JPH0629824B2 - Leak detection device - Google Patents

Description

Description: (a) Field of Industrial Application The present invention relates to a liquid leakage detection device for detecting leakage of non-insulating liquid such as water or a mixed liquid of water and oil.

(b) Conventional technology For example, in the underfloor of a computer room where many cables are laid, or a storage room for articles that dislike moisture,
There must be no liquid leakage, and the liquid leakage must be detected early to prevent malfunction of the device and damage to articles.

2. Description of the Related Art Conventionally, as a device for detecting liquid leakage, there has been proposed a device including a detection line whose electric characteristic changes due to adhesion of a non-insulating liquid and a detection circuit which detects a change in electric characteristic of the detection line.

(c) Problems to be Solved by the Invention Such a liquid leakage detection device is originally provided as a safety device, and the frequency of occurrence is low, but if a liquid leakage state occurs once, it causes a great deal of damage. It has the characteristic that it is used for potentially dangerous applications. Therefore, the device is required to have high reliability.

Conventionally, in order to maintain the reliability of the device, periodic maintenance inspection is performed, but if no defect is found in the device during this maintenance inspection, the liquid leakage will actually occur before the leakage detection. There could have been a situation in which a device failure was noticed.

An object of the present invention is to provide a liquid leakage detection device which, so to speak, is provided with a self-diagnosis function so that a malfunction of the device can always be found in a normal operating state.

(d) Means for Solving the Problems The present invention provides a leak detection sensor whose electric resistance changes due to the presence of a non-insulating liquid, and a voltage conversion circuit which converts the electric resistance of the leak detection sensor into a DC voltage. A liquid leak including A / D conversion means for converting the output voltage of the voltage conversion circuit into digital data, and a liquid leakage determination means for determining the presence or absence of liquid leakage based on the output data of the A / D conversion means. In the detection device, a dummy resistor having a constant resistance value connected to the voltage conversion circuit, first switching means for intermittently connecting the dummy resistor to the voltage conversion circuit instead of the liquid leakage detection sensor, When the voltage conversion circuit is connected to the dummy resistor, voltage conversion abnormality determination means for determining normality / abnormality of the voltage conversion circuit based on output data output from the A / D conversion means based on the dummy conversion resistor, and a constant value for diagnosis. A diagnostic voltage generating circuit for generating a pressure, a second switching means for intermittently connecting the diagnostic voltage generating circuit to the A / D converting means instead of the voltage converting circuit, and the A / D converting means. Is connected to the diagnostic voltage generating circuit, the A / D conversion abnormality determining means for determining normality / abnormality of the A / D converting means based on the output data thereof is provided.

(e) Action The configuration of the present invention is shown in FIG. In the figure, the leak detection sensor is, for example, a detection line having two electrode conductors.
The liquid leakage detection sensor is connected to the voltage conversion circuit via the first switching means. The voltage conversion circuit converts the electric resistance of the liquid leakage detection sensor into a DC voltage and outputs it as an output voltage. This output voltage is input to the A / D conversion means via the second switching means. The A / D conversion means converts the output voltage into digital data and outputs it as output data. Based on this output data, the liquid leakage determination means determines the presence or absence of liquid leakage.

The liquid leakage detection device executes the above operation as a normal operation. During this normal operation, the first switching means intermittently connects the dummy resistor to the voltage conversion circuit. Since the resistance value of the dummy resistor is a known constant resistance value, the output voltage to be output by the voltage conversion circuit is also known in advance. Based on this output voltage, the voltage conversion abnormality determination means determines whether the digital data (output data) output by the A / D conversion means is normal. This makes it possible to determine whether or not the voltage conversion circuit is normal during normal operation.

Further, during the normal operation, the second switching means intermittently connects the diagnostic voltage generating circuit to the A / D converting means. Since the voltage generated by the diagnostic voltage generating circuit is a known constant voltage, the output data to be output by the A / D conversion means is also known in advance. The A / D conversion abnormality determining means determines whether or not the output data is normal. This makes it possible to determine whether or not the A / D conversion unit is normal during normal operation.

(f) Embodiments A block diagram of a water leakage detection device that is an embodiment of the present invention is shown in FIG. 2 (in the embodiments, "leakage" is taken as an example).

