JP2017073172A - Fire detector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fire detector capable of speedily detecting heat generation of a planate monitoring object such as a solar panel using an inexpensive and simple configuration.SOLUTION: A fire detector which detects a heat generation state of a solar panel is installed on a rear surface of the solar panel or a group of a plurality of solar panels. The fire detector comprises: a set of electric wires 22 provided with a coating which melts at a predetermined low melting point; and a control section 40 which detects the heat generation state of the solar panel or the group of the plurality of solar panels by monitoring a short circuit state of the set of the electric wires 22 with the coating thereof melted due to the heat generation of the solar panel or the group of the plurality of solar panels.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a fire detection device and a fire detection method capable of detecting heat generation of a planar monitoring target such as a solar panel, for example.

  In a general residential solar power generation system, a solar cell array (hereinafter, this solar cell array is referred to as a solar panel) composed of solar cell modules connected in series and parallel is installed on the roof of a house. Yes. And the output from a solar panel is connected to the power conditioner via the relay terminal box, and it is comprised so that desired electric power may be obtained (for example, refer patent document 1).

JP 2013-110290 A

However, the prior art has the following problems.
While such a photovoltaic power generation system is widespread, an increase in fire caused by the photovoltaic power generation system is a problem. Since the solar panel always generates power when irradiated with light, a failure in the solar panel may lead to a fire.

  Therefore, it is important to quickly detect the heat generation of such a planar monitoring target such as a solar panel. For example, if an infrared camera or the like is used, such heat generation can be monitored. However, in the configuration using the infrared camera, the entire system becomes expensive, and it has been difficult to effectively and inexpensively monitor the abnormal heat generation of the solar panel. In the future, in consideration of the widespread use of solar panels, it is desired to detect heat generation using an inexpensive and simple configuration.

  The present invention has been made to solve the above-described problems, and can quickly detect the heat generated by a planar monitoring object such as a solar panel using an inexpensive and simple configuration. It aims at obtaining a fire detection apparatus and a fire detection method.

(1-1) The present invention is a fire detection device that detects a heat generation state of a solar panel, and is disposed on the back surface of the solar panel or a plurality of solar panel groups, and melts at a predetermined low melting point. A set of electric wires with a covering and the heat generation of the solar panel or a plurality of solar panel groups are monitored to melt the covering of the electric wires so that the one set of electric wires are short-circuited. And a control unit that detects a heat generation state of the light panel or the plurality of solar panel groups.

(1-2) The present invention is a fire detection device that detects a heat generation state of a solar panel, and is disposed only on the entire circumference or part of the periphery of the solar panel or the plurality of solar panel groups, Due to the heat generated by the solar panel or the plurality of solar panel groups, the set of electric wires is short-circuited due to melting of the cover of the electric wire due to the heat generation of the solar panel or the plurality of solar panel groups. And a controller that detects the heat generation state of the solar panel or the plurality of solar panel groups.

(1) A fire detection device according to the present invention is a fire detection device that detects a heat generation state of a planar monitoring object, and is attached to one surface of the monitoring object and melts at a predetermined low melting point. The voltage between the conductive patterns is monitored so that the conductive pattern is disconnected due to melting of the base material on the sheet due to heat generation of the monitoring target and the sheet provided with the conductive pattern on the material. And a control unit that detects the heat generation state of the monitored object.

(2) The fire detection device according to the present invention is a fire detection device that detects the heat generation state of a planar monitoring object, and is a cover that is attached to one surface of the monitoring object and melts at a predetermined low melting point. Between one set of electric wires and one set of electric wires being short-circuited due to melting of the coating on the sheet due to the heat generated by the monitoring object And a control unit that detects the heat generation state of the monitoring object.

  According to the present invention, on a sheet affixed to a planar monitoring object, an electric wire having a disconnection state between patterns on a substrate that melts at a predetermined low melting point or a coating that melts at a predetermined low melting point A fire detection device and a fire detection method capable of quickly detecting the heat generated by a planar monitoring object such as a solar panel by using an inexpensive and simple configuration Can do.

