WO2016151250A1 - Energetically self-contained device for detecting forest fires and method for detecting forest fires implementing such a device - Google Patents

Abstract

The present invention relates to an energetically self-contained device for detecting forest fires, which comprises a component with shape memory, a piezoelectric component rigidly connected to the component with shape memory, and an electronic module capable of converting the electric energy produced by the piezoelectric component into a radio-frequency signal. The present invention also relates to a network for detecting forest fires comprising a plurality of detection devices according to the invention, as well as to a method for detecting forest fires implementing a detection device according to the invention or a detection network according to the invention.

Description

 DEVICE FOR DETECTION OF FOREST FIRES

 ENERGETICALLY AUTONOMOUS AND DETECTION METHOD

 FOREST FIRES USING SUCH A DEVICE.

The present invention relates to the field of devices and methods for detecting and alerting the beginnings of fires, including forest fires.

 More particularly, the present invention relates to an energy self-sustaining forest fire detection device, comprising a shape memory component (generally referred to as AMF) associated with a piezoelectric component for producing electrical power exploitable by a electronic module for transmitting a radio signal.

 By energetically autonomous device is meant a device that has the following properties:

 • it is a device that can operate without external energy supply for a long time (greater than one year) and over a significant distance (greater than 10 meters); this therefore excludes from the invention for example photovoltaic cells as a source of energy;

• it is a device that does not have an energy storage system in chemical (battery) or capacitive (capacitor) form.

Forest, for the purposes of the present invention, means more or less dense wooded areas, or areas with plant organisms likely to ignite.

Forest fire detection devices, known to those skilled in the art, rely on various more or less recent methods. The oldest is the watchtower that requires a watchman who must monitor the horizon on the lookout for a fire.

 Several documents describing fire detection devices are also known.

 French patent application FR 2614984 describes an optical system for detecting thermal radiation, intended to detect and locate forest fires in their initial phase. It is a device mounted on top of a mast, whose optical part includes mirrors, Fresnel lenses and infrared sensors.

 German patent application DE 4026676 discloses a device also mounted on a mast but using pyroelectric sensors.

 French patent FR 2637977 discloses a detector with infrared sensors for detecting infrared radiation from a heat source. Such a detector makes it possible to locate the position of a column of smoke. Such a device can be implemented for the detection of forest fires in a supervised area.

 The French patent application FR 2652269 describes a complex system for detecting, alerting and neutralizing fire starts, comprising a tank containing fire-extinguishing powder and an ejector able to project it on the flames, and a transmitter of Hertzian waves.

 French patent FR 2679779 describes an airborne detection method in which aircraft continuously scan the sensitive areas with thermal sensors.

US Pat. No. 5,218,345 describes a detection system using infrared cameras mounted on poles, which system being supported by a scanning system to improve detection.

 US Pat. No. 7,337,156 describes a method for the detection and the fight against forest fires, in which the detection is carried out by aerial surveillance using on-board infrared detectors. In this case, the innovative aspect is carried by the data analysis system.

 US Pat. No. 7,656,634 describes a device for detecting forest fires based on the chemical analysis of the atmosphere by optical spectroscopy.

 United States Patent Application US 2011/122245 discloses a forest fire control system comprising a network of optical and infrared scanners detectors mounted on towers. This control system makes it possible to detect fire starts and then to notify the emergency services.

 The US patent application US 2013/321149 describes a monitoring device based on remote systems equipped with cameras and infrared sensors and connected to a central that collects the data. These systems can be dropped for example from a helicopter and deployed over a wide area, including trees.

 The US patent application US 2014/192184 describes a method of interpreting measurements taken by the optical and infrared camera systems. Indeed, the climatic conditions, the very important surfaces to be watched, the topography of the places, the alternation day / night, the latitude and the longitude, the seasonal variations of climate, make the setting of these devices very complicated.

US Patent Application Serial No. 2002/026431 and International Publication WO 97/35433 describe a detection method based on the analysis and superimposition of data from infrared sensors placed on towers or airborne by aircraft, drones or satellites.

 French patent FR 2893743 describes a fire detection method, which is based on a network of sensors constituting a mesh of the area to be monitored. Each sensor has a fire detector and a radiofrequency transmitter connected to a central or control terminal. This system provides three to five sensors per hectare, each sensor being able to locally detect a fire. This system has a battery and an antenna that deteriorates over time, so that the signal can no longer be emitted.