In the figure, a portion 20 within a chain double-dashed line is a control unit, to which a display unit 21 and a relay unit 22 are connected. In the control unit 20, 10 is AC200V or AC100
This is a transformer to which a commercial power source of V is input, and the constant voltage circuit 11 rectifies and smoothes one secondary side output of the transformer 10 and makes it a constant voltage to output a power source voltage of 5 V as a power source voltage of a theoretical circuit system. . The sensor circuit 12 is a circuit corresponding to the voltage conversion circuit according to the present invention, and has terminals S1 to S.
A DC voltage corresponding to the resistance of the water leak detection sensor connected to 8 is generated. The dummy sensor circuit 13 is a resistance circuit connected instead of the water leak detection sensor. The reference voltage generation circuit 14 is a circuit that generates three types of predetermined constant voltages. The dummy sensor circuit 13, the sensor circuit 12, and the reference voltage generation circuit 14 correspond to the diagnostic voltage generation circuit according to the present invention. The analog switch 15 is A based on the instruction data from the CPU 17.
Any one of the input voltage signals 1 to A12 is output to the A / D converter 16. A / D converter 16 is CP
Along with U17, it corresponds to the A / D conversion means according to the present invention, and is composed of a D / A converter and a comparator.
Successive approximation type A / D conversion is performed by the processing of the PU 17. The CPU 17 is composed of a one-chip microcomputer with a built-in ROM and RAM, and executes the program previously written in the ROM to execute the analog switch 1
5, inputs and outputs signals to and from the A / D converter 16, the relay drive circuit 18, the display signal drive circuit 19, and the like. The relay drive circuit 18 is composed of two relays and a circuit for driving the same, and outputs from the terminal RRC whether or not any of the water leakage detection sensors connected to the terminals S1 to S8 is in the water leakage state, and the terminal S1. It is output from the terminal RDC whether or not any of the water leak detection sensors connected to S8 is in a disconnection state. The display signal drive circuit 19 outputs a display signal and a relay control signal to the display unit 21 and the relay unit 22 which are connected to the outside. The display unit 21
The output terminal of the power supply voltage to the relay unit 22 and other input / output terminals of control signals are omitted.

An external plan view of the display unit 21 shown in FIG. 2 is shown in FIG. In the figure, the water leakage display section and the disconnection display section are respectively 8 as indicated by the numbers 1 to 8.
This is a display unit composed of individual LEDs, and the numbers 1 to 8 correspond to the numbers of the water leakage detection sensors connected to S1 to S8 shown in FIG. The power source display section displays the energized state of the commercial power source. The reset switch is a switch that resets the entire device, and by this operation, the device starts execution from the initial routine of the program. The buzzer switch is a switch for selecting whether to generate or prohibit a buzzer sound when a water leakage state or a wire breakage state is detected.

FIG. 4 shows the sensor circuit 12 shown in FIG. 2 and circuits such as a water leak detection sensor connected thereto. As shown in the figure, the terminals S1 to S8 are connected to the detection line SL and the terminating resistor R, respectively.
o is connected. Reference numeral 13 denotes a resistor which constitutes the above-mentioned dummy sensor circuit, and terminals S1 to S8 and this dummy sensor circuit 13 are respectively provided with similar voltage conversion circuits as shown in the drawing. Taking the voltage conversion circuit at the top as an example, the AC voltage generated on the secondary side of the transformer 10 energizes via R1, SL, Ro, and R2. At that time, the power supply voltage is stabilized by the Zener diodes ZD1 and ZD2. ZNR also removes noise generated between terminals. The drop voltage of the resistor R2 is rectified and smoothed by the diode D1 and the capacitor C1, and the resistors R3 and R4 are
Is divided by. Therefore, the output voltage of the voltage conversion circuit becomes a constant voltage when not in the water leak state, and rises in accordance with the decrease in the inter-conductor resistance of the detection line SL when the water leak state occurs. In addition, when the detection line SL is broken, the terminals S1 to S1
When the connection with S8 is disconnected, a closed loop of current is not formed, so that the output voltage of the voltage conversion circuit becomes substantially zero.
Since the resistance value of the dummy sensor circuit 13 is the same as the termination resistance of each detection line (for example, 20 KΩ), the output voltage of the voltage conversion circuit is always a constant voltage.

