JP2017072402A - Liquid leakage detection device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a liquid leakage detection device capable of easily and surely performing setting of a device in a use time.SOLUTION: Liquid leakage detection devices 1A-1C comprise at least a sensor 10 containing an electrode pair 11 and comprise: a liquid leakage detection part 30 for outputting an output value according to an amount of a liquid which exists between the electrodes of the sensor 10; and a processing part 21 for determining presence/absence of liquid leakage based on the output value of the liquid leakage detection part 30. The processing part 21 sets a liquid leakage threshold based on a combined resistance of the liquid leakage detection part 30 in a state in which liquid leakage is not generated, and compares the value based on the output value and the liquid leakage threshold, for determining presence/absence of liquid leakage. Therefore, based on the combined resistance of the liquid leakage detection part 30 when liquid leakage is not generated, the liquid leakage threshold is automatically and correctly set, so that, an operator does not have to perform setting work of a device, namely inputs of a kind and a number of sensors 10 in a use time of the liquid leakage detection devices 1A-1C.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a leak detector.

  There is known a leak detector that utilizes a change in resistance value between electrode pairs in accordance with the amount of liquid existing between the electrodes of the sensor including the electrode pair. As such a leak detector, Patent Document 1 includes a plurality of sensors including electrode pairs, and the types and number of sensors estimated from the combined resistance of the resistance values between the electrode pairs of each sensor, and the operator Is used to determine whether or not the sensor is normally connected by comparing the type and number of sensors input by.

JP 2004-151062 A

  However, the operation of setting the device to input the type and number of sensors when using the leak detector is troublesome for the operator. In particular, when the leak detector includes different types of sensors, the operator needs to input the type of each sensor. In addition, when an operator inputs the type and number of sensors, an input error may occur. As described above, there is a demand for a liquid leakage detector that can easily and reliably set up a device during use.

  A leak detector according to an aspect of the present invention includes at least one sensor including an electrode pair, and a leak detector that outputs an output value corresponding to the amount of liquid existing between the electrodes of the sensor, And a processing unit that determines the presence or absence of leakage based on the output value of the liquid detection unit, and the processing unit sets a leakage threshold based on the combined resistance of the leakage detection unit in a state where no leakage has occurred. Then, the presence / absence of leakage is determined by comparing the value based on the output value with the leakage threshold.

  In this leak detector, the leak threshold is automatically set correctly based on the combined resistance of the leak detector when no leak has occurred. For this reason, it is not necessary for the operator to perform a device setting operation of inputting the type and number of sensors when using the leak detector. Therefore, it is possible to easily and reliably set the device during use.

  In the liquid leakage detector according to another aspect, the processing unit stores a data table in which values based on the combined resistance of the liquid leakage detection unit in a state where no liquid leakage occurs and a liquid leakage threshold value are associated with each other. The leak threshold may be set using a data table. In this case, it is possible to easily set the leak threshold based on the combined resistance of the leak detector when no leak has occurred.

  In the leak detector according to another aspect, the leak detector may include a plurality of sensors. When the leak detector has a plurality of sensors, the operation of setting the device to input the type and number of sensors is particularly troublesome for the operator when using the leak detector. There is a possibility that an input error occurs when the operator inputs the number. However, even in this case, according to the above configuration, the above-described effects can be suitably achieved.

  In the leak detector according to another aspect, the sensor may include a resistor connected between the electrode pair. When the sensor includes a resistor, it is troublesome for the operator to set the device to input the type and number of the sensor particularly when the leak detector is used, and the type and number of the sensor. There is a risk that an input error will occur when the operator inputs. However, even in this case, according to the above configuration, the above-described effects can be suitably achieved.

  In the leak detector according to another aspect, the leak detector may include a plurality of sensors, and at least two of the resistance values of the resistors included in the plurality of sensors may be different from each other. . In this case, since a sensor having a resistor having a different resistance value can be used depending on a place where each sensor is installed, the leakage can be detected more precisely.

  In the liquid leakage detector according to another aspect, the liquid leakage detection unit may include a plurality of sensors, and resistance values of resistors included in the plurality of sensors may be equal to each other. In this case, since the same type of sensor can be used, the manufacturing cost can be reduced.

  In the liquid leakage detector according to another aspect, the processing unit may acquire information on the liquid leakage detection unit based on an output value in a state where no liquid leakage occurs, and notify the information. In this case, the operator can confirm whether or not the automatically set leak threshold corresponds to the information related to the sensor provided in the leak detector.

