EP3494560B1 - Detector of smoke, gas or particles; system and method for detecting smoke, gas or particles - Google Patents

Description

TECHNICAL FIELD OF THE INVENTION

The present invention relates to a smoke, gas or particle detector, a method for detecting smoke, gas or particles and a smoke, gas or particle detection system. It applies, in particular, to the security of property and people.

STATE OF THE ART

• les détecteurs ponctuels,
• les détecteurs linéaires et
• les détecteurs multi-ponctuels par aspiration.

There are mainly three types of smoke, gas or particle detectors:

• point detectors,
• linear detectors and
• multi-point detectors by suction.

For each of them, detection is based on the optical principle of light scattering and / or absorption by smoke, gas or particles. The measurement of these physical phenomena allows the detection of smoke, gas or particles and therefore the presence of a risk nearby.

For point and linear detectors, the sample of smoke, gas or particles on which the detection is carried out is passively transported to the detector. The air is set in motion by natural convection, due to temperature differences in the environments to be protected. These air movements are sometimes supplemented by air currents associated with the presence of people or machines. In case of high ceilings (above 12 meters), a layer of hot air can form under the ceiling, under the action of the Foal effect, thus preventing the arrival of smoke, gas or particles to the detector, which can make it inoperative.

For multi-point detectors by suction, a suction device, via a fan, actively draws air from a network of tubes punctuated by multiple capture orifices, towards a centralized optical detection device. Each hole capture thus plays a role analogous to that of a point detector. The gas or the particles can be sampled by several capture orifices thus increasing the sensitivity of the detection.

However, the installation of these multi-point detectors requires a significant installation of a network of suction pipes. In addition, the detection unit has large dimensions, which generally requires a dedicated room. The fouling of the housing requires interventions made complex according to the positioning of the housing. These multi-point detectors are therefore both expensive and complicated to install.

In addition, certain low volume applications to be analyzed do not justify the cost of such an installation.

Finally, in current systems, it is impossible to determine which orifice comes the smoke, gas or particles detected by the detector.

Systems such as described in the document are known in particular WO 2013/182822, published December 12, 2013 .

Systems are also known as described in the document. WO 2010/100549, published September 10, 2010 .

Systems are also known as described in the document. EP 2,320,398, published May 11, 2011 .

Systems are also known as described in the document. EP 0 638 885, published on February 15, 1995 .

However, none of these systems allows optimal detection.

OBJECT OF THE INVENTION

The present invention aims to remedy all or part of these drawbacks.

• une chambre de détection reliée à un dispositif d'aspiration et à une ouverture permettant le passage d'un flux d'air et de particules ou de gaz,
• un moyen de ségrégation de particules traversant l'ouverture et/ou de rétention de particules dans la chambre,
• un détecteur de présence de fumée, de gaz ou de particules dans la chambre de détection et
• un émetteur d'un signal représentatif de la détection de fumée, de gaz ou de particules dans la chambre de détection.

To this end, according to a first aspect, the present invention relates to a smoke, gas or particle detector, which comprises:

• a detection chamber connected to a suction device and to an opening allowing the passage of a flow of air and of particles or of gas,
• a means for segregating particles passing through the opening and / or for retaining particles in the chamber,
• a detector for the presence of smoke, gas or particles in the detection chamber and
• a transmitter of a signal representative of the detection of smoke, gas or particles in the detection chamber.

These embodiments make it possible to extend the time spent by the air in the detection chamber, so as to improve reliability.

In embodiments, the detector object of the present invention comprises a capillary, fixed to the opening, offset the opening, relative to the micro-pump, of a predetermined length of capillary.

These embodiments allow the air suction point to be offset, in particular in the case where the layer of air in place under the action of the foal effect is of considerable thickness.

In embodiments, the capillary has a plurality of openings. In embodiments, the capillary has a "T" shape.

In embodiments, the retention means is formed by an interior volume of the chamber configured so that a flow of aspirated air forms a vortex, between an inlet and an outlet of said chamber, to increase the time of occupancy of smoke particles in the room.

In embodiments, the chamber has the shape of a cylinder of revolution, the inlet being positioned so that the flow enters the chamber in a direction tangential to the lateral periphery of the cylinder.

These embodiments make it possible to extend the time spent by the air in the detection chamber, so as to improve reliability.

In embodiments, the chamber includes fins for guiding the air flow from the inlet to the outlet.

These embodiments make it possible to extend the time spent by the air in the detection chamber, so as to improve reliability.

In embodiments, the outlet is positioned perpendicular to the air flow in the chamber when positioning the outlet.