A circuit diagram of the relay drive circuit 18, the display signal drive circuit 19 and the relay unit 22 shown in FIG.
Shown in the figure. In the figure, P10 to P17 and P24 and P25 of the CPU 17 are a part of the input / output ports and are used here as output ports. A buffer circuit 30 is connected to P10 to P17, and its output is pulled up by eight resistors R5. An AND circuit (negative logic OR circuit) is connected to the output of the buffer 30 by eight diodes D2 and a resistor R6, and the output is input to the D terminals of the D flip-flops 31 and 32. Clock signals are applied to the flip-flops 31 and 32 from the CPU ports P24 and P25, respectively. The Q output of the flip-flop 31 is connected through the gate 33 to the transistor Q1 which drives the common leak relay Ry9. Further, the transistor Q2 for driving the common disconnection relay Ry10 is connected to the Q output of the flip-flop 32 via the gate 34. The diode D is provided in the flip-flops 31 and 32.
An OR circuit composed of 3, D4 and a resistor R7 is connected. An oscillating circuit 35 outputs a rectangular wave signal when the output of the OR circuit is at "H" level. The transistor Q3 drives the piezoelectric buzzer BZ by the rectangular wave signal output from 35.

In the relay unit 22 shown in the chain double-dashed line, 36 is a short pin for selecting whether to operate this relay unit when a water leakage state is detected or when a disconnection state is detected. If it is connected, it will operate at the time of detecting the water leakage state, and if it is connected between b and c, it will operate at the time of detecting the disconnection state. A transistor circuit including a noise prevention capacitor C2 and transistors Q6 and Q7 is connected to the c terminal of the short pin 36. 37 is an up edge trigger D-type flip-flop array, 38 is a photocoupler array, 39 is a driver array for driving a relay, 40 is an LED array for confirming the operation of the relays Ry1 to Ry8, and Ry1 to Ry8 are in a leaked state or a broken state, respectively. Is a relay that outputs.

Although the display unit 21 shown in FIG. 2 is not shown in FIG. 5, the output terminal P of the buffer circuit 30 is not shown.
16 L's by the signals for 8 lines output from 10 'to P17' and the water leakage / disconnection selection signals output from the output terminals of the transistors Q4 and Q5 and P24 'and P25'.
The ED (see FIG. 3) is dynamically lit.

6 and 7 show examples of waveforms output from the ports P10 to P17 and P24 and P25 of the CPU 17 shown in FIG. As shown in FIG. 6 (A), P
24 and P25 alternately output the "L" level selection signal, and P10 to P17 alternately output the signal for the water leak display and the signal for the disconnection display. Therefore, when neither sensor is in the water leak state or the wire breakage state, P
10 to P17 remain at the “H” level, and none of the LEDs of the display unit are turned on.

As shown in FIG. 6 (B), when any of P10 to P17 is at "L" level, when P24 or P25 falls, the corresponding individual relay is latched. After that, when any of P10 to P17 is at the "L" level, when P24 or P25 rises, the common relay P
Buzzer BZ with y9 or Py10 latched
Is driven. That is, referring to FIG. 5, in the case where the short pin 36 is connected between a and c and P24 falls, Q4 and Q6 are turned on and Q7 is turned off. As a result, the clock input of each flip-flop of the D-type flip-flop array 37 rises, and the output state of the buffer 30 is latched by the D-type flip-flop array 37. For example, CP
If only port P10 of U is at "L" level, D
Only the type flip-flop 37-1 is in the reset state, and the other flip-flops are in the set state. Therefore, the photocoupler 38-1 is turned off, the output of the inverter 39-1 becomes "L" level, and the confirmation LED 40-1 is turned on.
The individual relay Ry1 is turned on. All the other confirmation LEDs and the individual relays are turned off.

Then, when the port P24 of the CPU rises, the D-type flip-flop 31 is triggered to latch the output state of the negative logic OR circuit composed of R6 and D2. In the above example, the flip-flop 31 is in the reset state, and the transistor Q1 turns on the common leak relay Ry9. At the same time, the output of the OR circuit composed of D3, D4 and R7 becomes "H" level, and the output of the oscillation circuit 35 causes the transistor Q3 to drive the buzzer BZ.