 US patent application US 2011/122245 describes a fire control system installed in several wooded areas in France. This control system consists of a network of surveillance cameras on towers at 40 meters height. These cameras record around twenty 180-degree photos and these photos are transmitted to a powerful computer that analyzes and detects potential smoke plumes for up to 20 kilometers. The location is by triangulation and the accuracy is 300 meters.

 However, devices based on aerial or satellite surveillance have the disadvantage of being random because they depend on the frequency of passage of the equipment over the areas to be monitored, unless continuous surveillance is envisaged, which would make it a lot too expensive.

Moreover, devices based on terrestrial surveillance by optical and infrared cameras require expensive installation and very complex processing algorithms that need to take into account many parameters as mentioned previously in the description of the contents of US patent application US 2014/192184.

 Finally, devices based on a terrestrial sensor network have the main disadvantage that they must be powered by batteries requiring maintenance and regular change. In addition, the presence of this type of component in nature does not improve compliance with ecological criteria.

 None of these devices or systems known from the prior art are energetically autonomous within the meaning of the present invention.

 To solve the aforementioned defects and disadvantages, the applicant has developed an energy-autonomous forest fire detection device, comprising an electronic module (or transmitter) able to emit a radio signal from the energy produced by the device. himself. For this, the device comprises, besides the transmitter, a shape memory component (or AMF) associated with a piezoelectric component integral with said AMF component, the AMF component converting into a displacement and / or change of shape the heat received by a a source whose temperature is above a threshold temperature (in particular emitted by a fire), and the piezoelectric component converting the displacement and / or the change in shape of the AMF component into electrical energy.

 More particularly, the subject of the present invention is a device for detecting forest fires, characterized in that it constitutes an energy-independent assembly comprising:

A shape memory component (or AMF component) able to convert, in a displacement and / or a change of shape (and consequently in mechanical energy), the heat received by a source whose the temperature is higher than a threshold temperature (heat created for example by a fire);

 A piezoelectric component capable of converting the displacement and / or the change in shape of the AMF component into electrical energy, said piezoelectric component being integral with said AMF component; and

 An electronic module capable of converting the electrical energy produced by said piezoelectric component into a radio (or radio) signal to warn and give a fire warning.

 By threshold temperature is meant, in the sense of the present invention, a temperature which is:

 - in the order of 55 ° C in countries with a moderate climate (typically in Western Europe), or

 - in the order of 45 ° C, in cold countries or regions (typically Alaska or Siberia), or

 - of the order of 60-65 ° C in hot countries

(especially tropical or subtropical countries).

 For the purposes of the present invention, an assembly or device that is energetically autonomous means an assembly or device that can operate without requiring the use of a complementary energy source such as a battery, a battery, or a storage battery. energy. Indeed, the AMF component, by triggering from a certain temperature, representative of a fire departure, will provide sufficient energy to supply, via the piezoelectric component, a radio transmitter which will thus enable the sending a signal to a checkpoint.

In operation, when the device according to the invention detects a forest fire manifesting itself generally by a high temperature (for example of the order of 80 ° C) greater than the trigger temperature of the device according to the invention, this causes said AMF component to change shape and / or produce a displacement. This trip temperature can be selected (between 50 and 200 ° C) depending on the environmental parameters or safety criteria.

 As the piezoelectric component is, in the device according to the invention, integral with the AMF component, its displacement and / or shape change induces the displacement and / or the change of shape of the piezoelectric component. The latter converts it into electrical energy, which is itself converted into a radio signal by the electronic module. Thus, the displacement and / or change of shape of the AMF component, triggered from a certain threshold temperature representative of a fire start, provides sufficient energy to supply, via the piezoelectric element, a radio transmitter, which will thus allow the sending of a signal to a control station.

 When the device according to the invention is not solicited, it has the advantage of operating in "zero energy" mode, that is to say that it consumes no energy. It is a passive device. The device according to the invention can therefore operate for years without the need for maintenance or maintenance.

The device according to the invention therefore has three components: the AMF component which has the dual function of high temperature detector and energy generator, the piezoelectric component that converts mechanical energy into electrical energy, and the electronic module that converts the electrical energy produced in a radio signal used to warn and give a warning of starting fire. This signal includes the geographic coordinates or a identification number that allows you to instantly locate the fire. The signal is intended to be received by a computer system equipped with a radio receiver.

 This simple configuration allows the device according to the invention to be very compact (in other words conditioned in a small volume), easy to deploy, and much less expensive than previous devices.