It is explanatory drawing of the sheet | seat used for the fire detection apparatus for detecting the heat_generation | fever of the planar monitoring target object in Embodiment 1 of this invention. It is an illustration figure in the case of cascade-connecting the sheet | seat shown in previous FIG. 1 in Embodiment 1 of this invention. It is explanatory drawing of the sheet | seat used for the fire detection apparatus for detecting the heat_generation | fever of the planar monitoring target object in Embodiment 2 of this invention. It is explanatory drawing of the sheet | seat used for the fire detection apparatus for detecting the heat_generation | fever of the planar monitoring target object in Embodiment 2 of this invention, and is the figure which showed the example of wiring different from previous FIG. It is a circuit diagram of the fire detection apparatus in Embodiment 3 of this invention. It is explanatory drawing of the structure of the base material and 1st conductive pattern in Embodiment 4 of this invention.

Hereinafter, preferred embodiments of a fire detection device and a fire detection method of the present invention will be described with reference to the drawings.
The present invention monitors the disconnection state between patterns on a base material that melts at a predetermined low melting point, or the short circuit state between electric wires with a coating that melts at a predetermined low melting point, so that the pattern or the electric wire is arranged. It is a technical feature to detect the heat generation state of the planar monitoring target. In the following description, a solar panel will be described as an example of a planar monitoring target, but an inexpensive and simple configuration is similarly used for other planar monitoring targets. Thus, fever can be detected quickly.

Embodiment 1 FIG.
FIG. 1 is an explanatory diagram of a sheet used in a fire detection device for detecting heat generation of a planar monitoring target in Embodiment 1 of the present invention. The sheet used for the fire detection apparatus in the first embodiment is, for example, conductive fine particles (or carbon black or ITO (indium-tin oxide)) on the base material 10 having a melting point of about 100 to 200 ° C. (or The conductive pattern 20 is formed by printing a conductive paint).

  The pair of conductive patterns 20 includes a first conductive pattern 20a disposed so as to cover the entire surface of the base material 10 on one side of the base material 10, and a second conductive pattern 20b disposed between the opposing end surfaces. (See FIG. 1). In addition, diodes 30 are arranged in parallel at both ends of the first conductive pattern 20a.

  FIG. 2 is an exemplary view when the sheets shown in FIG. 1 in the first embodiment of the present invention are cascade-connected. The unit sheet shown in FIG. 1 is affixed to the back surface of each solar cell module that constitutes a solar panel that is a planar monitoring object. Then, as shown in FIG. 2, the respective sheets are cascade-connected by connecting the first conductive patterns 20a and the second conductive patterns 20b, respectively.

  Further, a closed circuit composed of a plurality of cascade-connected sheets, a DC power source 1, and resistors 2 and 3 is configured, and the voltage between the monitoring points P1 and 0V in FIG. By monitoring the fluctuation of the monitoring voltage V by the unit 40, it is possible to detect the presence or absence of heat generation of the solar panel.

  Specifically, when the base material 10 melts due to abnormal heat generation of the panel, the pair of conductive patterns 20 printed on the base material 10 is torn, and the monitoring voltage V rises above the allowable upper limit value. However, the monitoring voltage V also rises when a disconnection occurs in the wiring in the closed circuit other than the pair of conductive patterns 20.

  Therefore, the presence or absence of disconnection in the wiring in the closed circuit other than the pair of conductive patterns 20 can be determined as follows. Although not shown in FIG. 2, if the polarity to which the DC power supply 1 is applied is reversed, the diode 30 functions to cause conduction when the pair of conductive patterns 20 (conductive pattern 20 a) is torn due to heat generation. However, when the wiring is disconnected by a wiring other than the pair of conductive patterns 20 (conductive pattern 20a), there is no conduction. Therefore, the control unit 40 can determine the presence or absence of disconnection in the closed circuit other than the pair of conductive patterns 20 (conductive pattern 20a) from the conductive state when the polarity is reversed.

  Note that when there is a short-circuit portion in the wiring, the monitoring voltage V decreases, and the control unit 40 can also determine the presence or absence of a short-circuit from the monitoring result of the monitoring voltage V. In addition, by using a capacitor instead of the diode 30, it is possible to determine the presence or absence of disconnection. However, in the case of using a capacitor, the presence / absence of a disconnection is determined by applying an alternating current or a pulse, rather than applying a voltage whose polarity is reversed and confirming the presence / absence of the disconnection.

