PT105108A - SWITCH BY TOUCH INTEGRATED IN MODULAR COATING PLATE - Google Patents

Abstract

The present invention relates to a barrel which functions as a contact-sensitive switch to drive resistive, capacitive or inductive loads. THIS BRICK IS CONSTITUTED BY TWO BRICKS, ONE EMBEDDED IN THE CENTER OF THE OTHER, WHERE THE LITTLE ONE (1) IS PRESENT IN THE CENTRAL AREA OF THE LARGEST (2) AND WORKS AS A SWITCH. THE TWO BRICKS ARE UNITED BY A SEALING, O-RING, TRANSPARENT RING THAT ALLOWS THE PASSAGE OF THE LIGHT ISSUED BY PRESENCE LEDS PLACED ON THEIR INTERIOR SURFACE. O-RING ALSO HAS PURPOSE TO PROTECT FROM LIQUIDS. AS AN ACTIVATION ELEMENT THERE IS A PIEZOELECTRIC SENSOR ON THE MINIMUM BRICK INSIDE SURFACE, SENSITIVE TO THE RINGS CARRIED OUT ON THE EXTERIOR SURFACE. THE BRICK CONTAINS AN ELECTRONIC SYSTEM CONSISTING BY VARIOUS MODULES: ELECTRICAL SUPPLY, SIGNAL ACQUISITION, SIGNAL CONDITIONING, SIGNAL PROCESSING AND ACTUATION MODULE, EMBEDDED IN AN ELECTRONIC CIRCUIT ENCAPSULATED IN A BOX, INTEGRATED IN THE INSIDE OF THE BRICK.

Description

rear). The sensor / encapsulated switch system is not visible nor comes into contact with the user, with the entire signal acquisition and processing system integrated into the tile face that is not visible to users. A commercial piezoelectric sensor in film form encapsulated in transparent polyurethane film is used as a touch / pressure sensor and placed in the rear of the smaller tile (built-in tile), which in turn is integrated into the larger tile structure through of a transparent o-ring. The sensor is composed of a PVDF polymer film, in which metallic thin films forming the electrodes of the sensor are deposited. The piezoelectric polymer film produces more than 10 mV per micro-strain, the voltage-varying electrical signal (mV) being acquired from the terminals / electrodes (metal contacts) which is subsequently conveyed to the conditioning and processing unit by conductors copper. Copper wires are attached to the sensor through a " clamping " piezoelectric sensor system will monitor mechanical vibrations in the embedded tile structure, and touches on the surface of the tile face will allow for peaks of electrical voltage in the sensor signal, this signal being transmitted to the conditioning and signal processing system which controls the switch (on / off function) based on the signal obtained. In this way, each command will respond to a switch. The piezoelectric sensor is encapsulated in neutral PH silicone (Standard grade) glue and glued directly to the rear ceramic surface of the built-in tile (smaller tile). The encapsulation and silicone bonding area does not exceed the limits of the embedded tile 8 so as not to cover the transparent o-ring area and acrylic rim where LEDs will be placed to illuminate the perimeter of the built-in tile which will correspond to the area of the switch .