  In the liquid leakage detector according to another aspect, the information may indicate the number of sensors. In this case, the operator can confirm whether or not the automatically set leak threshold corresponds to the number of sensors constituting the leak detector.

  In the liquid leakage detector according to another aspect, the sensor may include a resistor connected between the electrode pair, and the information may indicate a type of the sensor. In this case, the operator can confirm whether or not the automatically set leak threshold corresponds to the type of sensor constituting the leak detector.

  ADVANTAGE OF THE INVENTION According to this invention, the setting of the apparatus at the time of use can be performed easily and reliably.

It is the schematic which shows one Embodiment of the leak detector based on this invention. It is the schematic which shows an example of a sensor part. It is the schematic which shows an example of a sensor part. It is the schematic which shows an example of a sensor part. It is a figure which shows an example of a data table. It is a figure which shows typically the circuit structure of the leak detection part in the state which the leak has generate | occur | produced.

  Hereinafter, a preferred embodiment of a leak detector according to the present invention will be described in detail with reference to the drawings. FIG. 1 is a schematic view showing an embodiment of a liquid leakage detector according to the present invention, and FIGS. 2 to 4 are schematic views showing an example of a sensor unit.

  As shown in FIG. 1, the leak detectors 1 </ b> A to 1 </ b> C include a sensor 10, a controller 20, and a cable 13 that connects the sensor 10 and the controller 20. The liquid leakage detector 1A is a device that is installed indoors or outdoors and detects liquid leakage. In particular, the leak detector 1A suitably detects a leak of conductive liquid.

  First, the configuration of the sensor 10A in FIG. 2 will be described. As shown in FIGS. 1 and 2, as the sensor 10, one sensor 10 </ b> A is provided in the liquid leakage detector 1 </ b> A. The sensor 10A is provided with an electrode pair 11 exposed to the outside. The electrode pair 11 is composed of a pair of electrodes 11a and 11b that are spaced apart from each other. The electrodes 11a and 11b are connected to the ends of the cable 13, respectively. The electrodes 11 a and 11 b are not electrically connected to each other except that they are connected via the cable 13 and the controller 20. The electrodes 11a and 11b form an electric circuit with the liquid when the liquid exists between the electrodes, and as a result, the resistance value between the electrodes 11a and 11b decreases. Thus, the sensor 10A shows a resistance value corresponding to the amount of liquid existing between the electrodes.

  The cable 13 includes a signal line 13a and a signal line 13b. The signal line 13a has one end connected to the controller 20 and the other end connected to the electrode 11a. The signal line 13b has one end connected to the controller 20 and the other end connected to the electrode 11b.

  Next, the configuration of the sensor 10B in FIG. 3 will be described. As shown in FIGS. 1 and 3, the leak detector 1 </ b> B is different from the leak detector 1 </ b> A in the type of the sensor 10. As the sensor 10, the leak detector 1B is provided with one sensor 10B. The sensor 10 </ b> B includes a resistor 14 connected between the electrode pair 11. Here, the resistor 14 is, for example, a resistor 14B having a resistance value of 820 kΩ.

  Next, the configuration of the sensors 10C to 10E in FIG. 4 will be described. As shown in FIGS. 1 and 4, the leak detector 1 </ b> C differs from the leak detector 1 </ b> A in the type and number of sensors 10. As the sensor 10, the leak detector 1C is provided with three sensors 10C to 10E. The sensors 10C to 10E are connected to each other in parallel by a cable 13. Each of the sensors 10C to 10E includes resistors 14C to 14E connected between the electrode pairs 11, respectively. Here, each resistor 14 is, for example, resistors 14C to 14E having a resistance value of 820 kΩ. That is, the resistance values of the resistors 14C to 14E are equal to each other.

  In addition, the leak detectors 1A to 1C are examples of the configuration of the leak detector, and the configuration of the leak detector 30 is not limited to that described above. For example, the number of sensors 10 is not limited to one or three, and may be any number. When a plurality of sensors 10 are provided, the resistance values of the resistors 14 included in the sensors 10 may be different from each other, or only some of the resistors 14 may be different from each other. .

  As shown in FIGS. 1 to 4, the controller 20 is connected to the sensor 10 via the cable 13. The controller 20 includes a housing (not shown), and a processing unit 21, a power supply unit 22, an input unit 23, a notification unit 24, and an output value acquisition unit 25 provided in the housing. The sensor 10, the cable 13, and the output value acquisition unit 25 constitute a liquid leakage detection unit 30.

