KR101764735B1 - Driving circuit for leak detecting sensor - Google Patents

Abstract

The present invention relates to a driving circuit of a leak detecting sensor. A leak status is able to be sensed, and an amount of leaks is able to be grasped. Moreover, a breakdown of a sensor is able to be determined. The driving circuit comprises: a charging and discharging capacitor (C) connected between one side of a copper wire (11a) of a first cable (11) to form a leak detection sensor (10) and one side of a copper wire (12a) of a second cable (12); a discharging resistor (R1) connected between the other side of the copper wire (11a) of the first cable (11) and the other side of the copper wire (21a) of the second cable (12); and a control unit (100) to apply a constant direct current voltage in a pulse state through a switching device (S) to the other side of the copper wire (11a) of the first cable (11) to make the charging and discharging capacitor (C) perform charging and discharging operations, and detecting a leak and the amount of leaks by checking a discharging time.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a leakage detection circuit,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a driving circuit of a leakage sensor, and more particularly, to a driving circuit of a leakage sensor, which can detect the leakage amount as well as detect the leakage amount, .

BACKGROUND ART [0002] Generally, a leak detection sensor is a sensor for detecting leakage and leaking, and various types such as a film type sensor using a cable or an electrode type pattern are disclosed.

The driving circuit and the operation of such a leakage sensor will be described with reference to Figs. 1 and 2. Fig.

The leak sensor 10 comprises a cable sensor composed of a first cable 11 and a second cable 12 and a first electrode 14 and a second electrode 15 printed on the film 13 And a film-type sensor.

For the sake of convenience, the cable sensor is explained as an example here. A direct current 5 V voltage is applied to the copper wire 11a of the first cable 11 through the resistor R and a copper wire 12a of the second cable 12 is applied to the copper wire 11a of the first cable 11. [ Is grounded.

When the water is not detected, the leakage detection sensor 10 outputs a DC 5V voltage to the output terminal OUT through the load resistor R in normal operation.

However, when water W is detected between the first cable 11 and the second cable 12 as shown in FIG. 2, the resistance of the water W between the first cable 11 and the second cable 12 The voltage applied to the output terminal OUT changes, and when the value reaches the set range, it is determined that a leak has occurred.

That is, the conventional leak detection sensor simply detects leakage or not.

Accordingly, the inventor of the present invention has been studying a leak detection sensor to detect a leakage amount as well as a leakage amount and to automatically drive the drying heat source device installed in the cable after the leak detection to evaporate and dry all the remaining water at the time of leak detection The present invention has been described below.

Open Patent Publication No. 10-2014-0059313, Registered Patent Publication No. 10-1326923, Registered Patent Publication No. 10-1578060

SUMMARY OF THE INVENTION It is an object of the present invention to provide a driving circuit of a leakage sensor capable of detecting the leakage amount as well as detecting the leakage amount and determining whether the sensor is faulty have.

It is another object of the present invention to provide a driving circuit of a leakage sensor that automatically drives a heater to detect a leakage of water to dry the sensor to increase measurement accuracy.

To achieve these and other advantages and in accordance with the purpose of the present invention, as embodied and broadly described herein, there is provided a water leakage sensor comprising: a charge / discharge capacitor connected between one side of a copper wire of a first cable and one side of a copper wire; A discharge resistor connected between the other side of the copper wire of the first cable and the other side of the copper wire of the second cable; A constant DC voltage is applied in a pulse form to the other side of the first cable through a switching element so that the charge and discharge capacitor performs charging and discharging operations and then the discharge time is checked to detect the amount of leakage and leakage And a control unit for controlling the control unit.

According to another aspect of the present invention, the control unit may include an A / D converter for converting an analog voltage applied to the other side of the first cable into a digital signal and inputting the digital signal to the MCU; An MCU for generating a switching signal for on / off interrupting of a switching element to a switching signal generating unit, for analyzing a digital signal inputted through the A / D converting unit to check the discharging time and calculating the amount of leakage corresponding to the discharging time, Wow; A switching signal generator for controlling the switching element to be turned on and off so that a DC voltage of 5 V is applied to or cut off from the charge / discharge capacitor; And an interface unit for transmitting leakage information and leakage amount information detected through the MCU to a network.

