JP2010190574A - Liquid leak detector - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a liquid leak detector capable of quickly pinpointing an actual liquid leaking spot even when the liquid leak occurs at a place such as a dark place. <P>SOLUTION: A plurality of light emission sections D1-Dn are wired at predetermined intervals along a detection cable 200. When the liquid leaks, the liquid leak detector 100 calculates the position of the liquid leak on the basis of the voltage value of a voltage sensor and allows the light emission section D corresponding to the calculated liquid leak position to emit light. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a leak detection device that notifies the occurrence of a leak and the position of the leak.

  A leak detection system that detects a leak may be installed in a place such as a computer room or an article storage where it is necessary to prevent damage due to the leak.

  Patent Document 1 discloses a leak detection system that includes a leak sensor disposed at a leak detection location and a leak detector that detects leak from the output of the leak sensor.

  In the leak detection system disclosed in Patent Document 1, the leak sensor accommodates two conductors in an insulating film with a constant interval. The insulating coating is partially absent at the side edges of both conductors, both conductors are partially exposed to the outside from the lacked portions, and the exposed portions of the respective conductors serve as leakage detection electrodes. When an AC signal is applied between the electrodes, the leak detector will short circuit between the electrodes via the leak when a leak occurs, resulting in a closed circuit state, so detection according to the applied AC signal A signal can be detected, and the occurrence of liquid leakage can be detected.

  Further, Patent Document 2 includes a detection line having an electrode line made of a pair of conductors, a constant current power source, a voltage measurement unit, and a determination unit, and between the electrode lines at one end of the detection line when leaking is detected. Connect the constant current power supply, connect the voltage measurement means between the near end and the far end of the low voltage side electrode line of the detection line, and the judgment means will calculate the leakage position from the voltage value measured by the voltage measurement means. A liquid detection device is disclosed.

JP 2000-131176 A Japanese Patent Application Laid-Open No. 7-113719

  As described above, there is known a liquid leakage detection device that notifies the occurrence of liquid leakage and the position of the liquid leakage.

  However, there are many relatively dark places, such as under the floor and behind the ceiling, where the leak is detected by the leak detector. Further, the leaked liquid is often colorless and transparent. Therefore, even if the leak position is notified by the leak detection device, it may be difficult to quickly identify the actual leak location at the site.

  An object of the present invention is to provide a leak detection device that can quickly identify an actual leak location even when the location where the leak has occurred is a place such as a dark place.

  The liquid leakage detection device according to the present invention includes a resistance wire, a detection wire that is insulated from the resistance wire, short-circuited with the resistance wire due to liquid leakage, and the resistance at the time of a short circuit due to liquid leakage between the detection wire. A liquid leakage position calculation unit that calculates a liquid leakage position of the line, a plurality of light emitting units arranged along the resistance line, and light emission position information that defines a range of liquid leakage positions corresponding to each of the light emitting units. A storage unit for storing, a light emission control unit that identifies the light emitting unit corresponding to the liquid leakage position calculated by the liquid leakage position calculating unit with reference to the light emission position information, and causes the identified light emitting unit to emit light, It is characterized by providing.

  According to the liquid leakage detection device of the present invention, a plurality of light emitting units arranged along the resistance line are provided, and when the liquid leakage occurs, the light emitting unit corresponding to the liquid leakage position emits light. Even when it is not easy to identify the actual leak location with the naked eye such as in a dark place where the leak has occurred, the actual leak location can be quickly identified.

  A liquid leakage detection device according to the present invention includes a plurality of liquid leakage detection sensors for detecting liquid leakage in a predetermined liquid leakage detection region, and each liquid leakage detection region of each liquid leakage detection sensor or each liquid leakage detection. A plurality of light emitting units provided along the region, a light emitting position information storage unit that stores light emitting position information indicating identification information of the light emitting unit corresponding to each liquid leak detecting sensor, and any one of the liquid leak detecting sensors The light emission control for identifying the light emitting part corresponding to the liquid leakage detection sensor that has detected the liquid leakage by referring to the light emission position information and causing the identified light emitting part to emit light in response to the liquid leakage detected by And a section.

