KR20110049975A - Input device using inductive sensor - Google Patents

Abstract

PURPOSE: An input device using an inductive sensor is provided to recognize the inductance variation of a coil through key input in a touch operation. CONSTITUTION: An inductive touch sensing apparatus includes an AC(Alternating Current) generator(300), an inductive sensor unit(100) and a control unit(400). The AC generator converts a square wave signal into an AC signal. The inductive sensor unit receives the AC signal, and generates the variation of the inductance for the external pressure. If the AC signal is inputted to the inductive sensor, the control unit senses the variation of the inductance in the inductance sensor.

Description

Inductive touch sensing device {Input device using inductive sensor}

The present invention relates to an inductive touch sensing device, and more particularly, to an inductive touch sensing device using an inductive sensor as an input means for switching various state information displayed on a display panel.

In general, home appliances are provided with a display panel for notifying various operating states and errors.

For example, the display panel 10 of the Kimchi refrigerator may be divided into the display unit 11 and the input unit 15 as shown in FIG. 1, and the display unit 11 may be a liquid crystal display (LCD) or It may be made using a light emitting diode (LED).

In addition, the display unit 11 displays mode information such as upper compartment, middle compartment and lower compartment information of the kimchi refrigerator, temperature state, and temperature control information, and the input unit 15 displays the upper portion of the kimchi refrigerator through a touch sensor. You can change the middle, lower or lower compartment, or adjust the temperature of Kimchi refrigerator.

A conventional touch sensor applied to the input unit 15 may be formed using a capacitive sensor, which is a conductive plate on a substrate (not shown), as shown in FIG. A structure in which a voltage is applied to the conductive plate 21 by arranging the 21 is provided according to the dielectric constant between the hand 30 and the conductive plate 21 when the human hand 30 contacts the conductive plate 21. It works on the principle of detecting parasitic capacitance.

However, when the capacitive sensor 20 is used, a liquid such as water or moisture on the cover surface of the input unit 15 may cause a malfunction due to malfunction of the user. Touching the input unit 15 with a gloved hand did not work.

In addition, the cover of the input unit 15 has a problem that the operation is good only if made of a non-conductive material such as glass (glass), plastic (plastic) or acrylic (acrylic).

An object of the present invention for solving the above problems, even if the liquid or moisture is present on the touch surface because it is recognized as a key input through the change in inductance of the coil when the touch by using the inductive sensor as an input means through the touch It works well and works well even when touching with a hand wearing gloves. Inductive touch sensing that can form the touch surface not only with non-conductive materials but also with conductive materials such as copper, stainless steel, brass or aluminum. It is to provide a device.

Inductive touch sensing device of the present invention for achieving the above object is an AC generator for receiving a square wave signal is converted into an AC signal, and outputs an AC signal, an inductive for generating a change in inductance with respect to external pressure And a control unit for detecting a change in inductance when a change in inductance occurs in the inductive sensor while the sensor unit and the AC signal are input to the inductive sensor unit.

A voltage divider may be connected to the inductive sensor unit.

The controller may detect a change in inductance in the inductive sensor by receiving a voltage value applied across the voltage dividing resistor and comparing it with a preset reference voltage.

The inductive sensor may include a circuit board part, a coil part formed on an upper surface of the circuit board part, a through hole corresponding to the coil part, and a spacer stacked on an upper surface of the circuit board part, an upper plate part stacked on an upper surface of the spacer part, and an upper surface of the upper part of the circuit board part. It may include a cover portion.

The inductance sensor may change inductance of the coil unit by moving the upper plate to the coil unit due to the external pressure.

The cover part may be a conductive material or a non-conductive material.

According to the present invention, since an inductive sensor is used as an input means through a touch, the touch is recognized as a key input through a change in inductance of the coil. Touching with one hand works well, and the touch surface can be formed of a conductive material such as copper, stainless steel, brass, or aluminum as well as non-conductive material, so that the design can be diversified or advanced.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention.

3 is a circuit diagram illustrating an inductive touch sensing device according to an embodiment of the present invention. Inductive touch sensing device according to an embodiment of the present invention, as shown in Figure 3, the oscillator 410 for outputting a square wave signal, the AC generator 300 for receiving a square wave signal is converted into an AC signal, and outputs, When the AC signal is input and the inductance change occurs when the AC signal is input to the inductive sensor unit 100 and the AC signal is input to the inductive sensor unit 100 due to external pressure, it is recognized as a key input. The control unit 400 receives a signal.