  The power supply unit 22 is connected to an external power source. When using an external power supply with an AC voltage, the power supply unit 22 includes, for example, an AC / DC converter, and converts the AC voltage from the external power supply into a DC voltage having a predetermined potential difference. The power supply unit 22 applies a predetermined voltage to the power supply unit 22 side of the electrode pair 11 of the sensor 10. The power supply unit 22 may apply a predetermined voltage to one side of the electrode pair 11 not only with the power from the external power source but also with the power from the built-in battery.

  The output value acquisition unit 25 is electrically connected to the cable 13 connected to the side opposite to the power supply unit 22 side of the electrode pair 11 of the sensor 10. The output value acquisition unit 25 has an internal circuit that branches from an electric circuit for supplying power from the power supply unit 22 and is grounded through a voltage dividing resistor. When a voltage is applied to the power receiving side of the electrode pair 11 by the power supply unit 22, the output value acquisition unit 25 has a resistance value between the electrode pair 11 and a resistance value of the voltage dividing resistor in the output value acquisition unit 25. , (Ie, a voltage value corresponding to the amount of liquid existing between the electrodes of the sensor 10) is acquired and output to the processing unit 21. In the present embodiment, this voltage value is the output value of the liquid leakage detection unit 30. Note that the output value of the liquid leakage detection unit 30 may not be the voltage value itself, but may be a value obtained by performing a predetermined calculation process on the voltage value.

  The processing unit 21 determines the presence or absence of liquid leakage based on the output value of the liquid leakage detection unit 30. The processing unit 21 first acquires the combined resistance of the liquid leakage detection unit 30 based on the output value of the liquid leakage detection unit 30 in a state where no liquid leakage has occurred. Specifically, in the present embodiment, the processing unit 21 includes a voltage value that is an output value of the liquid leakage detection unit 30 in a state where no liquid leakage occurs, and a voltage value that is applied to the electrode by the power supply unit 22. Based on the resistance value of the voltage dividing resistor, the combined resistance of each sensor 10 in the liquid leakage detection unit 30 is calculated and acquired. Here, “synthetic resistance” refers to the resistance value of the sensor 10 when only one sensor 10 is provided in the liquid leakage detector, for example.

  When the processing unit 21 acquires the combined resistance of the leak detection unit 30 in a state where no leak has occurred, the processing unit 21 sets a leak threshold based on the combined resistance. At this time, the processing unit 21 sets a leak threshold using a data table as shown in FIG. 5 as an example (see FIG. 5). The data table is stored in the storage unit 26 included in the processing unit 21. In the data table, a value based on the combined resistance in a state where no leakage occurs is associated with a leakage threshold (details will be described later).

  As illustrated in FIG. 1, the processing unit 21 compares a value based on the output value of the leak detection unit 30 input from the output value acquisition unit 25 with the leak threshold set by the processing unit 21. Thus, the presence or absence of leakage is determined. Specifically, in the present embodiment, the processing unit 21 calculates and acquires the output value of the leak detection unit 30, the voltage value applied to the electrode by the power supply unit 22, and the resistance value of the voltage dividing resistor. The presence or absence of leakage is determined by comparing the combined resistance and the leakage threshold.

  Moreover, the process part 21 acquires the information regarding the sensor 10 based on the output value in the state in which the liquid leakage has not generate | occur | produced. Here, the output value is a voltage value as an example. The processing unit 21 acquires information about the sensor 10 using a data table as shown in FIG. 5 as an example (see FIG. 5). The data table is stored in the storage unit 26 included in the processing unit 21. In the data table, a value based on the combined resistance in a state where no leakage occurs is associated with information on the sensor 10 (details will be described later).

  As information about the sensor 10, for example, the type and number of the sensor 10 can be used. The type of sensor 10 is, for example, information on whether or not the resistor 14 is included in the sensor 10 or the resistance value of the resistor 14 included in the sensor 10. Moreover, the number of sensors 10 is information regarding the number of sensors 10 connected in parallel in the liquid leakage detection unit 30, for example.

  The notification unit 24 notifies information related to the leak detection unit 30. The notification unit 24 may be a light-emitting unit such as an LED, and in this case, for example, the light-emitting body may blink in a light-emitting pattern of an LED assigned in advance to information to be notified. Further, the notification unit 24 may be an image display unit such as a liquid crystal screen. In this case, for example, the image display unit may display an image representing information to be notified in characters, symbols, designs, and the like. Moreover, the alerting | reporting part 24 may be an audio | voice, for example, In this case, you may sound the chime and melody previously allocated, for example to the information which should be alert | reported, and may read the announcement about the information which should be alert | reported.