These embodiments make it possible to extend the time spent by the air in the detection chamber, so as to improve reliability.

In embodiments, the segregation means includes a virtual impactor upstream of the opening.

In embodiments, the segregation means includes an impactor upstream of the opening.

In embodiments, the air suction device is protected by a filter limiting its fouling.

• au moins un détecteur de fumée, de gaz ou de particules objet de la présente invention et
• une centrale d'alarme comportant :
  • un récepteur d'un signal émis par chaque détecteur et
  • un moyen de transmission d'une information représentative de la détection de fumée, de gaz ou de particules par au moins un détecteur.

According to a second aspect, the present invention relates to a smoke detection system, which comprises:

• at least one smoke, gas or particle detector object of the present invention and
• an alarm center comprising:
  • a receiver of a signal emitted by each detector and
  • a means of transmitting information representative of the detection of smoke, gas or particles by at least one detector.

The aims, advantages and particular characteristics of the system object of the present invention being similar to those of the detector object of the present invention, they are not repeated here.

• une micro-pompe pour aspirer de l'air, vers une chambre de détection, à travers une ouverture,
• un détecteur de présence de gaz ou de particules dans la chambre de détection et
• un émetteur d'un signal représentatif de la détection de gaz ou de particules dans la chambre de détection,

la micro-pompe, la chambre de détection, le détecteur et l'émetteur étant embarqués dans un boîtier commun, l'ouverture ouvrant à l'extérieur du boîtier.According to a third aspect, the present invention relates to a gas or particle detector, which comprises:

• a micro-pump for sucking air, towards a detection chamber, through an opening,
• a detector for the presence of gas or particles in the detection chamber and
• a transmitter of a signal representative of the detection of gases or particles in the detection chamber,

the micro-pump, the detection chamber, the detector and the transmitter being embedded in a common housing, the opening opening outside the housing.

These provisions make it possible to benefit from an active means of moving air, increasing the reliability of the point detector in a manner comparable to that of a multi-point detector and limiting the harmful consequences of the foal effect, combined with the ease of installation of a point detector.

In embodiments, the micro-pump is a micro-pump with electrostatic actuation.

These embodiments make it possible to produce a miniaturized pump aspirating a small, but sufficient, quantity of air to perform the detection.

In embodiments, the micropump is a piezoelectric membrane micropump.

These embodiments make it possible to produce a miniaturized pump aspirating a small, but sufficient, quantity of air to carry out the detection.

In embodiments, the detector object of the present invention comprises means for measuring the air flow sucked by the micropump.

These embodiments make it possible to determine a level of fouling of the micro-pump.

In embodiments, the detector object of the present invention comprises a means of communication of a signal as a function of the measured air flow.

These embodiments make it possible to communicate, to a third-party device, the measured flow rate or an alert signal representative of an abnormal flow rate of the micropump.

In embodiments, the flow measurement means comprises a sensor of a vibration frequency of the membrane of the micropump and a means of determining a value of flow as a function of the vibration frequency picked up.

These embodiments make it possible not to use additional external means to determine the value of the flow rate.

In embodiments, the means for measuring the flow comprises a vibration amplitude sensor of the piezoelectric membrane and a means for determining a value of the flow as a function of the amplitude of vibration detected.

These embodiments make it possible not to use additional external means to determine the value of the flow rate.

In embodiments, the means for measuring the flow comprises a thermistor and a means for determining a value of the flow as a function of a value of the sensed resistance.

In embodiments, the means for measuring the flow is a flow meter.

• un émetteur de lumière,
• un récepteur de lumière, sensible pour au moins une partie des longueurs d'onde des rayons lumineux émis par l'émetteur,
• un premier réflecteur de lumière en regard de l'émetteur pour diriger la lumière émise par l'émetteur vers une zone de détection dans la zone de diffusion et
• un deuxième réflecteur de lumière en regard du récepteur pour diriger, en présence de gaz ou de particules dans la zone de diffusion, la lumière diffusée en provenance de ladite zone de détection, vers le récepteur.

In embodiments, the detector comprises:

• a light emitter,
• a light receiver, sensitive for at least part of the wavelengths of the light rays emitted by the transmitter,
• a first light reflector facing the emitter to direct the light emitted by the emitter to a detection zone in the diffusion zone and
• a second light reflector facing the receiver for directing, in the presence of gases or particles in the diffusion area, the light scattered from said detection area, towards the receiver.

In embodiments, the first reflector and / or the second reflector is an optical prism.

These embodiments make it possible to improve the signal-to-noise ratio by high focusing on a chosen area. In addition, these embodiments allow automation in the manufacturing process.