Piezo-Resistive Sensors The touch / pressure sensor to be integrated into the surface of the tile face will be a thin transparent piezo-resistive film. This piezo-resistive film will consist of a thin film of conductive transparent metal oxide such as Aluminium Zinc Oxide (AZO), Indium Tin Oxide (ITO), Indium Zinc Oxide (IZO), Gallium Zinc Oxide (GZO) and other transparent conductive oxides, which will be deposited on the surface of the tile in contact with the user through physical deposition techniques such as: physical vapor deposition - direct current (DC) sputtering techniques, Radio Frequency (RF) sputtering, reactive sputtering and dual magnetron sputtering, reactive evaporation and other physical deposition techniques. This thin transparent conductive film is sized and deposited using masks of the size / shape so as to obtain a resistance value (ohm) at the ends of the film, i.e. at the electrical contacts of the film. The thin film is coated with a transparent polymeric film to ensure an encapsulation to protect the sensor from mechanical wear (shocks, wear and occurrence of cracks in the film) and wear on contact with environmental conditions (humidity and temperature extremes, pressure and pH). The terminals of the sensor (transparent conductive film) are located at the end of the touch / pressure sensing area (in the embedded tile) being placed metal contacts / electrodes on which the transparent film is deposited and thereby establishing contact between the oxide-metallic film and the metallic contacts. Copper conductors are connected to the metal contacts through a " clamping " system. The conductive wires allow to close the resistive circuit consisting of: sensor / conductive film, metallic electrical contacts, system of acquisition and signal processing. The integration of a fully transparent sensor on the face of the tile allows avoiding constraints in the design and manufacture of the ceramic part, since the sensor is processed / deposited after the tile manufacturing process. The transparent sensor allows monitoring of the electrical resistance (ohm) variation signal resulting from mechanical touch / solicitation in the area of the piezo-resistive sensor. The resistance variation of the transparent thin film upon mechanical application at the surface is monitored by the conditioning and processing system, acquiring the resistance variation signal at the metal terminals / contacts located at the end of the embedded tile. The resistance variation within the range determined by the sensor gauge factor will allow the acquisition and processing system to control the switch (on / off function) based on the signal obtained. Thus, at the one touch / mechanical request on the tile face will correspond to an activation of the switch and control of the on / off function.

Electrical system operation mode

Feeding Floor The feed of the electronic system is divided into three distinct sections, which due to their characteristics 10 require specific values of feed voltage (figure 5). The main power of the system comes from the mains, ie an alternating voltage of 230V at a frequency of 50Hz, which is propagated by the system where it is directly used in the load (bulb) and transformed into a direct voltage for the control circuit and the power LEDs.

In order to supply power to the control circuit, since it requires very low values of power for its operation, a rectifier source of half wave without transformer, using resistive components, that allows to convert the alternating voltage of the electric network voltage. This was sized to provide the circuit with a DC voltage of 5V. The presence LED circuit needs a higher value of power for its operation, so a rectified full-wave source without transformer using a capacitive impedance and a bridge rectifier, that allows to convert the alternating voltage of the voltage. This was dimensioned to provide the circuit with a 24 V DC voltage.

Signal acquisition

When a tap is touched on the surface of the minor tile, the piezoelectric sensor present on the other side thereof will react to the mechanical vibrations generated, emitting an electrical signal to the signal conditioning circuit. 11

Signal Conditioning The signal conditioning circuit proceeds to filter the parasitic elements introduced by the mains through a second order high pass filter. Thereafter, the signal is amplified and introduced in a variable hysteresis comparator, which allows touch sensitivity adjustment on the tile. The comparator output is connected to a peak detector circuit that prolongs the acquired voltage level, avoiding both ripple interference, which occurs the pulse generated by the touch, and the response to too fast consecutive tones. The actuation circuit is the last module of the electronics system and it is through it that electrical energy necessary for the activation of the lamp is delivered. It consists of a triac, which has the particularity of conducting current from the moment that its control port is activated through a digital signal. Once the control port is activated, the triac will remain in operation regardless of subsequent values provided that the electric current at its conduction terminals never reaches zero. However, if the logic level is maintained at the control port when the electric current at the drive terminals reaches zero, the triac remains active.

Signal processing The signal processing is carried out by means of a microcontroller, where one of its digital inputs is connected to the output of the peak detector circuit and a digital output controls the actuating module. The microcontroller is by default in standby mode, 12 being activated every lOms (50Hz) by means of a zero-voltage detection circuit of the AC mains voltage, which is connected to the activation pin of the microcontroller.

This signal processing circuit will generate the pulses that allow the actuation circuit to remain active. The operating state diagram can be seen in figure 6. When enabled, the microcontroller will check the status of the peak detector and the current status of the lamp and generate pulses to the triac according to these states. For operation as a switch the following states machine is used: - If the current state is turned off (" OFF ") and the peak detector is at the high logic level, impulses will be generated by the microcontroller every 10 ms, which is equivalent to generating a boost whenever it exits the suspend state. Upon receiving these pulses the triac will drive and the charge will be switched on (" ON "); - If the current state is ON (" ON ") and the peak detector is at the high logic level, the microprocessor will stop generating pulses, which will cause the triac to stop driving when the alternating current travels to its driving terminals for OA, returning to the off state (" OFF "); - If the peak detector is logic low, the current state is maintained.

