible in FIG. 1, that if in the form of an annular piece 140. In the example of FIG. 1, the annular piece 140 fixed window 14b has a U-shaped section, the base of the U serving as a face visible by the user. The arm of this annular piece which is located opposite the ice is provided with a protrusion 141 extending from the free end of the arm perpendicular to said arm. This protrusion 141 is used during the assembly of the window 13 and the fixed window 14b, the window 14b being previously mounted to the window 13 so as to rest in part on the flange 31. When mounting the window 13, It is supported on the protrusion 141 of the annular piece 140 of the fixed bezel 14b. The fixed bezel 14b is then wedged between the glass 13 and the middle part 1 1. This arrangement allows to have a fixed bezel 14b having a hollow interior space.

When the electrodes 52 are arranged at the fixed bezel 14b, they are in the hollow portion of the bezel 14b. For this, the case 1 1 is hollowed so that a passage is present between the electronic module 20 and the hollow interior of the bezel as shown in FIG. 1. To maintain the flexible printed circuit 51 in the hollow interior space of the telescope, the solution used in FIG. 1 is to provide a hold 54. This wedge 54 is placed in the hollow interior space of the bezel. This shim 54 is arranged to fit between the flexible printed circuit 51 and the middle part 1 1. In this way, the shim 54 acts on the flexible printed circuit 51 so that the electrode 52 is in contact with the inner wall of the bezel 14b.

In another alternative with a rotating bezel 14c, that is also in the form of an annular piece 150. In the example of FIG. 2, the annular piece 150 of fixed window 14b has a section in three parts. This section is configured so that the rotating bezel 14c is provided with flanks having a first portion 151 extending perpendicular to the ice 13, a second portion 152 extending parallel to the ice 13 and a

4

Claims (11)