In embodiments, the shape of an interior volume of the chamber is configured so that a flow of sucked air forms a vortex, between an inlet and an outlet of said chamber, to increase the occupation time of the gas. or particles in the room.

These embodiments make it possible to extend the time spent by the air in the detection chamber, so as to improve reliability.

In embodiments, the chamber has the shape of a cylinder of revolution, the inlet being positioned so that the flow enters the chamber in a direction tangential to the lateral periphery of the cylinder.

In embodiments, the chamber includes fins for guiding the air flow from the inlet to the outlet.

In embodiments, the outlet is positioned perpendicular to the air flow in the chamber when positioning the outlet.

In embodiments, the detector object of the present invention comprises a virtual impactor upstream of the chamber.

• une étape d'aspiration d'air, par une micro-pompe, à travers une ouverture d'un boîtier vers une chambre de détection positionnée à l'intérieur du boîtier,
• une étape de détection de présence de gaz ou de particules dans une chambre de détection positionnée à l'intérieur du boîtier et
• une étape d'émission d'un signal représentatif de la détection de gaz ou de particules dans la chambre de détection, par un émetteur positionné à l'intérieur du boîtier.

According to a fourth aspect, the present invention relates to a method for detecting gases or particles, which comprises:

• an air suction step, by a micro-pump, through an opening of a housing towards a detection chamber positioned inside the housing,
• a step of detecting the presence of gas or particles in a detection chamber positioned inside the housing and
• a step of transmitting a signal representative of the detection of gas or particles in the detection chamber, by an emitter positioned inside the housing.

The aims, advantages and particular characteristics of the method which is the subject of the present invention being similar to those of the detector which is the subject of the present invention, they are not repeated here.

BRIEF DESCRIPTION OF THE FIGURES

• la figure 1 représente, schématiquement, un mode de réalisation particulier du détecteur objet de la présente invention,
• la figure 2 représente, schématiquement, une première vue d'un mode de réalisation particulier de la chambre d'aspiration,
• la figure 3 représente, schématiquement, une deuxième vue d'un mode de réalisation particulier de la chambre d'aspiration,
• la figure 4 représente, schématiquement et sous forme d'un logigramme, une succession d'étapes particulière du procédé objet de la présente invention,
• la figure 5 représente, schématiquement, un mode de réalisation particulier du système objet de la présente invention,
• la figure 6 représente, schématiquement, un mode de réalisation particulier du détecteur objet de la présente invention,
• la figure 7 représente, schématiquement, un mode de réalisation particulier du détecteur objet de la présente invention,
• la figure 8 représente, schématiquement, un mode de réalisation particulier du détecteur objet de la présente invention,
• la figure 9 représente, schématiquement, un mode de réalisation particulier du détecteur objet de la présente invention,
• la figure 10 représente, schématiquement, un mode de réalisation particulier du détecteur objet de la présente invention,
• la figure 11 représente, schématiquement, un mode de réalisation particulier du détecteur objet de la présente invention,
• la figure 12 représente, schématiquement, un mode de réalisation particulier du détecteur objet de la présente invention,
• la figure 13 représente, schématiquement, un mode de réalisation particulier du détecteur objet de la présente invention et
• la figure 14 représente, schématiquement, un mode de réalisation particulier du détecteur objet de la présente invention.

Other advantages, aims and particular characteristics of the invention will emerge from the following non-limiting description of at least one particular embodiment of the detector, of the system and of the method which are the subject of the present invention, with reference to the accompanying drawings, wherein :

• the figure 1 shows, schematically, a particular embodiment of the detector object of the present invention,
• the figure 2 shows schematically a first view of a particular embodiment of the suction chamber,
• the figure 3 schematically represents a second view of a particular embodiment of the suction chamber,
• the figure 4 represents, diagrammatically and in the form of a logic diagram, a succession of particular steps of the method which is the subject of the present invention,
• the figure 5 schematically represents a particular embodiment of the system which is the subject of the present invention,
• the figure 6 shows, schematically, a particular embodiment of the detector object of the present invention,
• the figure 7 shows, schematically, a particular embodiment of the detector object of the present invention,
• the figure 8 shows, schematically, a particular embodiment of the detector object of the present invention,
• the figure 9 shows, schematically, a particular embodiment of the detector object of the present invention,
• the figure 10 shows, schematically, a particular embodiment of the detector object of the present invention,
• the figure 11 shows, schematically, a particular embodiment of the detector object of the present invention,
• the figure 12 shows, schematically, a particular embodiment of the detector object of the present invention,
• the figure 13 shows schematically a particular embodiment of the detector object of the present invention and
• the figure 14 shows schematically a particular embodiment of the detector object of the present invention.