FIG. 7 shows an example of control by output signals from the CPU ports P10 to P17 and P24 / P25. Here, the example of (1) is the same as that of FIG. 6 (B), in which the LED of the display unit is turned on during the selection signal “L”, the individual relays are latched at the fall of the selection signal, and at the rise. Latch the buzzer with the common relay. In the example of (2), the selection signal is made to fall before outputting the data signal from P10 to P17, and the selection signal is made to rise after the output of the data signal is finished so that the LED of the display unit
This is an example of lighting only. (3) is an example in which the individual relays are latched by lowering the selection signal during the output of the data signal, and the common relay is not latched by raising the selection signal after the output of the data signal is completed. (4) is an example in which the common relay and the buzzer are latched by raising the selection signal during the output of the data signal without lowering the selection signal and latching the individual relay before outputting the data signal.

In this way, depending on the signal corresponding to the sensor number output from the ports P10 to P17 of the CPU and the water leak / disconnection selection signal output from the ports P24 and P25, the LED of the display unit and the individual relay R in the relay unit 22.
It is possible to selectively drive y1 to Ry8 and the common relays Ry9 and Ry10 in the control unit.

Now, the processing procedure of the CPU will be described.

FIG. 8 shows the processing procedure of the main routine of the CPU, and FIG. 9 shows the processing procedure of some subroutines.

As shown in FIG. 8 (A), when the power is turned on or the reset switch is operated, the contents of the RAM are first initialized, and whether the RAM operates normally is checked by writing and reading specific data (n
1). If the RAM is not normal, the LED of the disconnection display portion of the display unit blinks a predetermined error code to display that a memory error has occurred (n2 → n3). If there is no abnormality in the RAM, the operation of the display unit is confirmed by sequentially turning on the LEDs of the display unit (n4). Then, read the status of the mode switch (this is connected to the input / output port of the CPU and can be read by the CPU), and if the normal mode other than the test mode is set, check the status of the connected leak detection sensor. The number is read by the sensor number setting switch (which is, for example, a rotary type DIP switch and is connected to the input / output port of the CPU), and it is checked whether it is an appropriate value of 1 to 8 (n6). When the impossible value is set, a sensor number setting error is displayed by blinking a predetermined error code on the LED of the disconnection display portion of the display unit (n7 → n8). If the setting of the number of sensors is OK, thereafter, water leakage and disconnection are sequentially detected. First, the initial value 10 is set to the number SWN to be selected of the analog switch 15 shown in FIG. 2, and the flag FF1 is set (n9 → n10 → n11). (Flag FF1
Is a flag for storing that the setting of the analog switch number is completed. After that, the analog switch having the set analog switch number is selected, A / D conversion is performed, and voltage data X is obtained (n12 → n13). Then, the voltage data corresponding to the analog switch number SWN is compared. Since SWN = 10 at first, it is determined at n15 whether the difference between the voltage data X and the reference value V ₁₀ stored in the ROM of the CPU 17 in advance is within a certain value. When the voltage data X deviates from the reference voltage V ₁₀ by a certain value or more, the LED of the disconnection display portion of the display unit
A predetermined error code is displayed blinking on (n16). If the value of voltage data X is normal, analog switch number SW
N is incremented and the input voltage data indicated by that number is checked (n17 → n18 → n5 → ...
・). That is, if SWN = 11, it is determined whether the input voltage data is close to the second reference voltage (n20 → n21), and if SWN = 12, the input voltage data is close to the third reference voltage. It is determined whether or not (n22 → n23). If there is a deviation of a certain value or more, an error display is similarly performed (n24, n25).

If the three reference voltages are A / D converted normally, the A / D converter is regarded as normal, and then the analog switch number SWN is set to 9 (n19), and the dummy sensor circuit is connected. Check the output voltage of the voltage conversion circuit. That is, in n27, it is determined whether or not the deviation between the input voltage data X and the reference voltage V ₉ is within a certain range. If it exceeds a certain range, it is considered that the sensor circuit 12 shown in FIG. 2 is not operating normally and an error is displayed (n28). This is, for example, the sensor circuit 12
The cause is that the AC power supply voltage to is abnormal.