  According to the liquid leakage detection device of the present invention, the light emitting unit corresponding to the liquid leakage detection sensor that has detected the liquid leakage emits light in response to the liquid leakage detected by any of the liquid leakage detection sensors. Therefore, even if it is not easy to identify the actual leak location with the naked eye, such as in a dark place where the leak has occurred, the actual leak location can be quickly identified.

  In one aspect of the liquid leakage detection device according to the present invention, the liquid leakage detection sensor has a pair of electrodes wired in an insulated state from each other, and the liquid leakage is caused by the short circuit between the pair of electrodes. The light emitting unit is installed in a liquid leakage detection region formed by the pair of electrodes and capable of detecting liquid leakage.

  According to one aspect of the liquid leakage detection device according to the present invention, the light emitting section emits light within the liquid leakage detection region corresponding to the liquid leakage location, so that the location where the liquid leakage occurs is a dark place, etc. Thus, even when it is not easy to identify the actual leak location with the naked eye, it is possible to quickly identify the leak region corresponding to the actual leak location.

  In one aspect of the liquid leakage detection device according to the present invention, the liquid leakage detection sensor has a pair of electrodes wired in an insulated state from each other, and the liquid leakage is caused by the short circuit between the pair of electrodes. A plurality of the light emitting units are installed so as to surround a liquid leakage detection region formed by the pair of electrodes and capable of detecting liquid leakage.

  According to one aspect of the liquid leakage detection device according to the present invention, since the plurality of light emitting units provided along the liquid leakage detection region corresponding to the liquid leakage location emit light, the place where the liquid leakage occurs is dark. Even if it is not easy to identify the actual leak location with the naked eye at a place such as a place, the range of the leak region corresponding to the actual leak location can be quickly identified.

  According to the present invention, by causing the light emitting unit corresponding to the liquid leakage position to emit light in response to the occurrence of liquid leakage, the actual liquid leakage occurs in a place such as a dark place where the liquid leakage occurred. Even when it is not easy to identify the spot with the naked eye, the actual leaking spot can be quickly identified.

It is a figure which shows the whole structure of the leak detection apparatus which concerns on this embodiment. It is a figure which shows the circuit structure of the liquid leak detection apparatus which concerns on this embodiment. It is a figure which shows the functional block of the control part with which the leak detection apparatus which concerns on this embodiment is provided. It is a figure which shows an example of the light emission position information memorize | stored in the light emission position information storage part which concerns on this embodiment. It is a figure which shows a circuit state at the time of a resistance wire and a detection wire short-circuiting by the leak at a short circuit point. It is a flowchart which shows the process sequence at the time of the liquid leak detection apparatus concerning this embodiment calculating a liquid leak. It is a figure which shows the whole structure of the leak detection apparatus which concerns on this modification. It is a figure which shows the circuit structure of a leak sensor. It is a figure which shows the functional block of the control part with which the leak detection apparatus which concerns on this modification is provided. It is a figure which shows an example of the light emission position information memorize | stored in the light emission position information storage part which concerns on this modification. It is a flowchart which shows the process sequence at the time of the liquid leak detection apparatus concerning this modification calculating a liquid leak. It is a figure which shows the circuit structure of another aspect of a leak sensor.

  DESCRIPTION OF EMBODIMENTS Hereinafter, modes for carrying out the present invention (hereinafter referred to as “embodiments”) will be described with reference to the drawings.

  FIG. 1 is a diagram illustrating an overall configuration of a leak detection apparatus according to the present embodiment.

  As shown in FIG. 1, a detection cable 200 for detecting leakage is connected to the leakage detection device 100. When a leak occurs in the vicinity of the detection cable 200, the leak detection device 100 calculates the leak position and displays on the built-in display or the like where the leak is occurring on the detection cable 200. To notify the user. Furthermore, in the present embodiment, light emitting portions D1 to Dn (hereinafter, collectively referred to as “light emitting portion D”) such as light emitting diodes are wired along the detection cable 200 at predetermined intervals. When the liquid leakage occurs, the liquid leakage detection device 100 configured as described above displays the liquid leakage position on the display or the like to the user and emits the light emitting unit D corresponding to the location where the liquid leakage actually occurs. By informing the user of the occurrence of leakage and the location of occurrence of leakage.