 Advantageously, the device according to the invention is portable.

 Advantageously also, it is removable, even years after installation, which allows to remove the device when the tree or the plant on which it was fixed, must be exploited or transformed without risk of foreign material residue for wood .

AMF component

 The first component of the detection device is the AMF component. The AMF component can be of different shapes and made of different shape memory materials. This may advantageously be in the form of a wire, a tubular, a flat or a more complex component such as a spring.

 The shape memory component (generally referred to by the acronym AMF) consists of a shape memory alloy.

 As form-memory alloys that may be used in the context of the present invention, mention may notably be made of:

 • Copper-based alloys: CuAlBe, CuAlNi, CuAlMn, CuZnAl,

• Nickel-Titanium-based alloys: NiTi, NiTiFe, NiTiCu, NiTiCr, and • Iron-based alloys: FeMnSi, FeMnCr, FeMnCrSi.

 Some of these shape memory alloys may be monocrystalline, i.e., consist of a single grain or several grains separated by grain boundaries of low disorientation.

 As preferred AMF alloys that may be used in the context of the present invention, mention may be made of copper-based alloys CuAlBe, CuAlNi, and alloys based on nickel-titanium NiTi and NiTiCu, and is preferably the NiTi alloy.

Piezoelectric component

 The second component of the detection device according to the invention is the piezoelectric component.

 Piezoelectricity is the property that some bodies have to be electrically polarized under the action of a mechanical stress, and conversely to deform when an electric field is applied to them. The two effects are inseparable. The first is called direct piezoelectric effect, while the second piezoelectric inverse effect.

 The piezoelectric component of the device according to the invention may be a piezoelectric cell or a piezoelectric composite comprising a plurality of piezoelectric cells.

 Advantageously, the piezoelectric component of the device according to the invention may be a composite comprising piezoelectric cells assembled and fixed between two layers of polymers, electrically insulating, identical or different.

The piezoelectric component in the form of a composite may comprise conductive strips interposed between the polymer layers, to allow the transfer of the electric current. The piezoelectric materials that can be used in the context of the present invention to constitute the piezoelectric component can be of different natures. The most known piezoelectric material is quartz, still used today in watches to create clock pulses. But it is the synthetic ceramics, the PZTs (Titano-Lead Zirconate) which are the most widely used today in the industry.

 In the context of the present invention, piezoelectric cells made of titanium lead zirconate will preferably be used.

Electronic module.

 The electronic module and the radio transmitter convert the electrical energy produced by the piezoelectric component into a radio signal for warning and giving a fire warning.

 This signal includes geographic coordinates or an identification number that allows to instantly locate the fire. The signal is received by a computer system and transmitted to a radio receiver (control station). The range of the transmitted signal can be from several hundred meters to several kilometers, which makes it possible to configure a network of detectors whatever the configuration of the terrain.

 Relay stations can be used to relay the signal to a central station and thus increase the area under surveillance. The accuracy of location is of the order of one meter and depending on the density of detectors installed in an area, the reaction time and intervention can be much lower than previous solutions.

Thus, the present invention also relates to a forest fire detection network comprising a plurality of forest fire detection devices. according to the invention, wherein each device is arrangedaccording to a mesh depending on the nature of the ground to be protected and the risk of fire, the position of each device being recorded so as to allow the rapid location of a fire departure.

 In the network according to the invention, the distance between each detection device according to the invention that constitutes it can be chosen according to the nature of the terrain and the risk of fire.

 In an advantageous variant of the device according to the invention, it may further comprise an arming system and / or a visual device adapted to verify that the detection device is operational. The device according to the invention can be used with automatic and / or visual arming system when fixing the detector on the plant or on the surface of the ground.

 In yet another advantageous variant of the invention, the device according to the invention may further comprise a fixing device of the screw or nail type to be able to fix it on the trunk of a tree or shrub without hindering its growth. It can also be glued directly on the plant.

 In yet another advantageous variant of the invention, the device according to the invention may further comprise a foot for planting it directly into the ground if the vegetation is small.

 In yet another variant, there is added a suspension system allowing the detector to be suspended from the branch of a tree or shrub.