The controller 400 preferably uses a microcontroller, and the oscillator 410 may be provided in a form built in the microcontroller, that is, the controller 400.

The AC generator 300 is an RC circuit including a first resistor R1 and a first capacitor C1. The AC generator 300 receives an square wave signal and drives an inductive sensor unit 100 to drive AC according to a time constant of the RC circuit. Output the signal.

The inductive sensor unit 100 may be composed of one or a plurality of inductive sensors 105, in the case of a plurality of inductive sensors 105, a plurality of AC signals input through the switch unit 200 Switch to input to any one of the inductive sensor 105.

Here, the switching unit 200 operates in a multiplexer form and repeatedly switches a plurality of inductive sensors 105 one by one at a very high speed while receiving an AC signal. That is, the switching unit 200 periodically switches a plurality of inductive sensors 105 while repeatedly turning on or off.

Figure 4 is a combined perspective view showing an inductive sensor according to an embodiment of the present invention.

As shown in FIG. 4, the inductive sensor 105 corresponds to the coil part 120 and the coil part 120 which are formed by etching the circuit board part 110 and the upper surface of the circuit board part 110. A spacer 130 forming a through hole 140 and stacked on the upper surface of the circuit board 110, an upper plate 150 stacked on the upper surface of the spacer 130, and a cover 160 stacked on the upper surface of the upper plate 150. Is made of.

The coil part 120 is spirally formed on the upper surface of the circuit board part 110 with a conductive material, and the spacers 130 are stacked to give a gap between the coil part 120 and the upper plate part 150.

Accordingly, the spacer 130 is stacked between the upper plate 150 and the circuit board 110 by allowing the through hole 140 to be placed on the upper surface of the coil unit 120, so that the coil portion 120 is the same as the thickness of the spacer 130. ) And a gap between the top plate 150 is given.

For reference, the thickness of the spacer 130 may be formed to a thickness corresponding to 1% to 3% of the diameter length of the through hole 140, because the spacer 130 must be mechanically rigid and electrically insulated It may be made of a plastic material such as Flame Retardant composition 4 (FR4), Flame Retardant composition 4 (FR2), resin bound paper, or ABS.

The upper plate part 150 is formed of a conductive material, and the cover part 160 corresponds to the outermost part of the inductive sensor 105, and is directly contacted by the user for key input. Accordingly, one surface of the cover portion 160 corresponds to a touch surface for key input, and the upper surface portion 150 is in contact with the other surface.

The cover 160 may be formed of a conductive material such as stainless steel, aluminum, or a non-conductive material such as plastic or wood.

On the other hand, if the cover portion 160 is formed of a conductive material, the cover portion 160 may also serve as the upper plate portion 150 without the need to stack the upper plate portion 150 separately, and if the cover portion 160 is formed of a metal material The cover portion 160 may be aesthetically superior to the non-conductive material.

In addition, a voltage divider R2 is connected in series to the inductive sensor unit 100, and between the inductive sensor unit 100 and the voltage divider resistor R2 to amplify a voltage applied to both ends of the voltage divider resistor R2. Amplification unit 500 is connected.

Therefore, the voltage across the voltage divider R2 is amplified at a ratio corresponding to the amplification degree of the amplifier 500 and output.

On the other hand, the comparison unit 450 for comparing the voltage across the voltage dividing resistor (R2) amplified by the amplifier 500 with a preset reference voltage may be provided, the reference voltage and the divided voltage preset in the comparison unit 450 Compare the voltage across resistor R2. Thus, when the voltage across the voltage dividing resistor R2 is lower or higher than the reference voltage, the control unit 400 outputs a signal corresponding thereto.

For reference, as the distance between the coil unit 120 and the upper plate 150 is closer, the inductance of the coil unit 120 increases, and as the inductance increases, the voltage applied to both ends of the coil unit 120 increases accordingly. do.

When the voltage across the coil unit 120 increases, the magnitude of the voltage applied across the voltage divider R2 is relatively decreased.