If the input voltage from the dummy sensor circuit is normal, then the analog switch number SWN is set to 1 (n29),
After that, the input voltage data obtained by the actual water leak detection sensor is checked. That is, it is determined at n30 whether the input voltage data X is less than the reference value Vd. If it is less than the above, it is considered that the water leak detection sensor is broken, and the corresponding LED of the breakage display section of the display unit is turned on, and if the relay unit is set to the breakage output side by the shorting pin, the corresponding The individual relay to be turned on is latched, and further the common disconnection relay and the buzzer are latched (n31). Further, at n34, it is determined whether the input voltage data X is a value exceeding the reference value Vr. When the reference value is exceeded, it is considered that the water leak detection sensor is in a water leak state, the corresponding LED of the water leak display section of the display unit is turned on, and the relay unit is set to the water leak output side by the short pin. If so, the corresponding individual relay is latched, and further the common leak relay and buzzer are latched (n3
5). These checks the analog switch number SWN
SWN is sequentially incremented until n reaches a preset number of sensors (n32 → n33 → n5 →.
・ ・). After checking the input voltage data for all water leak detection sensors, analog switch number SWN
Is set to 10 (n36), and the process returns to the check of the reference voltage.

The above process is repeated. At this time, the analog switch completes a cycle of 20 msec.

The analog switches 15 and n19, n12, n26 correspond to the first switching means of the present invention, and n27 corresponds to the voltage conversion abnormality determining means of the present invention.

Also, the analog switches 15 and n10, n12, n
14, n20, n22, n17 and n18 correspond to the second switching means of the present invention, and n15, n21 and n23 correspond to the A / D conversion abnormality determining means of the present invention.

When the mode switch is set to test mode,
The processing shown in FIG. 8 (C) is performed. First, the value of the sensor number setting switch is read (n40). The sensor number setting switch in the test mode is used to set the test number and performs various tests according to the value SN. SN =
If 0, D / A converter test is performed (n41 → n
42). This repeatedly outputs data that changes sequentially to the D / A converter provided in the A / D converter 16 shown in FIG. Thus, the function test of the D / A converter is performed by measuring the output waveform of the D / A converter.

If SN is 1 to 8, the input voltage by the water leak detection sensor indicated by the number is displayed on the display unit together with the sensor number (n43 → n44). If SN = 9, the input voltage from the dummy sensor is displayed together with the normal voltage value (n45 → n46). If SN is 10 to 12, the input reference voltage and the normal voltage value are compared and displayed (n47 → n48). If SN = 13, each LED of the water leakage display section of the display unit is sequentially turned on and the water leakage common relay is latched (n49 →
n50). If SN = 14, the LEDs in the disconnection display portion of the display unit are sequentially turned on and the disconnection common relay is latched (n51 → n52). SN = 1
If it is 5, the individual relays of the relay unit are sequentially latched (n53).

FIG. 9 (A) shows n44, n46, in FIG. 8 (C).
The processing procedure shown in n48 is shown in FIG.
The processing procedures of n50, n52, and n53 in FIG.

As shown in FIG. 9 (A), in the sensor voltage test, first, the LED of the SNth water leakage display section indicated by the value of the sensor number setting switch is turned on (n60). Then, the SNth sensor is selected and the input voltage is A / D converted (n61 →
n62 → n63). Further, the input voltage data is displayed in binary on the LED of the disconnection display portion of the display unit (n64). Thereby, the sensor output voltage is displayed together with the sensor number under test.

In the dummy sensor voltage test, the design normal voltage is displayed in binary on the LED of the water leakage display section of the display unit (n65), and the sensor output voltage of the dummy sensor is displayed in binary on the LED of the disconnection display section of the display unit. It is displayed (n61 to n64). This compares the normal dummy sensor output voltage with the actual output voltage. In the case of the reference voltage test, the design normal voltage value is displayed in binary on the LED of the water leakage display section of the display unit, and the voltage data of the actual reference voltage indicated by SN is displayed on the LE of the display unit disconnection display section.
It is displayed in D in binary (n61 to n64). As a result, the normal reference voltage and the actually read reference voltage are compared and displayed. In the leak LED and common relay test, as shown in FIG. 9 (B), first, an initial value 1 is set as the LED number of the leak indicator of the display unit (n70), and the Nth LED of the leak indicator is set. It is lit for 0.7 seconds (n71 → n72). Thereafter, the value of n is sequentially incremented until n = 8, and the same processing is repeated (n73 → n74 → n71). As a result, the LEDs of the water leakage display section of the display unit are sequentially turned on and the water leakage common relay is latched.