  FIG. 2 is a diagram illustrating a circuit configuration of the liquid leakage detection apparatus 100 according to the present embodiment.

  In FIG. 2, one end of a signal line L is connected to the power supply unit 20, and a leakage detection current having a voltage value Vo and a current value Io is output via the signal line L. To the signal line L, a resistance line 30 having a resistance value Rz, a switch 12, and a resistor 32 having a resistance value R1 are connected in series. More specifically, one end of the resistance line 30 is connected to the other end of the signal line L, one end of the switch 12 is connected to the other end of the resistance line 30, and one end of the resistor 32 is connected to the other end of the switch 12. The other end of the resistor 32 is grounded.

  Furthermore, one end of the detection line La is connected to the contact Pa between the resistance line 30 and the switch 12, and the other end of the detection line La is grounded via the voltage sensor 14. In other words, the voltage sensor 14 is connected in parallel with the switch 12 and the resistor 32 connected in series via the detection line La, and detects the voltage value Va of the contact Pa.

  Further, the detection line Lb is in an insulated state with the resistance line 30 when no leakage occurs, one end of the detection line Lb is opened, and the other end is grounded via the voltage sensor 16. The voltage sensor 16 detects the voltage value Vb at the short-circuit point on the resistance wire 30 when the resistance wire 30 and the detection wire Lb are short-circuited due to leakage.

  In addition, in the vicinity of the resistance line 30, a light emitting portion D capable of emitting light at a predetermined location such as a light emitting diode or a liquid crystal display is wired along the resistance line 30 with a predetermined interval.

  The signal line L, the resistance line 30, the detection line La, and the detection line Lb are incorporated in the detection cable 200 shown in FIG. Moreover, you may also incorporate into the detection cable 200 the conducting wires d1-dn for transmitting the signal (electric current) for making the light emission part D light-emit.

  The control unit 10 is configured by a microcomputer or the like, and controls on / off of the switch 12 and calculates a leakage position based on the voltage values Va and Vb acquired through the voltage sensors 14 and 16. Moreover, the control part 10 specifies the light emission part corresponding to the calculated leak position, and performs light emission of the specified light emission part.

  In the present embodiment, when a plurality of light emitting portions D are wired at predetermined intervals along the resistance wire 30 and liquid leakage occurs, the light emitting portions D corresponding to the liquid leakage positions are caused to emit light. Even when the leaking point is a dark room or the like, the leaking liquid is colorless and transparent, etc., and the identification with the naked eye is not easy, the actual leaking point can be quickly identified.

  FIG. 3 is a diagram illustrating functional blocks of the control unit 10.

  3, the control unit 10 includes a CPU 110, a ROM 112, a RAM 114, a storage device 120, and an input / output interface 150. The CPU 110, the ROM 112, the RAM 114, the storage device 120, and the input / output interface 150 are connected via a communication bus 160. Connected.

  The CPU 110 develops a basic control program such as a BIOS program stored in the ROM 112 in the RAM 114, further detects the position of the liquid leak stored in the storage device 120, and emits light corresponding to the liquid leak position D. A program 130 for emitting light is developed in the RAM 114, and the program 130 is executed to calculate the position of the liquid leakage and light emission of the light emitting unit.

  In the present embodiment, the storage device 120 stores a liquid leakage position calculation unit 132 and a light emission control unit 134 as a program 130. The leak position calculation unit 132 calculates the leak position based on the voltage values Va and Vb acquired via the input / output interface 150. Details of the leak position calculation process will be described later. In addition, the storage device 120 stores a light emission position information storage unit 140 that indicates a relationship between a liquid leakage position and a light emitting unit that is a light emission target corresponding to the liquid leakage position. FIG. 4 shows an example of the light emission position information. As shown in FIG. 4, in the light emission position information, identification information for uniquely identifying the light emitting parts to be emitted one by one in association with each liquid leakage position is registered in the liquid leakage positions. ing.