DESCRIPTION OF EXAMPLES OF EMBODIMENT OF THE INVENTION

This description is given without limitation, the invention is defined by the claims.

We note now that the figures are not to scale.

It will be noted, as of now, that the embodiments described below are suitable for both smoke detection and the detection of particular gases or particles.

It is recalled that smoke can be defined as all of the solid particles and gases emitted by the ashes from the combustion reaction, or by mechanical heating. Particles and gases are mainly derived from carbon.

It will be recalled that the particles can be defined as a set of aggregates of solid matter in suspension, ranging in size from a nanometer to a fraction of a millimeter, for example obtained by the combustion reaction or by mechanical heating.

It is recalled that the gas can be defined as a set of atoms, molecules or ions very weakly linked and which can be considered as independent. In the gaseous state, matter does not have its own form or volume.

We call "vortex", a region of a fluid in which the flow is mainly a rotational movement around an axis, straight or curved.

• une micro-pompe 105 pour aspirer de l'air, vers une chambre 110 de détection, à travers une ouverture 135,
• un détecteur 115 de présence de fumée dans la chambre de détection et
• un émetteur 120 d'un signal représentatif de la détection de fumée dans la chambre de détection, la micro-pompe 105, la chambre 110 de détection, le détecteur 115 et l'émetteur 120 étant embarqués dans un boîtier 125 commun, l'ouverture 130 ouvrant à l'extérieur du boîtier 125.

We observe, on the figure 1 , which is not to scale, a schematic view of an embodiment of the detector 100 object of the present invention. This smoke detector 100 includes:

• a micro-pump 105 for sucking air, towards a detection chamber 110, through an opening 135,
• a smoke detector 115 in the detection chamber and
• a transmitter 120 of a signal representative of the smoke detection in the detection chamber, the micro-pump 105, the detection chamber 110, the detector 115 and the transmitter 120 being embedded in a common housing 125, the opening 130 opening to the outside of the housing 125.

The micro-pump 105 is, for example, a micro-pump 105 with a piezoelectric membrane encapsulated in a particular geometry. The oscillation of a piezoelectric pellet attached to a membrane confers a pumping cycle in two stages. Initially, the air is mainly sucked in through the inlet port, then in a second step, the air is mainly expelled through the outlet port. Thus, by applying an alternating electrical voltage to the membrane, the membrane vibrates, creating a movement of air passing through the orifices of said encapsulation.

• à activation électrostatique,
• à activation électromagnétique,
• à activation thermo-pneumatique,
• à changement de phase,
• bimétallique,
• un alliage à mémoire de forme,
• à film polymère,
• un moteur à courant continu,
• un moteur à courant alternatif, universel, synchrone ou asynchrone ou
• un moteur sans balais (« brushless », en anglais).

In variants, the micro-pump 105 is:

• with electrostatic activation,
• with electromagnetic activation,
• thermo-pneumatic activation,
• phase change,
• bimetallic,
• a shape memory alloy,
• with polymer film,
• a DC motor,
• an AC, universal, synchronous or asynchronous motor or
• a brushless motor.

This micro-pump 105 makes it possible to draw air outside the housing 125 to transport it to the detection chamber 110. This detection chamber 110 is a volume configured to retain a predetermined quantity of sucked air. Smoke detection is carried out by the detector 115 on the basis of the air contained in this chamber 110 at a given time.

This air micro-pump 105 can vary in position relative to the detection chamber 110. Thus, in certain variants, the micro-pump 105 is positioned downstream of the chamber 110, on the air path, the surrounding air being sucked through the chamber 110. In other variants, such as that shown in figure 10 , the micro-pump 105 is positioned upstream of the chamber 110, on the air path, the surrounding air being pushed out of the detector 100, creating an air movement at the level of the chamber 110.

In particular embodiments, the micro-pump 105 operates intermittently.

The detector 115 is, for example, an optical smoke detector (with Tyndall effect or extinction), an ionization detector, with electric discharges, or with a thermionic or photoelectric source, a thermal detector or a thermo-velocimetric detector. As all of these types of detectors are widely described in the reference literature in the field of fire safety, their operation is not repeated here.

The detector 115 is configured to perform a point detection, on receipt of a detection command issued by an external device, or periodic, according to a predetermined period, variable or modifiable by a command issued by an external device.

This detector 115 performs the detection in the detection chamber 110.

In embodiments, the detector 100 includes means 160 for measuring the air flow sucked in by the micro-pump 105.