In the disconnection LED / common relay test, the processing shown in FIG. 9 (C) is performed. The difference from the processing shown in FIG. 9B is n
The only difference is that the LED of the disconnection display section of the display unit is turned on at 81, and the LEDs of the disconnection display section of the display unit are sequentially turned on by the same processing as the processing shown in FIG. Latch the relay.

In the individual relay test, the processing shown in FIG. 9 (D) is performed.
The difference from the process shown in FIG. 9 (B) is that each individual relay of the relay unit is turned on at n91, and by performing the same process as the process shown in FIG. 9 (B), the relay unit Sequentially turn on each individual relay.

In the embodiment, the voltage conversion circuit is provided corresponding to each of the water leak detection sensor and the dummy sensor circuit connected as the sensor circuit 12. However, for example, a single voltage conversion circuit is used, and a plurality of water leak detections are provided at its input. The sensor and the dummy sensor circuit (dummy resistance) may be sequentially switched and connected.

(g) Effect of the Invention As described above, according to the present invention, the operating state of the device is diagnosed by reading the diagnostic voltage at the time of normal liquid leakage detection and determining whether the value is normal or not. Therefore, even if you do not perform regular maintenance inspection work,
The soundness of the device can be confirmed under normal use conditions. As a result, the inconvenience of noticing a failure of the liquid leakage detection device after the liquid leakage actually occurs does not occur.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration example of the present invention. FIG. 2 is a block diagram of a water leak detection device according to an embodiment of the present invention, and FIG. 3 is an external plan view of a display unit of the device. FIG. 4 is a circuit diagram of the sensor circuit 12 shown in FIG. 2 and its peripheral portion. FIG. 5 is a circuit diagram of the blocks 17, 18, 19 and 22 shown in FIG. Sixth
7A and 7B and FIG. 7 are waveform diagrams of signals for the relay drive circuit 18, the display signal drive circuit 19, the display unit 21 and the relay unit 22 shown in FIG. 8A to 8C and 9A to 9D are flowcharts showing the processing procedure of the CPU. 12 ... Sensor circuit (voltage conversion circuit), 13 ... Dummy sensor circuit (dummy resistor), 14 ... Reference voltage generation circuit, (12 + 13 + 14) ... Diagnostic voltage generation circuit, Ro ... Termination resistor, SL ... Detection line, (Ro + SL) ... Leakage detection sensor, Ry1-Ry8 ... Individual relay, Ry9 ... Leakage common relay, Ry10 ... Disconnection common relay, BZ ... Piezoelectric buzzer.

Claims (1)

[Claims] 1. A leak detection sensor whose electric resistance changes due to the presence of a non-insulating liquid, a voltage conversion circuit for converting the electric resistance of this leak detection sensor into a DC voltage, and an output voltage of this voltage conversion circuit. A leak detecting device comprising A / D converting means for converting into digital data, and leak judging means for judging presence / absence of leak based on output data of the A / D converting means, wherein the voltage converting circuit includes: A dummy resistor having a constant resistance value to be connected, a first switching unit that intermittently connects the dummy resistor to the voltage conversion circuit instead of the leak detection sensor, and the voltage conversion circuit is connected to the dummy resistor. Voltage conversion abnormality determining means for determining normality / abnormality of the voltage conversion circuit based on output data output from the A / D conversion means based on the above, and a diagnostic voltage for generating a constant voltage for diagnosis. A generating circuit; second switching means for intermittently connecting the diagnostic voltage generating circuit to the A / D converting means instead of the voltage converting circuit; and the A / D converting means serving as the diagnostic voltage generating circuit. A liquid leakage detection device comprising: an A / D conversion abnormality determination means for determining normality / abnormality of the A / D conversion means based on the output data when connected.