The cost of a device or a network of devices according to the invention is lower than the cost of previous solutions, which allows to consider a use of these systems in less developed countries but having great natural resources to protect. Finally, the subject of the present invention is also a method for detecting forest fires using the detection device according to the invention or the network according to the invention comprising a plurality of detection devices, said method comprising the following steps :

 • reaching a threshold temperature leads (100) said AMF component to change shape and / or to produce a displacement;

 • this change of shape and / or displacement of the AMF causes the change of shape and / or the displacement (200) of the piezoelectric component;

Said piezoelectric component integral with the AMF component converts (300) its displacement and / or its deformation into electrical energy; and

The electrical energy produced by said piezoelectric component is converted (400) by said electronic module into a radio signal.

Other advantages and features of the present invention will result from the description which follows, given by way of nonlimiting example and with reference to the appended figures:

 FIG. 1 represents a typical temperature-stress diagram of a shape memory alloy;

 FIG. 2 is an illustration of the shape memory effect in the particular case of a shape memory alloy spring;

FIG. 3 represents a description of the energy conversion resulting from the heat of the flames by the device according to the method according to the invention, leading to generate a radio signal; FIG. 4 represents a side perspective view of a first example of a device according to the invention composed of round AMF wires integral with a piezoelectric composite;

 FIG. 5 represents a side perspective view of a second example of a device according to the invention composed of AMF ribbons integral with a piezoelectric composite;

 FIG. 6 represents a sectional view of each of the devices according to the invention illustrated respectively in FIGS. 4 and 5;

• Figure 7 schematically illustrates the operating mode of a device according to the invention.

FIG. 1 is a schematic diagram of the typical stress-temperature of a shape memory alloy (AMF) for understanding the properties of these alloys.

 Shape memory alloys (AMF) are metal alloys with special properties: shape memory effect and superelasticity mainly. These properties are the macroscopic result of a microscopic phase change, called martensitic transformation. Under the effect of a stress or an increase in temperature or both, the atomic structure of the alloy is modified and results in a shape change in the case of shape memory effect, and a very large reversible elastic deformation in the case of superelasticity.

Figure 1 shows that the domain D _T of the martensitic transformation (in gray in the figure) varies according to the temperature (abscissa) and the constraint (ordinate). The domain D _T is situated between two oblique lines, called transition temperatures, which constitute the beginning and the end of the martensitic transformation of the material. These oblique lines separate the two phase domains, austenite on the right and martensite on the left. Depending on whether you are cooling or heating, these lines are different:

thus, at zero stress, at cooling, the beginning of the direct transformation is named M _s (for "Martensite Start" in English) and the end of the transformation is named M _f (for "Martensite Finish"),

while at heating, always at zero stress the beginning of the inverse transformation is named A _s (Austenite Start) and the end of the transformation is named A _f (Austenite Finish),

FIG. 1 shows that the temperature As (in heating, beginning of the formation of austenite in martensite) is higher than the temperature Mf (in cooling, end of the transformation of the austenite in martensite), and that the temperature Af (in heating, end of the transformation of martensite into austenite) is greater than the temperature Ms (in cooling, beginning of the transformation of the austenite in martensite). When a material is to the right of the D _T domain (point A) and is stressed (point B), the deformation generated within the material is completely reversible when the stress is released. This is the superelastic effect.

When a material is to the left of the D _T domain (point C) and is stressed (point E), it remains deformed after the relaxation of the stress. This same deformed material, if it is heated beyond the domain D _T (point F), will return to its original shape. This is the shape memory effect. In the context of the present invention, the AMF component of the detection device according to the invention uses the shape memory effect.

 FIG. 2 represents an illustration of the shape memory effect: a shape memory alloy spring initially of length LO is subjected to a mass M1. It is deformed under the effect of the force exerted by this mass at room temperature to a position Ll. If the temperature increases, the component returns to its original form LO. In the case of the invention, this change of shape is not reversible automatically.

 FIG. 3 represents a description of the energy conversion resulting from the heat of the flames by the device according to the method according to the invention:

 • step 100:

 a fire is triggered in a given area and reaching a threshold temperature causes the shape memory component to change shape and / or produce a displacement;

 • step 200:

 this change of shape and / or displacement of the shape memory component induces the shape change and / or the displacement of the piezoelectric component;

 • step 300:

 this piezoelectric component integral with the shape memory component converts its displacement and / or its deformation into electrical energy; and

 • step 300

the electrical energy produced by said piezoelectric component is converted by the electronic module into a radio signal. FIGS. 4 and 6 (top of FIG. 6) show an example of a device (or detector) according to the invention comprising AMF round wires 2 integral with a piezoelectric composite 3. This composite 3 comprises piezoelectric cells 31 interconnected by electrical conductors (not shown in the figures). The piezoelectric cells 31 are assembled and fixed between two polymer layers 32.