third inclined portion 153 connecting the first portion 151 and the second portion 152. At the free end of the first portion 151 and the third portion 153, attachment means 160 are provided. Fastening means 160 are maies such as hooks 161 inserted in grooves 162 of the middle part 1 1 serving as female parts. This case 1 1 then has a shoulder consisting of two perpendicular walls on which the female parts are arranged. The annular part 150 of the rotating bezel 14c and the shoulder of the middle part 1 1 make it possible to create an interior space. When the electrodes 52 are arranged at the rotating bezel 14c, they are in the hollow portion of the bezel 14c. For this, the case 1 1 is hollowed so that a passage is present between the electronic module 20 and the hollow interior of the rotating bezel 14c. As shown in fig. 2. To maintain the flexible printed circuit 51 in the hollow inner space of the rotating bezel 14c, the solution employed in FIG. 2 is to provide a shim 55. This wedge 55 is placed in the hollow inner space of the rotating bezel 14c. This shim 55 is arranged to fit between the flexible printed circuit 51 and the middle part 1 1. In this way, the shim 55 supports the flexible printed circuit 51 so that the electrode 52 close to the inner wall of the rotating bezel 14c without however come into contact with the rotating bezel 14c to allow the rotation of the bezel 14c. One can also imagine a frame located in the inner space formed by the annular part 150 of the rotating bezel 14c and the shoulder of the middle part. This frame makes it possible to support the flexible printed circuit 51. In a first variant visible in FIG. 4, it is possible to have more than one electrode 52 per support, that is to say flexible printed circuit 51. For this, the flexible printed circuit 51 has a suitable shape. This adapted form is in the form of a T, that is to say that the flexible printed circuit 51 comprise a main section 51 a. This main section 51a is connected at one end to the electronic module while at its free end, two arms 51b extend on either side. This configuration makes it possible to have the different electrodes 52 which are situated on the end of the flexible printed circuit 51 and at the level of the arms 51b. The conductive tracks 53 then converge towards the main section 51a to then be electrically connected to the microcontroller 23. Preferably, the arms 51b have a curvature so as to have a shape that follows that of the telescope 14. This curvature of the arms 51b allows a better integration of said flexible printed circuit 51. Thus, for an electronic object having twelve touch keys, it is conceivable to have four flexible printed circuits 51 according to the present variant as shown in FIG. 4. Each flexible printed circuit board 51 supports three electrodes 52 and sees his arms 51 b formed an arc. The sum of the arcs of the four flexible printed circuits 51 is a circle similar to that formed by the telescope 14. In a second variant visible in FIG. 5, the touch control means 50 comprise a single flexible printed circuit 51 arranged to support all the electrodes 52. For this, the flexible printed circuit 51 comprises a peripheral section 51c on which the different electrodes 52 are made. This peripheral section 51c has a shape identical to that of the box 10, that is to say that its shape may be annular or square or barrel-shaped. The peripheral section 51c is connected to the microcontroller 23 of the electronic module 20 by at least one secondary section 51d extending radially with respect to the annular section 51c. The conductive tracks 53 converge towards this secondary section 51 d to electrically connect the electrodes 52 to the microcontroller 23. In a preferred version of this second variant visible in FIG. 5, the flexible printed circuit 51 comprises two secondary sections 51 d. These secondary sections 51 d are diametrically opposed. This preferred version has the advantage of making it possible to simplify the electrical connection between the electrodes 52 and the microcontroller 23. The conductive tracks 53 are then divided into two groups, each converging towards a secondary section 51d. It will be understood that the tracks 53 which are angularly distant from a secondary section 51 d of an angle less than or equal to 90 ° converge towards it. An advantage of this second variant is that it allows a simplification of the manufacturing process because there is only one printed circuit to be produced and fixed to the electronic module 20. It will be understood that various modifications and / or improvements and / or combinations obvious to those skilled in the art can be made to the various embodiments of the invention described above without departing from the scope of the invention defined by the appended claims. Thus, it is conceivable that the electrodes 52 are in the form of the conductive track 53 which, at its free end, is wound on itself, the track not coming into contact with itself as visible in fig. 6. claims 1. portable electronic object (1) provided with a housing (10) comprising a middle part (1 1) closed by a bottom and by an ice (13) and a bezel (14) fixed to the middle part, said housing enclosing at least an electronic module (20) consisting of a printed circuit (22) to which is fixed at least one microcontroller (23) sending information to display means (30), said object further comprising tactile control means ( 50) comprising at least one support (51) on which at least one electrode (52) is arranged, said electrode being electrically connected to the microcontroller by a conductive track (53), characterized in that the substrate is flexible so that it can be deformed to fit the shape of the portable object. An electronic object according to claim 1, characterized in that the support (51) is made of a plastic, the electrode (52) being a layer of conductive materials deposited on said support. 3. An electronic object according to claim 1 or 2, characterized in that the touch control means (50) comprises a plurality of supports (51) on each of which an electrode (52) is arranged. 4. An electronic object according to claim 1 or 2, characterized in that the touch control means (50) comprises a plurality of supports (51) on each of which at least two electrodes (52) are arranged. 5. An electronic object according to claim 4, characterized in that each support (51) comprises a main section (51a) connected at one end to the electronic module and two arms (51b) extending from one side to the other. other of the free end of said main section, the electrodes being arranged on said arms. 6. An electronic object according to claim 1 or 2, characterized in that the touch control means comprise a support on which a plurality of electrodes are arranged, said support (51) comprising a peripheral section (51c) connected by a secondary section (51). d) the electronic module, the electrodes being arranged on said peripheral section (51c). 7. Electronic object according to claim 6, characterized in that said peripheral section (51c) of the support (51) has a shape identical to that of the box. 8. Electronic object according to one of the preceding claims, characterized in that the touch control means (50) are arranged at the bezel (14). 9. Electronic object according to claim 8, characterized in that the bezel (14) is a fixed bezel (14b). 10. Electronic object according to claim 8, characterized in that the bezel (14) is a rotating bezel (14c). 1. An electronic object according to claim 8, characterized in that the middle part (1 1) and the bezel (14) are a single piece to form a middle-telescope (14a). 6