For dimmer operation, in the case of an illumination with the increasing cycle divided into three phases, the following state machine is verified: - If the current state is switched off (" OFF ") and the peak detector is high logic level, pulses will be generated by the microcontroller every 20 ms, which is equivalent to cyclically generating a pulse when it exits from the suspended state, alternating with no impulse at the next suspension output. Upon receiving these pulses the triac will drive at 20ms intervals (figure 7) and the lamp will be connected at 50% of its intensity (" DIM 50% "); - If the current state is connected to 50% of the intensity (" DIM 50% ") and the peak detector is at the high logic level, the microcontroller will start to generate pulses every 10 ms, ie whenever it leaves the mode. As the triac will receive a pulse with each passing through the zero of the alternating current of its conduction terminals, being in continuous conduction (figure 7). Under these conditions the maximum luminous intensity in the lamp (" DIM 100% ") is obtained; - If the current state is turned on at 100% of the intensity (" DIM 100% ") and the peak detector is at the high logic level, the microcontroller will stop generating pulses, which will cause the triac to stop driving when the alternating current of current running through its conduction terminals is 0A, returning to the off state (" OFF "); - If the peak detector is logic low, the current state is maintained.

Description of Figures

BRIEF DESCRIPTION OF THE DRAWINGS For a more complete understanding of the invention, the following are attached figures which represent preferred embodiments of the invention which, however, are not intended to limit the subject matter of the present invention.

Figure 1: Schematic representation of the invention where (1) represents the inner switch tile, and 14 (2) represents the larger outer tile.

Figure 2: Schematic representation of the invention where (A) represents the outer view of the switch and (B) represents the interior view of the switch where (3) represents a light emitter, (4) represents a sealing ring, and (5) represents a vibration sensor.

Figure 3: Schematic representation of the exterior of the switch element of the switch.

Figure 4: Schematic representation of the electrical modules of the invention.

Figure 5: Schematic representation of the power supply of the invention.

Figure 6: Schematic representation of the electric operation in regulator, dimmer, of the invention.

Figure 7: Schematic representation of the dimmer electronic operation of the invention where (7) represents alternating current, (8) represents the output, control output of the TRIAC microcontroller, for 100% light intensity, (9) represents the TRIAC ON / OFF states, for 100% light intensity, (10) represents the control output of the TRIAC microcontroller for 50% light intensity, (11) represents the ON / OFF states of the TRIAC (12) represents the ON state, 15 (13) represents the OFF state, (14) represents 10 ms, (15) represents 20 ms, and (16) represents a pulse in the output, control output of the TRIAC microcontroller.

The following claims further define preferred embodiments of the present invention.

Lisbon, July 21, 2011 16

Claims (10)

A touch switch characterized in that it comprises: a modular cover plate (1, 2), called a tile, - a touch switch, coupled to said plate (1, 2) in order to activate when it detects a touch in said plate (1, 2). Touch switch according to claim 1, characterized in that said cover plate is divided into two tiles, one inner (1) and one outer (2), and in that it comprises a sealing ring (4) between said tiles, wherein the inner tile, referred to as the switch tile (1), is contained in the outer tile, referred to as the larger tile (2). Touch switch according to the preceding claims, characterized in that said sealing ring (4) is translucent or transparent, and comprises one or more light emitters (3) arranged to illuminate said sealing ring (4). Touch switch according to the preceding claim, characterized in that said light emitters (3) are electrically connected to illuminate said sealing ring as presence signaling. Touch switch according to the preceding claim, characterized in that said light emitters (3) are LEDs. 1 Touch switch according to the preceding claims, characterized in that it comprises a piezoelectric sensor (5) for activating the switch when detecting mechanical vibrations corresponding to a tap on said plate (1,2). Touch switch according to the preceding claims, characterized in that it comprises a conductive transparent thin film resistive sensor arranged to activate the switch when it detects the touch pressure on said plate. Touch switch according to the preceding claims, characterized in that it comprises a dimmer dimmer. A touch switch according to the preceding claim, characterized in that it comprises a touch-switch circuit, connected at 100%, switched off and connected at 50%. A switch system characterized in that it comprises a plurality of switches according to any one of the preceding claims. Lisbon, July 21, 2011 2