According to the present invention, the MCU detects a voltage value inputted through the A / D conversion unit. When the voltage value is maintained at 5V for a predetermined time, the MCU determines that the charging / discharging capacitor is broken or broken, To a network via a network.

According to another aspect of the present invention, the control unit further includes a heater driving unit installed in the leakage sensor to drive heater means for drying and evaporating moisture remaining at the time of leakage detection.

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As described above, the present invention provides an advantage that the amount of leakage can be detected as well as the detection of the leakage state, and the failure of the sensor can also be determined.

In addition, the present invention provides an advantage that the sensor is automatically driven after the leakage of water to dry the sensor to increase the measurement accuracy.

1 is a configuration diagram of a conventional leak sensor and a drive circuit,
FIG. 2 is a block diagram of the locking operation of FIG. 1,
3 is a configuration diagram of a leakage sensor driver circuit according to the present invention,
4 is a detailed circuit block diagram of a control unit according to the present invention;
FIG. 5 is a block diagram of the operation of the leakage detection sensor according to the present invention.
FIG. 6 is an output waveform diagram of the leak sensor drive circuit according to the present invention,
7 is a circuit block diagram of a control unit according to another embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

3 is a configuration diagram of a leakage sensor driver circuit according to the present invention.

As shown in the drawing, in the driving circuit of the leak sensor of the present invention,

A charge / discharge capacitor C connected between one side of the copper line 11a of the first cable 11 constituting the leak sensor 10 and one side of the copper line 12a of the second cable 12; A discharge resistor R1 connected between the other side of the copper wire 11a of the first cable 11 and the other side of the copper wire 21a of the second cable 12; A constant DC voltage is applied in the form of a pulse through the switching element S to the other side of the copper wire 11a of the first cable 11 so that the charge and discharge capacitor C performs charging and discharging operations, And a controller (100) for checking the amount of water leakage and leakage by checking the discharge time.

Here, for convenience, the cable sensor is described as an example, but the same applies to the sensors of the electrode patterns 14 and 15 of Fig.

The charging / discharging capacitor C is charged when the switching element S is turned on and a 5V DC voltage is applied. When the switching element S is turned off and the DC voltage of 5V is cut off, Lt; / RTI >

The controller 100 includes an A / D converter 110, an MCU 120, a switching signal generator 130, and an interface unit 140 as shown in FIG.

The A / D converter 110 converts an analog voltage applied to the other side discharge resistor R1 of the first cable 11 into a digital signal and inputs the digital signal to the MCU 120.

The MCU 120 generates a switching signal for switching on and off of the switching element S to the switching signal generator 120 and analyzes the digital signal input through the A / D converter 110 The discharge time is checked and the amount of leakage corresponding to the discharge time is calculated.

The amount of the leakage increases as the discharge time is shorter.

Also, the MCU 120 transmits the detected leak information and leak amount information to the network via the interface unit 140.
Here, the network is a communication network connected between a driving circuit of the leakage detection sensor of the present invention and a central control room, which is an external device for remotely controlling leak detection, and transmits the sensed information to an external device through the network.

The switching signal generator 130 controls the switching device S on and off so that a DC voltage of 5 V is applied to or blocked from the charge / discharge capacitor C.

The operation of the present invention thus configured will be described with reference to the output waveform diagram of Fig.

First, when the power is applied and the ON signal and the OFF signal are output from the switching signal generator 130 of the controller 100 at intervals as shown in FIG. 6A, the switching elements S Is turned on and off accordingly.

When the switching device S is turned on at the time point T1, the DC power source 5V is applied through the first cable 11 and the second cable 12 so that the capacitor C is rapidly charged, And is maintained.

When the switching element S is turned off at the time T2 and the supply of the DC power is interrupted, the voltage charged in the capacitor C starts to discharge through the discharging resistor R1, and at time T3 The voltage across the capacitor C becomes 0V.

Thereafter, when the power is supplied at the time T4, the operation of charging the capacitor C is repeated continuously.