  FIG. 5 shows a circuit state when the resistance wire 30 and the detection wire Lb are short-circuited due to leakage at the short-circuit point Lb1.

  Here, with reference to FIG. 5, when a leak occurs, the leak position calculation unit 132 calculates the position of the leak (the distance β from the other end (contact point Pa) of the resistance wire 30). explain. In addition, the detection method of the leak position demonstrated below is only an example, You may apply the detection method of the other known leak position.

  The resistance value of the resistance wire 30 is 1 meter unit XΩ, the resistance value of the resistance wire 30 from the contact point Pa to the short circuit point Lb1 is Rx, the resistance value of the resistor 32 is R1, the current flowing through the resistor Rx is Io, and the leakage resistance is The resistance value is Rs.

  Since the current flowing through the leak resistance Rs is very small compared to the current flowing through the resistor R1, the current Io can be obtained by the equation (1).

Io = Va / R1 (1)
Further, the resistance Rx can be obtained by equation (2).

Rx = (Vb−Va) / Ia (2)
Therefore, the distance β corresponding to the position of the first leakage can be obtained from the equation (3) based on the equations (1) and (2).

β = Rx / X = R1 (Vb−Va) / (X × Va) (3)
FIG. 6 is a flowchart showing a processing procedure when the leak detection device according to the present embodiment calculates a leak.

  In FIG. 6, the leakage position calculation unit 132 determines that leakage has occurred, for example, when the voltage value of the voltage sensor 16 changes by a predetermined value or more, turns on the switch 12, and calculates the leakage position. Is started (S100). That is, the liquid leakage position calculation unit 132 acquires the voltage values Va and Vb via the voltage sensors 14 and 16 and substitutes the acquired Va and Vb into the above equation (3), so that the distance β, that is, the liquid leakage Calculate the position. Subsequently, the light emission control unit 134 refers to the light emission position information storage unit 140 and identifies the light emission unit to be emitted corresponding to the calculated liquid leakage position (S102). For example, when the calculated liquid leakage position is included in the range of L2 ± α, the light emission control unit 134 specifies that the light emitting unit to be emitted is the light emitting unit D2. Furthermore, the light emission control unit 134 causes the identified light emitting unit to emit light, for example, by outputting a current from an output interface corresponding to the identified light emitting unit (S104).

  As described above, according to the present embodiment, when a plurality of light emitting portions D are wired at predetermined intervals along the resistance wire 30 and liquid leakage occurs, the light emitting portions D corresponding to the liquid leakage positions are caused to emit light. As a result, even if the leak location is in a dark room or the case where the leaked liquid is colorless and transparent and the identification by the naked eye is not easy, the actual leak location can be quickly identified.

  Subsequently, modified examples of the present embodiment will be described below with reference to the drawings.

  In this modification, a plurality of sensors configured to detect leakage when a pair of electrodes are wired at a predetermined interval and the electrodes are short-circuited due to leakage are arranged in the leakage detection area. This is different from the above-described embodiment in which leakage is detected using a single detection cable 200.

  FIG. 7 is a diagram showing an overall configuration of a liquid leakage detection apparatus 101 according to this modification. FIG. 8 is a diagram illustrating a circuit configuration of a liquid leakage sensor 210 provided in the liquid leakage detection device 101.

  As illustrated in FIG. 7, the liquid leakage detection device 101 according to this modification includes a plurality of liquid leakage sensors 210 and a light emitting unit D such as a light emitting diode provided for each liquid leakage sensor 210.