This measuring means 160 can also measure a relative flow rate with respect to a predetermined nominal flow rate, this nominal flow rate corresponding to a correct, or initial, operating state of the micropump 105.

In embodiments, such as that shown in figure 6 , this means 160 for measuring the air flow rate comprises a sensor 170 of a value of the capacitance of a piezoelectric crystal 106 implemented by the micro-pump 105 and a means 171 for determining a value of the flow rate function of the capacitance value received.

The sensor 170 measures, for example, the voltage across a piezoelectric crystal to determine if the micro-pump has failed, since a zero voltage across the piezoelectric crystal prevents the micro-pump from operating.

If this value is equal to the nominal capacitance value determined, the determination means 170 determines that the flow rate of the micro-pump 105 is correct.

If this value is too different from the nominal capacitance, the determination means 170 determines that the flow rate of the micro-pump 105 is incorrect and less than the nominal flow rate.

The determination means 171 is, for example, an electronic calculation circuit.

In embodiments, such as that shown in figure 7 , the means 160 for measuring the flow comprises a sensor 172 of a vibration frequency of the membrane 107 of the micro-pump and a means 173 for determining a value of the flow as a function of the vibration frequency picked up.

The sensor 172 is formed, for example, of a synchronous counter and of a comparator associated with a microcontroller for controlling the membrane 107.

If the measured frequency is close to the nominal oscillation frequency, measured or determined, of the piezoelectric membrane of the micro-pump, the determination means 173 determines that the flow rate of the micro-pump 105 is correct.

If this frequency is too different from the nominal frequency, the determination means 173 determines that the flow rate of the micro-pump 105 is incorrect and less than the nominal flow rate.

The determination means 173 is, for example, a configured electronic calculation circuit.

In embodiments, such as that shown in figure 8 , the means 160 for measuring the flow comprises a thermistor 174 and a means 175 for determining a value of the flow as a function of a value of the sensed resistance.

The flow value is captured, for example, by an ohmmeter connected to the terminals of the thermistor. The relationship between resistance and temperature is given by the Steinhart-Hart formula.

The resistance is measured here and, by the Steinhart-Hart formula, we deduce the temperature.

If the resistance measured is close to the resistance measured during nominal operation of the micro-pump, the determination means 175 determines that the flow rate of the micro-pump 105 is correct.

If this value is too different from the nominal resistance, the determination means 175 determines that the flow rate of the micro-pump 105 is incorrect and less than the nominal flow rate.

The determination means 175 is, for example, an electronic calculation circuit.

In embodiments, such as that shown in figure 9 , the means 160 for measuring the flow rate is a flow meter.

This flow meter is positioned upstream or downstream of the micro-pump 105 on the air path generated by the operation of this micro-pump 105.

In embodiments, such as that shown in figure 10 , the means 160 for measuring the flow comprises a sensor 176 of the amplitude of vibration of the piezoelectric membrane and a means 177 of determining a value of the flow as a function of the amplitude of vibration sensed.

The amplitude sensor 176 is, for example, an electrical circuit connected to an output, called “self-drive feedback” of the piezoelectric crystal of the membrane 107, this output providing a signal representative of this amplitude.

If the amplitude measured is close to the nominal oscillation amplitude, measured or determined, of the piezoelectric membrane of the micro-pump, the determination means 177 determines that the flow rate of the micro-pump 105 is correct.

If this amplitude is too different from the nominal value, the determination means 177 determines that the flow rate of the micro-pump 105 is incorrect and less than the nominal flow rate.

The determination means 177 is, for example, an electronic calculation circuit.

One of the advantages of knowing the flow rate is the determination of a breakdown or defect of the micro-pump 105 which may be due to fouling.

In embodiments, such as that shown in figure 1 , the detector 100 includes a means 165 for communicating a signal as a function of the measured air flow.

The communication means 165 is, for example, an electronic circuit for controlling a wired or wireless link connecting the detector 100 to a third-party device.

In variants, the communication means 165 implements an Ethernet port.

In variants, the communication means 165 implements a wireless antenna configured to operate according to the IEEE 802.11 standard, called Wi-Fi.

In variants, the communication means 165 implements a wireless antenna configured to implement spread spectrum transmission technology, such as LoRa (registered trademark) technology.

In variants, the communication means 165 implements a narrowband radio technology or a short-range wireless technology of the Bluetooth Low Energy type.

In variants, the communication means 165 is an indicator light or a loudspeaker configured to emit a visual and / or audible signal.

In variants, the communication means 165 and the transmitter 120 are combined.