That is, as shown in (a) of FIG. 6, charging (T1 to T2) and discharging (T2) of the charging / discharging capacitor C are performed so as to correspond to a constant power supply (ON: T1 to T2) To T3 are performed in a constant pattern, and a certain time (T2 to T3) is required for discharging.

5, when the water W is detected between the first cable 11 and the second cable 12, the water (W) W) acts as a kind of resistance. The water resistance RW corresponding to the water W is connected in parallel with the discharge resistor R1 to increase the total resistance value.

Therefore, the charge / discharge capacitor C is discharged more quickly, and the discharge time is further shortened.

The switching element S is turned off at the time point T2 after the charging / discharging capacitor C is turned on and the supply of the DC power is interrupted as shown in FIG. 6 (b) The voltage is discharged by the total resistance ((1 / R1) + (1 / RW)) in which the discharging resistor R1 and the water resistance RW are summed to shorten the discharging times T2 to T5.

That is, the total resistance is increased proportionally depending on the size of the water resistance RW, so that the discharge time becomes short in proportion to the amount of the water resistance which is the water resistance RW.

The voltage discharged through the charge / discharge capacitor C is input to the MCU 120 through the A / D conversion unit 110 of the control unit 100. The MCU 120 detects the discharge time, Calculates the leakage amount using the data, and transmits the calculated leakage information to the network via the interface unit 140.

Also, the MCU 120 detects the voltage value input through the A / D converter 110, and when the input voltage is maintained at 5V so that a predetermined time elapses when the power source 5V is applied, (Charging error) or disconnection error, and transmits this information to the network via the interface unit 140

According to the present invention, the controller 100 further includes a heater driving unit 150 and a battery unit 160 as shown in FIG.

The heater driving unit 150 is installed in the water leakage sensor 10 including the first cable 11 and the second cable 12 and drives the heater means for drying and evaporating moisture remaining at the time of water leakage. After detecting the water leakage, the heater unit is driven for a predetermined time according to the control of the MCU 120 as needed, thereby drying the moisture adhering to the water leakage sensor 10.

When the power supply to the controller 100 is cut off, the battery unit 160 automatically senses the power supply and temporarily drives the battery unit 140 through the power supply of the battery unit 140.

10: leak sensor 11: first cable
12: second cable C: charge / discharge capacitor
R1: discharge resistance S: switching element
100: control unit 110: A / D conversion unit
120: MCU 130: Switching signal generator
140: interface unit 150: heater driving unit

Claims (5)

A charge / discharge capacitor C connected between one side of the copper line 11a of the first cable 11 constituting the leak sensor 10 and one side of the copper line 12a of the second cable 12;
A discharge resistor R1 connected between the other side of the copper wire 11a of the first cable 11 and the other side of the copper wire 21a of the second cable 12; And
A constant DC voltage is applied in the form of a pulse through the switching element S to the other side of the copper wire 11a of the first cable 11 so that the charge and discharge capacitor C performs charging and discharging operations, And a controller (100) for detecting the amount of water leakage and leakage by checking the discharge time.
The method according to claim 1,
The control unit 100 includes an A / D converter 110 for converting an analog voltage applied to the other side discharge resistor R1 of the first cable 11 into a digital signal and inputting the digital signal to the MCU 120;
The switching signal generating unit 130 generates a switching signal for on / off interrupting of the switching element S, analyzes the digital signal input through the A / D converting unit 110 to check the discharging time, An MCU 120 for calculating the amount of leakage corresponding to the time;
A switching signal generator 130 for controlling the switching element S to be turned on and off so that a DC voltage of 5 V is applied to or cut off from the charge / discharge capacitor C; And
And an interface unit (140) for transmitting leakage information and leakage amount information detected through the MCU (120) to a network.
The method of claim 2,
The MCU 120 detects a voltage value inputted through the A / D converter 110 and determines that the charge / discharge capacitor C is broken or disconnected if the voltage is maintained at 5V for a predetermined time And transmits it to the network via the interface unit (140).
The method according to claim 1,
The controller (100) further includes a heater driving unit (150) installed in the water leakage sensor (10) for driving the heater means for drying and evaporating the moisture remaining in the water leakage sensing operation. .
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