  As shown in FIG. 8, the leak sensor 210 has one electrode 212 formed of a comb-shaped conductive pattern and one electrode 214 formed of a comb-shaped conductive pattern on the surface of the substrate 216. Further, the gaps are configured to be alternately meshed while maintaining an insulating state with a space therebetween. Liquid leakage is detected when the electrodes 212 and 214 thus wired are short-circuited due to liquid leakage. That is, the region where the leakage can be detected (leak detection region 218) is a region where the pair of electrodes 212 and 214 can be short-circuited with each other as shown in FIG. Furthermore, in this modification, the light emitting part D is wired near the central part of the liquid leakage detection area 218 of the liquid leakage sensor 210, for example.

  The leak detection device 101 sends a leak detection signal to one electrode 212. When no liquid leakage occurs, the one electrode 212 and the other electrode 214 are insulative, and the one and the other electrodes 212 and 214 are in an open loop. Therefore, when no leak has occurred, the leak detection device 101 does not detect a signal based on the leak detection signal (hereinafter referred to as a “leak generation signal”) from the other electrode 214.

  On the other hand, when leakage occurs, one electrode 212 and the other electrode 214 are short-circuited due to leakage, so that the leakage detection signal sent to one electrode 212 is transmitted to the other through the leakage. Is transmitted to the electrode 214. That is, the first and second electrodes 212 and 214 are in a closed loop. Therefore, when a leak occurs, the leak detection device 101 detects a signal based on the leak detection signal (hereinafter referred to as a “leak generation signal”) from the other electrode 214.

  When a leak occurs, the leak detection device 101 identifies the leak sensor 210 that has detected the leak occurrence signal, and causes the light emitting unit D corresponding to the identified leak sensor 210 to emit light.

  FIG. 9 is a diagram illustrating functional blocks of the control unit 10 provided in the liquid leakage detection apparatus 101. In the present modification, the leak occurrence sensor specifying unit 136 is stored in the storage unit 120 instead of the leak position calculation unit 132, and the light emission position information storage unit 140 corresponds to the leak sensor instead of the leak position. It is different from the control part 10 which concerns on the said embodiment by the point which memorize | stores the identification information of the light emission part D of light emission object.

  The leak occurrence sensor specifying unit 136 sends out a leak occurrence signal from each electrode 212 of each leak sensor provided in the leak detection device 101 via the input / output interface 150. Further, the leak occurrence sensor specifying unit 136 constantly monitors whether or not a leak occurrence signal is input from each other electrode 214 via the input / output interface 150, and detects the input of the leak detection signal. In the case, the leak sensor 210 arranged in the area where the leak has occurred is specified based on the number of the input port (not shown) that has detected the leak detection signal. Further, the leak occurrence sensor specifying unit 136 provides the identification information of the specified leak sensor 210 to the light emission control unit 134.

  FIG. 10 shows an example of light emission position information in which the identification information of each light emitting unit D to be emitted is registered in association with each identification information of each liquid leakage sensor stored in the light emission position information storage unit 140. The light emission control unit 134 receives the identification information of the liquid leakage sensor 210 arranged in the area where the liquid leakage has occurred from the liquid leakage generation sensor specifying unit 136, and the light emission unit corresponding to the identification information of the liquid leakage sensor 210 The identification information of D is specified by referring to the light emission position information, and the current is output from the output interface corresponding to the light emitting unit D corresponding to the specified identification information, thereby causing the specified light emitting unit D to emit light.

  FIG. 11 is a flowchart showing a processing procedure when the leak detection device according to the present modification calculates a leak.

  In FIG. 11, the leakage occurrence sensor specifying unit 136 constantly monitors whether or not a leakage occurrence signal is input from the other electrode 214 of each leakage sensor 21 via the input / output interface 150. When the input of the liquid detection signal is detected, the leakage sensor 210 arranged in the area where the leakage has occurred is specified based on the number of the input port that has detected the leakage detection signal (S20). Next, the light emission control unit 134 receives the identification information of the leakage sensor 210 arranged in the area where the leakage occurred from the leakage occurrence sensor specifying unit 136, and corresponds to the identification information of the leakage sensor 210. The identification information of the light emitting unit D is specified by referring to the light emission position information shown in FIG. 10 (S202). Further, the light emission control unit 134 causes the identified light emitting unit D to emit light by outputting a current from the output interface corresponding to the light emitting unit D corresponding to the identified identification information (S204).