  The input unit 23 receives an input of a start instruction or a restart instruction for the leak detectors 1A to 1C from the operator. The input unit 23 may be a switch or a touch panel, for example. The input part 23 will output the said start or restart instruction to the process part 21, if the input of the start instruction or restart instruction | indication of the leak detectors 1A-1C from an operator is received. The processing unit 21 to which the activation or restart instruction is input from the input unit 23 activates or restarts the leak detectors 1A to 1C. When the liquid leakage detectors 1A to 1C are activated or restarted, the processing unit 21 assumes that no liquid leakage has occurred, and based on the output value of the liquid leakage detection unit 30 at that time, the liquid leakage detection unit 30 combined resistances are acquired, and a leak threshold is set based on the combined resistance.

  Next, a procedure for creating the data table shown in FIG. 5 will be described.

First, the calculation method of the combined resistance of the liquid leakage detection unit 30 in the data table creation procedure will be described. In FIG. 5, type 0 to type 3 sensors having different conditions of the resistor 14 are listed as types of the sensor 10. The type 0 sensor does not have the resistor 14, and the resistance value between the electrode pair 11 is larger than 1 × 10 ⁶ kΩ. The type 1 sensor has a resistor 14 of 820 kΩ between the electrode pair 11. The type 2 sensor has a 720 kΩ resistor 14 between the electrode pair 11. The type 3 sensor has a 620 kΩ resistor 14 between the electrode pair 11.

In FIG. 5, SS1 to SS7 are listed as configuration examples of the sensor 10 in the liquid leakage detection unit 30. The liquid leakage detection unit 30 of SS1 has only one type 0 sensor 10. For this reason, the combined resistance of the leak detector 30 of SS1 is a value larger than 1 × 10 ⁶ kΩ. The liquid leakage detector 30 of SS2 has only one type 1 sensor. For this reason, the combined resistance of the leak detection unit 30 of SS2 is 820 kΩ. The liquid leakage detection unit 30 of SS3 has three type 1 sensors 10 connected in parallel. For this reason, the combined resistance of the leakage detector 30 of SS3 is 273 kΩ. The liquid leakage detection unit 30 of SS4 has five type 1 sensors 10 connected in parallel. For this reason, the combined resistance of the leak detection unit 30 of SS4 is 164 kΩ. The liquid leakage detection unit 30 of SS5 has three sensors 10 connected in parallel, and each sensor 10 includes one type 10, one type 2, and one type 3 sensor 10. For this reason, the combined resistance of the leak detection unit 30 of SS5 is 236 kΩ. The liquid leakage detection unit 30 of SS6 has four sensors 10 connected in parallel. Each sensor 10 includes one type 1 sensor and one type 2 sensor, and two type 3 sensors. It is out. For this reason, the combined resistance of the leak detection unit 30 of SS6 is 171 kΩ. The liquid leakage detection unit 30 of SS7 has two sensors 10 connected in parallel, and each sensor 10 includes one type 1 sensor and one type 3 sensor. For this reason, the combined resistance of the leak detector 30 of SS7 is 353 kΩ.

  As described above, in the data table, the value based on the combined resistance of the leak detection unit 30 in the state where no leak has occurred (in this embodiment, the value of the combined resistance itself) and the information on the sensor 10 (in this embodiment) , The type and number of sensors 10).

Next, a method for calculating the leak threshold in the data table creation procedure will be described. FIG. 6 is a diagram schematically illustrating a circuit configuration of the leakage detection unit in a state where leakage has occurred. As shown in FIGS. 5 and 6, the water resistance R _W is in the case where the amount of liquid to be determined leakage has occurred is present between the electrodes of the sensor 10, the resistance value of the liquid. Water resistance R _W, the amount of liquid present between the electrodes of the sensor 10, and a different value depending on the kind of liquid (electrical conductivity) existing between the electrodes of the sensor 10. Figure 5 50kohm In the water resistance R _W, 100 k.OMEGA, are mentioned three kinds of 200 k [Omega], and the amount of liquid to be determined to have leakage, the type of liquid that may leak by these 3 It is appropriately selected from the types.