  In the above description, it has been described that the control unit 40 detects the presence or absence of heat generation of the solar panel by monitoring the monitoring voltage V. However, the monitoring voltage V may not be monitored, for example, the current is monitored. Such cases are also included in the technical scope of the present invention.

  As described above, according to the first embodiment, a sheet-like low-melting-point substrate that is printed with a conductive pattern and melts at a predetermined low-melting point is attached to a planar monitoring object (attachment). Equivalent to a step). Then, by monitoring the monitoring voltage at a specific location (corresponding to the voltage monitoring step), when the voltage between the conductive patterns is higher than the allowable upper limit voltage value, due to the heat generation of the monitoring object, It can be determined (corresponding to the heat generation detection step) that the conductive pattern is in a disconnected state by melting the base material 10 on the sheet. As a result, it is possible to realize a fire detection device and a fire detection method that can quickly detect heat generation of a planar monitoring target such as a solar panel using an inexpensive and simple configuration.

Embodiment 2. FIG.
In the first embodiment, the case where the disconnection due to heat generation is detected by monitoring the monitoring voltage between the patterns printed on the sheet-like low-melting-point substrate that melts at a predetermined low-melting point has been described. On the other hand, in the second embodiment, a pair of electric wires 21 or 22 having a coating of an insulating material having a low melting point is used, and the monitoring voltage V is monitored, so that a pair resulting from melting of the coating due to heat generation. The case where the short circuit of the electric wire is detected will be described.

FIG. 3 is an explanatory diagram of a sheet used in the fire detection device for detecting heat generation of the planar monitoring target in Embodiment 2 of the present invention. In the sheet used in the fire detection device according to the second embodiment, for example, a pair of electric wires 21a and 21b having a coating with an insulating material having a low melting point of about 100 to 200 ° C. is twisted, and there is always a slight force between the electric wires. It is comprised so that it may arrange | position on the base material 11 in the added state. Here, the base material 11 in the second embodiment does not need to be formed of a material that melts at a predetermined low melting point, unlike the base material 10 in the first embodiment.
Such a pair of electric wires 21 a and 21 b are arranged on one side of the base material 11 so as to cover the entire surface of the base material 11 and the electric wires of each other are twisted.

  The sheet shown in FIG. 3 can be cascade-connected by connecting the electric wires 21a and the electric wires 21b, respectively, similarly to the circuit configuration shown in FIG. Furthermore, a closed circuit composed of a plurality of cascade-connected sheets, a DC power source 1 and resistors 2 and 3 is configured, and the control unit 40 monitors fluctuations in the monitoring voltage V, thereby generating heat from the solar panel. The presence or absence of can be detected.

  Specifically, when abnormal heat generation of the panel occurs, since the melting point of the coating that is an insulating material is low, the wires 21a and 21b are short-circuited due to melting of the coating, and the monitoring voltage V is reduced. Therefore, the control part 40 can detect the heat_generation | fever of the solar panel which is a planar monitoring target object, when the monitoring voltage V falls from an allowable lower limit.

  In addition, as a specific wiring example for detecting a short circuit between a pair of electric wires by melting of the coating due to heat generation, other than those shown in FIG. FIG. 4 is an explanatory diagram of a sheet used in the fire detection device for detecting the heat generation of the planar monitoring object in the second embodiment of the present invention, and shows a wiring example different from the previous FIG. It is.

  In FIG. 4, instead of using the twisted wires, the horizontal electric wires 22a and the vertical electric wires 22b are knitted, and, as in the case of FIG. 3, the wires are applied with some force applied to each other. It is configured to be installed on the material 11.

  Even with such a configuration, the coating having a low melting point is melted due to abnormal heat generation of the panel, whereby the wires 22a and 22b are short-circuited and the monitoring voltage V is lowered. Therefore, the control part 40 can detect the heat_generation | fever of the solar panel which is a planar monitoring target object, when the monitoring voltage V falls from an allowable lower limit.