Therefore, if the magnitude of the voltage applied across the voltage divider resistor R2 is referred to as a reference voltage, the comparator 450 recognizes a key input when the magnitude of the voltage applied across the voltage divider resistor R2 is lower than the reference voltage. Can output a signal.

Thus, the controller 400 receives a signal indicating that a key has been input from the comparator 450 and outputs a control signal for performing an operation such as changing a mode of a device corresponding to the key input.

Hereinafter, the operation of the inductive touch sensing device will be described.

First, the square wave signal output from the oscillator 410 is converted into an AC signal through the AC generator 300, and applies an AC signal to the inductive sensor 105 through the switching unit 200 that is turned on.

Subsequently, a constant voltage is applied between both ends of the inductive sensor 105 and both ends of the voltage divider resistor R2, and a voltage applied across both of the voltage divider resistor R2 is amplified by the amplifier 500 and then the comparator ( 450).

For example, if the voltage at both ends of the voltage divider resistor R2 is higher than the reference voltage, and there is no key input, and if the voltage is low at the key input state, the voltage applied to both ends of the voltage divider resistor R2 is the reference. When the voltage is greater than the voltage, the comparator 450 outputs a signal that there is no key input.

Subsequently, when an AC signal is applied to the inductive sensor 105 through the switching unit 200 that is turned on, and the user touches the cover unit 160, that is, the touch surface, the pressure is applied to the cover unit 160 and the upper plate unit 150. ) Is biased.

Here, the deflection distance may be a very fine deflection of about 10 microns.

Subsequently, as the gap between the upper plate 150 and the coil unit 120 decreases, the inductance of the coil unit 120 increases, and as the inductance increases, the voltage applied to the coil unit 120 also increases.

Subsequently, when the voltage across the coil unit 120 increases, the voltage across the voltage divider R2 is relatively decreased.

Subsequently, the voltage applied across the voltage divider R2 is amplified by the amplifier 500 and then compared by the comparator 450.

As a result of comparison, when the voltage applied across the voltage divider resistor R2 is lower than the reference voltage, the comparator 450 outputs a signal indicating that there is a key input to the controller 400, and the controller 400 corresponds to a device corresponding to the key input. It outputs a control signal that can be performed such as mode change.

In this way, since the cover unit 160 and the upper plate 150 is deflected to perform the sensing operation, even if there is liquid or moisture on the surface of the cover unit 160 or gloves of any thickness, the sensing operation is not affected.

In the above description, the present invention has been described with reference to preferred embodiments, but the present invention is not necessarily limited thereto, and a person having ordinary skill in the art to which the present invention pertains does not depart from the technical spirit of the present invention. It will be readily appreciated that various substitutions, modifications and variations can be made.

1 is an exemplary view showing a display panel of a kimchi refrigerator,

2 is an exemplary view showing an operating state of a conventional capacitance sensor;

3 is a circuit diagram illustrating an inductive touch sensing device according to an embodiment of the present invention;

Figure 4 is a combined perspective view showing an inductive sensor according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

100: inductive sensor 300: AC generator

400: control unit

Claims (6)

An AC generator for receiving a square wave signal and converting the signal into an AC signal; An inductive sensor unit receiving an AC signal and generating a change in inductance with respect to external pressure; A control unit for detecting a change in inductance when a change in inductance occurs in the inductive sensor while the AC signal is input to the inductive sensor unit Inductive touch sensing device comprising a. The method of claim 1, An inductive touch sensing device, characterized in that the voltage divider is connected to the inductive sensor unit. The method of claim 2, wherein the control unit, An inductive touch sensing device, characterized in that for sensing the change in inductance in the inductive sensor by receiving a voltage value applied across the voltage divider resistance and compared with a predetermined reference voltage. The method of claim 1, wherein the inductive sensor, A circuit board part; A coil part formed on an upper surface of the circuit board part; A spacer formed with a through hole corresponding to the coil part and stacked on an upper surface of the circuit board part; An upper plate portion laminated on the spacer Cover part laminated on the upper surface Inductive touch sensing device comprising a. The method of claim 4, wherein the inductance sensor, Inductive touch sensing device, characterized in that the inductance of the coil portion is changed by the upper plate portion is deflected by the external pressure to move to the coil portion. The method of claim 4, wherein Inductive touch sensing device, characterized in that the cover portion is a conductive material or a non-conductive material.

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