The measurement value _RD calculated by the processing unit 21 from the voltage value of the output value acquisition unit 25 varies depending on the connection example of the sensor 10. In connection example of example SS2, also water resistance _{R W} is a case of a 100 k.OMEGA, measurements _{R D} becomes 89Keiomega. This, in a state in which leakage occurs, because the resistor resistor R _C and water resistance R _W of leak detection portion 30 constitute a parallel circuit, calculated in the processing unit 21 from the voltage value of the output value acquisition unit 25 This is because the measured value _{RD to} be obtained becomes a resistance value represented by the following formula (1). From this, by changing the leak threshold according to the combined resistance of the leak detector 30, the leak according to the amount of the liquid existing between the electrodes of the sensor 10 regardless of the type and number of the sensors 10. A threshold can be set. That is, for each combined resistance of leak detection unit 30, the water resistance R _W may be previously calculated each leakage threshold as a constant value.
1 / R _D = 1 / R _W + 1 / _RC (1)

  As described above, in the data table, the value based on the combined resistance of the leak detection unit 30 in the state where no leak has occurred (in this embodiment, the combined resistance value itself) is associated with the leak threshold. That's right. Note that the leak threshold value set by the above method is a value itself calculated based on the above formula (1), but a value obtained by appropriately increasing or decreasing this value may be used as a practical leak threshold value.

  Then, the acquisition method of the information regarding the sensor 10 using a data table is demonstrated.

  When the operator operates the input unit 23 and inputs a start or restart instruction for the leak detectors 1A to 1C, the processing unit 21 assumes that no leak has occurred at that time. In this state, the combined resistance of the leak detection unit 30 is acquired.

  The processing unit 21 refers to the data table and acquires information regarding the sensor 10 associated with the acquired combined resistance of the liquid leakage detection unit 30. For example, if the obtained combined resistance of the leak detection unit 30 is 820 kΩ, the combined resistance corresponds to the connection example of SS2, and therefore, only one type 1 sensor is connected to the leak detection unit 30. You can get information that Alternatively, if the obtained combined resistance of the leak detection unit 30 is 171 kΩ, since the combined resistance corresponds to the connection example of SS6, the leak detection unit 30 includes one type 1 sensor and one type 2 sensor. Information that two type 3 sensors are connected can be acquired.

  Note that the processing unit 21 causes the notification unit 24 to notify the acquired information on the liquid leakage detection unit 30. The notification unit 24 notifies information related to the type and number of sensors 10 constituting the liquid leakage detection unit 30 by a light emitting unit such as an LED, an image display unit such as a liquid crystal screen, or voice. Thereby, the operator can confirm whether the information regarding the sensor 10 acquired by the processing unit 21 matches the type and number of the sensors 10 that are actually connected. If they do not coincide with each other, after the connection state of the sensor 10 is corrected, the operator operates the input unit 23 to input a restart instruction to the leak detectors 1A to 1C, so that the processing unit 21 It is possible to reacquire the combined resistance of the leak detection unit 30 and reacquire information related to the sensor 10 associated with the combined resistance of the acquired leak detection unit 30.

  Next, a method for setting a leak threshold using a data table will be described.

  When the operator operates the input unit 23 and inputs a start or restart instruction for the leak detectors 1A to 1C, the processing unit 21 assumes that no leak has occurred at that time. In this state, the combined resistance of the leak detection unit 30 is acquired.

The processing unit 21 refers to the data table and sets a leak threshold used by the processing unit 21 associated with the obtained combined resistance of the leak detection unit 30. As the leak threshold, a value calculated in advance according to the above equation (1) is stored in the data table. For example, in the case where the water resistance _{R W} to detect was 100 k.OMEGA, when the combined resistance of the leak detection unit 30 obtained is 820kΩ, the processing unit 21 sets the leakage threshold 89Keiomega. Further, for example, in a case of a 200kΩ water resistance _{R W} to detect, when the combined resistance of the leak detection unit 30 obtained is 171kΩ, the processing unit 21 sets the leakage threshold 92Keiomega.

  As described above, in the leak detectors 1A to 1C, the leak threshold is automatically set correctly based on the combined resistance of the leak detector 30 when no leak has occurred. For this reason, it is not necessary for the operator to perform a device setting operation of inputting the type and number of sensors 10 when using the leak detectors 1A to 1C. Therefore, it is possible to easily and reliably set the device during use.

  Further, the processing unit 21 stores a data table in which a value based on the combined resistance of the liquid leakage detection unit 30 in a state where no liquid leakage has occurred and a liquid leakage threshold value are associated with each other, and the data table is used. Set the leak threshold. For this reason, the leak threshold can be easily set based on the combined resistance of the leak detector 30 when no leak has occurred.