The signal communicated is, for example, a measured flow value or information representative of the presence or not of a fault or a breakdown at the micro-pump 105 as a function of the comparison of the measured flow value and of a determined limit value.

In variants, the detector 115 also comprises an additional detector of monoxide, carbon dioxide or any other chemical species of interest according to the desired application of the detector 100.

In variants, the detector 100 is adapted to detecting gas only by replacing the smoke detector with a particular sensor suitable for detecting gas.

In variants, the detector 115 includes a prism as described in the patent application FR 10 57338, filed on September 14, 2010 by the company Finsécur.

• un émetteur 116 de lumière,
• un récepteur 117 de lumière, sensible pour au moins une partie des longueurs d'onde des rayons lumineux émis par l'émetteur,
• un premier réflecteur 118 de lumière en regard de l'émetteur pour diriger la lumière émise par l'émetteur vers une zone de détection dans la zone de diffusion et
• un deuxième réflecteur 119 de lumière en regard du récepteur pour diriger, en présence de fumée dans la zone de diffusion, la lumière diffusée en provenance de ladite zone de détection, vers le récepteur.

In particular embodiments, such as that shown in figure 11 , the detector 115 comprises:

• a light emitter 116,
• a light receiver 117, sensitive for at least part of the wavelengths of the light rays emitted by the transmitter,
• a first light reflector 118 facing the emitter for directing the light emitted by the emitter towards a detection zone in the diffusion zone and
• a second light reflector 119 facing the receiver for directing, in the presence of smoke in the diffusion area, the light scattered from said detection area, towards the receiver.

The light emitter 116 is, for example, a laser or light emitting diode source.

The receiver 117 is, for example, a photoelectric cell configured to generate an electrical signal upon reception of the light signal emitted by the light emitter 116.

The first reflector 118 is, for example, an optical prism.

The second reflector 119 is, for example, an optical prism.

The transmitter 120 is, for example, an electronic circuit for controlling a wired or wireless link connecting the detector 100 to a third-party device.

In variants, the transmitter 120 implements an Ethernet port.

In variants, the transmitter 120 implements a wireless antenna configured to operate according to the IEEE 802.11 standard, called Wi-Fi.

In variants, the transmitter 120 implements a wireless antenna configured to implement spread spectrum transmission technology, such as LoRa (registered trademark) technology.

In variants, the transmitter 120 implements a narrowband radio technology or a short-range wireless technology of the Bluetooth Low Energy type.

In variants, the transmitter 120 is an indicator light or a loudspeaker configured to emit a visual and / or audible signal.

In variants, the transmitter 120 is a buzzer.

The housing 125 is, for example, a rigid envelope having the shape of a flattened cylinder or of a truncated cone. The shape of the envelope depends on the place of use of the detector 100.

In embodiments, such as that shown in figure 1 , the detector 100 comprises a capillary 130, fixed to the opening, offset the opening 135 by a predetermined length of capillary.

The capillary 130 is, for example, a tube made of metallic or plastic material. This capillary 130 is fixed by gluing, screwing or clipping to the opening 135.

The capillary has a length greater than ten centimeters, greater than one meter or greater than five meters.

In embodiments, the capillary 130 is rigid.

In embodiments, such as that shown in figure 1 , the shape of an interior volume of the chamber 110 is configured so that a flow of aspirated air forms a vortex, between an inlet 140 and an outlet 145 of said chamber, to increase the occupation time of the smoke and / or particles in the chamber.

Such a chamber 110 is further illustrated in figures 2 and 3 .

We observe, on the figures 2 and 3 , an embodiment of the chamber 100 in which the chamber 110 has the shape of a cylinder of revolution, the inlet 140 being positioned so that the flow enters the chamber in a direction tangential to the lateral periphery of the cylinder.

We observe, on the figures 2 and 3 , an embodiment of the chamber 100 in which the chamber 110 comprises fins 150 for guiding the air flow from the inlet 140 towards the outlet 145. These fins 150 are positioned against an internal surface of the chamber 110 so directing the air to create a vortex, or vortex, guiding the air from inlet 140 to outlet 145.

This vortex has the effect of keeping the particles and the smoke in the chamber longer, which makes the analysis carried out by the detector 100 more reliable.

In variants, the detector 100 includes a virtual impactor 155, upstream of the chamber 110, configured to allow the capture of particles of a predetermined size (diameter, radius of gyration). These variants make it possible not to use a filter, which reduces the risks of fouling and therefore the maintenance needs of the detector 100 as well as the risks of detection of false alarms.

A particular embodiment of the virtual impactor 155 is shown in figure 13 . In this particular geometry, the air flow causes a separation of the particles, according to two air paths, according to the dimensions of these particles due to the reduced mobility of the larger particles.