 FIG. 5 and FIG. 6 (bottom of FIG. 6) also illustrate an example of device 1 (or detector) according to the invention, which differs from that of FIG. 4, in that the AMF component 2 is presented in FIG. form of flat bands 2.

 Figure 7 illustrates the operation of a detector according to the invention. The AMF components are preconditioned (armed) at normal room temperature before being placed on the piezoelectric composite, i.e. the round wires or ribbons are stretched before being attached to the piezoelectric composite. During a fire departure and therefore a significant increase in temperature, the AMF son return to their original shape [a priori LO] and thus change the shape of the piezoelectric composite. This change of shape causes the generation of an electric current. This electrical energy will be exploited by the electronic module (transmitter) to emit a radio signal.

 The following example illustrates the invention without limiting its scope. EXAMPLE 1

An example of a device according to the invention consists of a waterproof casing made of biodegradable polymer, comprising inside a piezoelectric composite on which is bonded strips (ribbons) nickel-titanium (NiTi). These NiTi strips are previously packaged (stretched).

 In the case, the piezoelectric composite provided with its NiTi strips is electrically connected to an electronic module converting the signal of the piezoelectric element into a radio signal.

 The housing of the device comprises a pre-drilled hole by which is inserted a screw which will serve to fix the device on the trunk of a tree. The fixing device, at the insertion of the screw, automatically records the GPS coordinates of the fixing location together with the identification number. This data is then transmitted to the dedicated software, which records all the identification numbers of the boxes coupled to their GPS coordinates.

 In the case of a fire, the increase of the temperature within the housing leads to the resumption of shape of the NiTi ribbons. The bands find their initial form shorter. In doing so, the piezoelectric element will generate, due to its deformation, an electrical signal transmitted to the electronic module.

 The signal transmitted before the destruction of the housing by the flames contains information such as the identification number of the housing. This unique identification number allows the receiving station located at a distance of eg 5 kilometers to instantly identify the device that has tripped and to transpose the identification number into GPS coordinates, viewable on a computer screen . The dedicated software can also automatically prevent backups.

Claims

1) Device (1) for detecting forest fires, characterized in that it constitutes an energy-autonomous assembly comprising:

 A shape memory component (2) able to convert the heat received by a source whose temperature is greater than a threshold temperature into a displacement and / or a change of shape,

 A piezoelectric component (3) capable of converting the displacement and / or the shape change of the shape memory component into electrical energy, said piezoelectric component being integral with said shape memory component and

An electronic module capable of converting the electrical energy produced by said piezoelectric component (3) into a radio signal to warn and give a fire departure alert.

2) Device (1) according to claim 1, characterized in that it is portable. 3) Device (1) according to claims 1 or 2, wherein said shape memory component (2) is selected from CuAlBe copper alloys, CuAINi and NiTi NiTiCu and NiTiCu-based alloys, and is preferably the NiTi alloy.

4) Device (1) according to any one of claims 1 to 3, wherein said piezoelectric component (3) is a piezoelectric cell or a piezoelectric composite comprising a plurality of piezoelectric cells.

5) Device (1) according to claim 4, wherein the piezoelectric cell or cells are titanium lead zirconate.

6) Device (1) according to claims 4 or 5, wherein said piezoelectric component (3) is a composite comprising piezoelectric cells (31) assembled and fixed between two layers of polymers (32) electrically insulating, the same or different.

7) Device (1) according to any one of claims 1 to 6, further comprising an arming system and / or a visual device adapted to verify that said detection device is operational.

8) A forest fire detection network comprising a plurality of forest fire detection devices (1) as defined in any one of claims 1 to 7, wherein each device (1) is arranged according to a mesh depending on the nature of the land to be protected and the risk of fire, the position of each device (1) being recorded so as to allow the rapid location of a fire departure.

9) A method for detecting forest fires using the detection device (1) as defined in any one of claims 1 to 7 or the network as defined in claim 8, said method comprising the following steps :

• reaching a threshold temperature leads (100) said shape memory component (2) to change shape and / or to produce a displacement; This shape change and / or displacement of the shape memory component (2) causes the shape change and / or displacement (200) of the piezoelectric component;

 Said piezoelectric component (3) integral with the shape memory component (2) converts (300) its displacement and / or its deformation into electrical energy; and

 The electrical energy produced by said piezoelectric component (3) is converted (400) by said electronic module into a radio signal.