  As described above, in this modification, when a leak occurs, the leak detection device 101 identifies the leak sensor 210 that has detected the leak occurrence signal, and emits light corresponding to the identified leak sensor 210. By causing part D to emit light, even if the leak location is in a dark room, etc., or when the leaked liquid is colorless and transparent, etc., and it is not easy to identify with the naked eye, the actual leak location is quickly identified. it can.

  In the above-described modification, an example in which one light-emitting diode is provided as the light-emitting portion D approximately at the center of each leakage detection region of each leakage sensor 210 has been described. However, each liquid leakage sensor 210 may be provided with a plurality of light emitting portions D such as light emitting diodes.

  FIG. 12 is a diagram illustrating an example of a circuit configuration when a plurality of light emitting units D are provided in the liquid leakage sensor 210. In FIG. 12, the light emitting diodes D are connected in series and wired so as to surround the liquid leakage detection region 218 formed by the pair of electrodes 212 and 214. By wiring in this way, the entire liquid leakage occurrence region emits light, and thus the actual liquid leakage location can be identified more quickly.

  In the present invention, by causing the light emitting portion corresponding to the leak position to emit light in response to the occurrence of the leak, the leak occurs even in a place such as a dark place. Even if it is not easy to specify, the actual leak location can be specified quickly, so that the present invention can be applied to a leak detection device that notifies the occurrence of leak or the position of leak.

DESCRIPTION OF SYMBOLS 10 Control part 12 Switch 14,16 Voltage sensor 20 Power supply part 30 Resistance wire D Light emission part L Signal line La, Lb Detection line 100, 101 Leak detection device 110 CPU
112 ROM
114 RAM
DESCRIPTION OF SYMBOLS 120 Memory | storage device 130 Program 132 Liquid leak position calculation part 134 Light emission control part 136 Liquid leak generation | occurrence | production sensor specific | specification part 140 Light emission position information storage part 150 I / O interface 160 Communication bus 200 Detection cable

Claims (4)

Resistance wire,
A detection line that is insulated from the resistance line and short-circuited with the resistance line due to leakage,
A liquid leakage position calculating unit for calculating the liquid leakage position of the resistance wire at the time of a short circuit due to liquid leakage with the detection line;
A plurality of light emitting units arranged along the resistance line;
A storage unit that stores light emission position information that defines a range of liquid leakage positions corresponding to each of the light emission units;
A light emission control unit that identifies the light emission unit corresponding to the liquid leakage position calculated by the liquid leakage position calculation unit with reference to the light emission position information, and causes the identified light emission unit to emit light;
A liquid leakage detection device comprising: A plurality of leak detection sensors for detecting leaks in a predetermined leak detection area,
A plurality of light emitting units provided in or along each leakage detection region of each leakage detection sensor; and
A light emission position information storage unit that stores light emission position information indicating identification information of the light emission unit corresponding to each liquid leakage detection sensor;
In response to the leakage detected by any of the leakage detection sensors, the light emitting unit corresponding to the leakage detection sensor that has detected the leakage is identified and identified by referring to the light emission position information. A light emission control unit for causing the light emitting unit to emit light,
A liquid leakage detection device comprising: The liquid leakage detection device according to claim 2,
The liquid leakage detection sensor has a pair of electrodes wired in an insulated state from each other, and detects a liquid leakage by short-circuiting the liquid leakage between the pair of electrodes,
The light emitting unit is installed in a liquid leakage detection region formed by the pair of electrodes and capable of detecting liquid leakage. The liquid leakage detection device according to claim 2,
The liquid leakage detection sensor has a pair of electrodes wired in an insulated state from each other, and detects a liquid leakage by short-circuiting the liquid leakage between the pair of electrodes,
A plurality of the light emitting sections are installed so as to surround a liquid leakage detection region formed by the pair of electrodes and capable of detecting liquid leakage.