  In addition, since the liquid leakage detection unit 30 includes a plurality of sensors 10, in general, it is troublesome for the operator to set the device to input the type and number of sensors 10 when using the liquid leakage detectors 1 </ b> A to 1 </ b> C. In addition, there is a possibility that an input error may occur when the operator inputs the type and number of sensors 10. However, even in this case, according to the above configuration, the above-described effects can be suitably achieved.

  In addition, since the sensor 10 includes the resistor 14, in general, it is troublesome for the operator to input the type and number of the sensor 10 when using the leak detectors 1 </ b> A to 1 </ b> C. In addition, when an operator inputs the type and number of sensors 10, an input error may occur. However, even in this case, according to the above configuration, the above-described effects can be suitably achieved.

  The liquid leakage detection unit 30 includes a plurality of sensors 10, and at least two of the resistance values of the resistors 14 included in the plurality of sensors 10 are different from each other. In this case, since the sensor 10 having the resistor 14 having a different resistance value can be used depending on the place where each sensor 10 is installed, the leakage can be detected more precisely.

  In addition, the liquid leakage detection unit 30 includes a plurality of sensors 10, and the resistance values of the resistors 14 included in the plurality of sensors 10 are equal to each other. In this case, since the same type of sensor 10 can be used, the manufacturing cost can be reduced.

  Moreover, the process part 21 acquires the information regarding the leak detection part 30 based on the output value in the state in which the leak has not generate | occur | produced, and alert | reports information. For this reason, the operator can confirm whether or not the automatically set leak threshold corresponds to the information regarding the sensor 10 provided in the leak detector 30 correctly.

  The information indicates the number of sensors 10. For this reason, the operator can check whether or not the automatically set leak threshold corresponds to the number of sensors 10 constituting the leak detector 30 correctly.

  The sensor 10 includes a resistor 14 connected between the electrode pair 11, and the information indicates the type of the sensor 10 that constitutes the liquid leakage detection unit 30. For this reason, the operator can confirm whether or not the automatically set leak threshold corresponds to the type of the sensor 10 constituting the leak detector 30.

As mentioned above, although one Embodiment of this invention was described, this invention is not limited to the said one Embodiment. For example, the data table may be different from the data table shown in FIG. Specifically, the sensor 10 may include a sensor 10 of a type having a different resistor 14 condition from that of the type 0 to the type 3, and a connection example different from SS1 to SS7 as a connection example of these individual sensors 10. it may contain, as a water-resistance _{R W} 50kohm, 100 k.OMEGA, may include different water resistance _{R W} and three 200 k [Omega].

  DESCRIPTION OF SYMBOLS 1A, 1B, 1C ... Liquid leak detector, 10 ... Sensor, 11 ... Electrode pair, 14 ... Resistor, 21 ... Processing part, 30 ... Liquid leak detection part.

Claims (9)

A liquid leakage detector having at least one sensor including an electrode pair and outputting an output value corresponding to the amount of liquid existing between the electrodes of the sensor;
A processing unit for determining the presence or absence of liquid leakage based on the output value of the liquid leakage detection unit,
The processor is
Set a leak threshold based on the combined resistance of the leak detector in the absence of leak,
A leak detector that determines the presence or absence of leak by comparing a value based on the output value and the leak threshold.   The processing unit stores a data table in which a value based on the combined resistance of the leak detection unit in a state where no leak has occurred and the leak threshold are associated with each other, and the data table is used. The leak detector according to claim 1, wherein the leak threshold is set.   The liquid leakage detector according to claim 1, wherein the liquid leakage detection unit includes a plurality of the sensors.   The liquid leakage detector according to claim 1, wherein the sensor includes a resistor connected between the electrode pair. The liquid leakage detection unit has a plurality of the sensors,
The liquid leakage detector according to claim 4, wherein at least two of the resistance values of the resistors included in the plurality of sensors are different from each other. The liquid leakage detection unit has a plurality of the sensors,
The liquid leakage detector according to claim 4, wherein resistance values of the resistors respectively included in the plurality of sensors are equal to each other.   The liquid leakage according to any one of claims 1 to 6, wherein the processing unit acquires information on the liquid leakage detection unit based on the output value in a state where no liquid leakage occurs, and notifies the information. Detector.   The leak detector according to claim 7, wherein the information indicates a number of the sensors. The sensor includes a resistor connected between the electrode pair;
The liquid leakage detector according to claim 7 or 8, wherein the information indicates a type of the sensor.