In variants, the detector 100 includes a plurality of cascade impactors.

The particles hit a wall on the air path in each impactor so that only the smallest particles pass through these impactors.

We observe, in figure 14 , a particular embodiment of the detector 100 which includes a virtual impactor 156, the smallest particles then passing through two impactors 157 and then the detection chamber 110.

We observe, on the figures 2 and 3 , an embodiment of the chamber 110 in which the outlet 145 is positioned perpendicular to the air flow in the chamber 100 at the positioning of the outlet.

• une étape 205 d'aspiration d'air à travers une ouverture d'un boîtier vers une chambre de détection positionnée à l'intérieur du boîtier,
• une étape 210 de détection de présence de fumée dans une chambre de détection positionnée à l'intérieur du boîtier et
• une étape 215 d'émission d'un signal représentatif de la détection de fumée dans la chambre de détection, par un émetteur positionné à l'intérieur du boîtier.

We observe, on the figure 4 , schematically, a particular flow diagram of steps 200 of the subject of the present invention. This smoke detection method 200 comprises:

• a step 205 of aspirating air through an opening of a housing towards a detection chamber positioned inside the housing,
• a step 210 of detecting the presence of smoke in a detection chamber positioned inside the housing and
• a step 215 of transmitting a signal representative of the smoke detection in the detection chamber, by a transmitter positioned inside the housing.

This process is carried out, for example, by the implementation of the detector 100 as described with regard to Figures 1 to 3 .

In preferred embodiments, the method 200 comprises a step of segregation of a part of the particles aspirated during the suction step 205. This step of segregation is carried out, for example, by the implementation of a filter or a virtual impactor.

In preferred embodiments, the method 200 includes a step of preserving the particles in the chamber, by the implementation of a vortex for example.

• au moins un détecteur 100 de fumée tel que décrit en regard de l'une des figures 1 à 3 et
• une centrale 305 d'alarme comportant :
  • un récepteur 310 d'un signal émis par chaque détecteur et
  • un moyen 315 de transmission d'une information représentative de la détection de fumée par au moins un détecteur.

We observe, on the figure 5 , schematically, a particular embodiment of the system 300 object of the present invention. This smoke detection system 300 comprises:

• at least one smoke detector 100 as described opposite one of the Figures 1 to 3 and
• a central alarm 305 comprising:
  • a receiver 310 of a signal emitted by each detector and
  • means 315 for transmitting information representative of smoke detection by at least one detector.

The alarm center 305 is positioned on the same site as at least one detector 100 or remotely.

The receiver 310 is configured to correspond to the transmission technique implemented by the transmitter 120 of each detector 100. This receiver 310 can thus be configured to receive a wired or wireless signal.

• un voyant lumineux,
• un écran d'affichage,
• un haut-parleur ou
• un circuit électronique de commande configuré pour commander une liaison filaire ou sans-fil reliant la centrale 305 à un dispositif tiers.

The transmission means 315 is, for example:

• an indicator light,
• a display screen,
• a speaker or
• an electronic control circuit configured to control a wired or wireless link connecting the central 305 to a third-party device.

• une chambre 110 de détection reliée à un dispositif (105) d'aspiration et à une ouverture 139 permettant le passage d'un flux d'air comportant de la fumée, des particules ou du gaz,
• un moyen, 156 et/ ou 157, de ségrégation de particules traversant l'ouverture et/ou de rétention de particules dans la chambre,
• un détecteur 115 de présence de fumée, de gaz ou de particules dans la chambre de détection et
• un émetteur 120 d'un signal représentatif de la détection de fumée, de gaz ou de particules dans la chambre de détection.

We also observe, in figure 1 and 12 , schematically, an embodiment of the detector 100 object of the present invention. This smoke, gas or particle detector 100 comprises:

• a detection chamber 110 connected to a suction device (105) and to an opening 139 allowing the passage of an air flow comprising smoke, particles or gas,
• a means, 156 and / or 157, for segregating particles passing through the opening and / or for retaining particles in the chamber,
• a detector 115 for the presence of smoke, gas or particles in the detection chamber and
• a transmitter 120 of a signal representative of the detection of smoke, gas or particles in the detection chamber.

The purpose of the segregation means is to limit the access of the chamber 110 to particles and gases of interest for the application of the detector 100.

This means of segregation is, for example, a filter or an absorbent material intended to prevent superfluous particles, for detection, from reaching the chamber 110.

In embodiments, the segregation means comprises a virtual impactor 155 upstream of the opening 156.