  As described above, according to the second embodiment, a sheet-like base material provided with a set of electric wires covered with a coating that melts at a predetermined low melting point is attached to a planar monitoring object ( It corresponds to the pasting step). Then, by monitoring the monitoring voltage at a specific location (corresponding to the voltage monitoring step), if the voltage between one set of wires is below the allowable lower limit voltage value during the voltage monitoring step, the monitoring target It can be determined that one set of electric wires is short-circuited due to melting of the coating of the electric wires on the sheet due to the heat generation of the object (corresponding to a heat generation detection step). As a result, it is possible to realize a fire detection device and a fire detection method that can quickly detect heat generation of a planar monitoring target such as a solar panel using an inexpensive and simple configuration.

  In the second embodiment, one set of electric wires 21 or 22 is provided as shown in FIG. 3 or FIG. 4, but any configuration that can detect a fire is acceptable, and the present invention is not limited to this configuration. For example, twisted wires (electric wires) (not shown) are arranged around the entire circumference or part of the circumference of each planar monitoring object (solar panel) or multiple planar monitoring objects (solar panel group). Should be provided. When a fire breaks out from a solar panel, it will generally fire from the back, but when a fire breaks out from the back of a solar panel, fire always comes out of the solar panel. It is sufficient to have a twist line around the panel. In this case, the base materials 10 and 11 as in the first and second embodiments are not necessary.

  In the second embodiment, the case where the coating is melted by heat and the electric wires 21a, 21b, 22a, and 22b are short-circuited has been described. However, the second embodiment is not limited thereto, and the electric wires 21a, 21b, 22a, A material whose insulation resistance value of the coating 22b decreases as the ambient temperature increases may be used.

Embodiment 3 FIG.
In this Embodiment 3, the method for detecting the presence or absence of the heat_generation | fever of a solar panel by the control part 40 is demonstrated based on a specific circuit. Here, a case where the electric wires 21a and 21b shown in FIG. 3 in the second embodiment are used will be described as an example.

  FIG. 5 is a circuit diagram of the fire detection apparatus according to Embodiment 3 of the present invention. More specifically, the control unit 40 monitors the heat generation state of the solar panel from the measurement result of the monitoring voltage V. It is a figure for demonstrating.

The controller 40 performs the following control in order to monitor the normal conduction state.
(Procedure 1) The control unit 40 switches the switch SW1 to be connected to a1, and switches the switch SW2 to be connected to d2.
(Procedure 2) After switching, the control part 40 can check the conduction | electrical_connection state of the electric wire 21a between a1-d2 by measuring the monitoring voltage V. FIG.
(Procedure 3) Similarly, the control unit 40 switches the switch SW1 to be connected to b1, and switches the switch SW2 to be connected to c2.
(Procedure 4) After switching, the control part 40 can check the conduction | electrical_connection state of the electric wire 21b between b1-c2 by measuring the monitoring voltage V. FIG.

  By performing such procedure 1 to procedure 4, when the control unit 40 can confirm the electrical connection state of the electric wires 21a and 21b, no disconnection occurs, and thus abnormal heat generation occurs in the solar panel. It can be judged that it is not.

Next, the control unit 40 performs the following control to monitor the disconnection state due to heat generation.
(Procedure 5) The control unit 40 switches the switch SW1 to be connected to a1, and switches the switch SW2 to be connected to b2.
(Procedure 6) After switching, the control part 40 can check the short circuit state of the electric wires 21a and 21b between a1-b2 by measuring the monitoring voltage V.
(Procedure 7) Similarly, the control unit 40 switches the switch SW1 to connect to c1, and switches the switch SW2 to connect to d2.
(Procedure 8) After switching, the control part 40 can check the short circuit state of the electric wire 21b and the electric wire 21b between c1-d2 by measuring the monitoring voltage V. FIG.

  By performing the procedure 5 to the procedure 8 described above, the control unit 40 can determine that abnormal heat is generated in the solar panel when the short-circuit state of the electric wires 21a and 21b can be confirmed.