In embodiments, the segregation means comprises an impactor 155 upstream of the opening 156.

The objective of the retention means is to retain the smoke and the particles of interest in the chamber 110 for the application of the detector 100.

This retention means is, for example, formed of an interior volume of the chamber 110 configured so that a flow of aspirated air forms a vortex, between an inlet 140 and an outlet 145 of said chamber, to increase the time d occupation of smoke and particles in the room.

In embodiments, the chamber 110 has the shape of a cylinder of revolution, the inlet 140 being positioned so that the flow enters the chamber in a direction tangential to the lateral periphery of the cylinder.

In embodiments, the chamber 110 comprises fins 150 for guiding the air flow from the inlet 140 to the outlet 145.

In embodiments, the outlet 145 is positioned perpendicular to the air flow in the chamber 100 when the outlet is positioned.

In embodiments, the air suction device 105 is protected by a filter 106 limiting its fouling.

Claims (15)

1. Detector (100) of smoke, gas or particles, that comprises:

   - a detection chamber (110) connected to a suction device (105) and to an opening (139) allowing a flow of air and particles or gas to pass;

   - a means (156, 157) for retaining particles in the chamber;

   - a detector (115) of the presence of smoke, gas or particles in the detection chamber; and

   - an emitter (120) of a signal representative of the detection of smoke, gas or particles in the detection chamber,

   characterized in that the retention means comprises a volume inside the chamber (110) configured such that a flow of air sucked in forms a vortex, between an inlet (140) and an outlet (145) of said chamber, to increase the time that smoke particles occupy the chamber.
2. Detector (100) according to claim 1, wherein the chamber (110) has the shape of a cylinder of revolution, the inlet (140) being positioned such that the flow penetrates the chamber in a direction tangential to the side periphery of the cylinder.
3. Detector (100) according to claim 2, wherein the chamber (110) comprises vanes (150) for guiding the air flow from the inlet (140) towards the outlet (145).
4. Detector (100) according to one of claims 1 to 3, wherein the outlet (145) is positioned perpendicular to the air flow in the chamber (100) at the position of the outlet.
5. Detector (100) according to one of claims 1 to 4, that further comprises a means (156, 157) for segregating particles passing through the opening.
6. Detector (100) according to claim 5, wherein the segregation means comprises a virtual impactor (155) upstream from the opening (156).
7. Detector (100) according to one of claims 5 or 6, wherein the segregation means comprises an impactor (155) upstream from the opening (156).
8. Detector (100) according to one of claims 1 to 7, which comprises a piezoelectric membrane micropump (105) to suck the air in towards a detection chamber (110) through an opening (135), the micropump, detection chamber, detector and emitter being built into a shared housing (125), the opening giving onto the outside of the housing.
9. Detector (100) according to claim 8, which comprises a means (160) for measuring the flow rate of the air sucked in by the micropump (105).
10. Detector (100) according to claim 9, which comprises a means (165) for communicating a signal as a function of the air flow rate measured.
11. Detector (100) according to one of claims 9 or 10 and according to claim 8, wherein the means (160) for measuring the flow rate comprises a sensor (172) of a vibration frequency of the membrane (107) of the micropump and a means (173) for determining a value of the flow rate as a function of the vibration frequency detected.
12. Detector (100) according to one of claims 9 or 10 and according to claim 8, wherein the means (160) for measuring the flow rate comprises a sensor (176) of an amplitude of the vibration of the piezoelectric membrane and a means (177) for determining a value of the flow rate as a function of the vibration amplitude detected.
13. Detector (100) according to claim 9, wherein the means (160) for measuring the flow rate comprises a thermistor (174) and a means (175) for determining a value of the flow rate as a function of the resistance detected.
14. Method (200) for detecting gas or particles, that comprises:

    - a step (205) of sucking air in with a micropump through an opening of a housing towards a detection chamber positioned inside the housing;

    - a step (210) of detecting the presence of gas or particles in a detection chamber positioned inside the housing; and

    - a step (215) of emitting a signal, representative of the detection of gas or particles in the detection chamber, by an emitter positioned inside the housing. characterized in that the sucking step comprises a step of keeping the particles inside a volume inside the chamber (110) configured such that a flow of air sucked in forms a vortex to increase the time that smoke particles occupy the chamber.
15. Device (300) for detecting smoke, characterized in that it comprises:

    - at least one detector (100) of smoke, gas or particles according to one of claims 1 to 13; and

    - an alarm control unit (305) comprising:

    - a receiver (310) of a signal emitted by each detector; and

    - a means (315) for transmitting an item of information representative of the detection of smoke, gas or particles by at least one detector.

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