  Note that the control unit 40 can estimate the resistance value of the wire between the switches SW1 and SW2 from the measurement result of the monitoring voltage V because the DC voltage Vcc and the resistances R1 and R2 of the DC power supply 1 are known. And the control part 40 calculates | requires the resistance value between a1-b2 and the resistance value between c1-d2 in the case of performing procedure 5-procedure 8, and obtains ratio of both, and it is a rough of a short circuit location. It is also possible to make a simple estimation.

  As described above, according to the third embodiment, the conduction state of each of the two electric wires and the short-circuit state between the two electric wires can be monitored by controlling the switch to monitor the monitoring voltage. . As a result, it is possible to realize a fire detection device and a fire detection method that can quickly detect the heat generation of a planar monitoring object such as a solar panel using an inexpensive and simple configuration.

Embodiment 4 FIG.
In the fourth embodiment, when abnormal heat generation occurs in a planar monitoring target using the sheet-like low melting point base material that melts at a predetermined low melting point described in the first embodiment. A structure in which the conductive pattern is more reliably broken will be described.

  FIG. 6 is an explanatory diagram of the configuration of the base material 10 and the first conductive pattern 20a in the fourth embodiment of the present invention. The base material 10 in this Embodiment 4 is comprised with the low melting-point base material (for example, resin sheet), and the some hole 10a is provided. And the 1st conductive pattern 20a is arrange | positioned so that between the some holes 10a may be sewn.

  By providing such a configuration, the low melting point base material 10 is easily torn when abnormal heat is generated in the planar monitoring target, so that the first conductive pattern 20a can be more reliably broken. Can do. In addition, by providing a plurality of holes 10a, the proportion of the first conductive pattern 20a in the low melting point base material 10 can be increased, and the tearing is reliably generated due to the effect of melting of the base material 10 due to heat. Is possible.

  As described above, according to the fourth embodiment, a plurality of holes are provided in the low melting point base material, and the conductive pattern is arranged so as to sew between the plurality of holes. As a result, by melting the low melting point base material, it becomes possible to induce the tearing of the conductive pattern more reliably and to improve the fire detection accuracy.

  DESCRIPTION OF SYMBOLS 1 DC power supply, 2, 3 resistance, 10 base material (base material which fuse | melts by low melting | fusing point), 10a several holes, 11 base material, 20 a pair of conductive pattern, 20a, 20b conductive pattern, 21, 22 1 set of electric wires , 21a, 21b, 22a, 22b Electric wire, 30 diode, 40 control unit.

Claims (4)

A fire detection device for detecting a heat generation state of a solar panel,
A set of electric wires disposed on the back surface of the solar panel or a plurality of solar panel groups, with a coating that melts at a predetermined low melting point;
Due to heat generation of the solar panel or a plurality of solar panel groups, the one set of electric wires is monitored to be short-circuited by melting the coating of the electric wires, and the solar panel or the plural solar panels A control unit for detecting the heat generation state of the solar panel group;
A fire detection device comprising: A fire detection device for detecting a heat generation state of a solar panel,
A set of electric wires provided with a coating that is disposed only around or around the solar panel or a plurality of solar panel groups, and melts at a predetermined low melting point;
Due to heat generation of the solar panel or a plurality of solar panel groups, the one set of electric wires is monitored to be short-circuited by melting the coating of the electric wires, and the solar panel or the plural solar panels A control unit for detecting the heat generation state of the solar panel group;
A fire detection device comprising: A switch for switching the connection so as to detect each conduction state of the one set of electric wires and a short circuit state between the electric wires of the one set of electric wires;
The said control part detects the heat_generation | fever state of the said solar panel by switching the said switch and monitoring the voltage between the electric wires in the connection state after switching, The Claim 1 or 2 characterized by the above-mentioned. The fire detection device described. The controller is
By the first switching control of the switch, the conduction state of the one set of electric wires is confirmed, and if it is the conduction state, it is determined that no abnormal heat is generated in the solar panel,
According to the second switching control of the switch, the short-circuit state of the one set of electric wires is confirmed, and in the short-circuit state, it is determined that abnormal heat generation is generated in the solar panel. The fire detection device according to claim 3.

Images