EP2492882A1 - Device for detecting obstacles concealing a smoke detector - Google Patents

Abstract

The device has an ultrasonic transmitter and receiver assembly (9) comprising an ultrasonic transmitter to transmit ultrasonic waves in the direction of a reflection surface i.e. reflection cone (10), having a central axis of symmetry (X) positioned relative to the transmitter to reflect the transmitted waves toward an obstacle detection zone (11) enclosing a smoke detector (1) having a light source (7) i.e. LED, at 360 degrees. An ultrasonic receiver is positioned with respect to the reflection surface to capture the reflected waves by the surface from obstacles present in the zone. An independent claim is also included for a method for detecting obstacles masking a smoke detector.

Description

The present invention relates to a device and a method for detecting obstacles that may mask a smoke or gas detector, for example CO ₂ , and operating by emission / reception of waves, particularly of the sonic or ultrasonic type.

A smoke detector is a safety device that reacts to the presence of smoke or vapor in the air. There are optically operated detectors, for example photocells, or that operate by ionization. Ionic detectors are prohibited in France because they have unauthorized radioactive elements in private homes. On the other hand, the detectors with photocell or optics are widespread in France because they respect the conditions established in the French norm. This standard stipulates that all private dwellings must be equipped with a smoke detection device by 2015.

A smoke detector is designed to trip when smoke arrives in a detector's detector chamber. It does not detect gas, heat or flames, but only fumes to warn as soon as possible of fires by triggering an integrated alarm.

Photoelectric smoke detectors have the advantage of detecting smoldering fires, in other words fires that take a long time to declare themselves (mattresses, sofas, garbage cans, etc.). These slowly evolving fires are the most common (80% of cases) and the most dangerous.

• d'un boîtier délimitant une chambre de détection obscure, pourvu d'une grille périphérique laissant passer l'air environnant vers l'intérieur de la chambre de détection ;
• d'une source lumineuse de type diode électroluminescente (LED) éclairant la chambre de détection, et
• d'une cellule photo-électrique localisée dans la chambre de détection, et ayant pour fonction de transformer la lumière en un faible courant électrique.

Photocell fire detectors are conventionally composed of:

• a housing defining an obscure detection chamber provided with a peripheral grid passing the surrounding air to the inside of the detection chamber;
• a light emitting diode (LED) type light source illuminating the detection chamber, and
• a photoelectric cell located in the detection chamber, and having the function of transforming the light into a weak electric current.

Concretely, the light source sends a beam of light through the detection chamber which, in normal times, is not directed towards the photocell.

When smoke particles arrive in the detection chamber, the light emitted by the source is reflected on the surface of said particles, thus dispersing the incident beam, a portion of which is reflected towards the photocell, producing a current that triggers the alarm.

The major disadvantage of these detectors lies in the possibility of an obstruction of their grid, which makes them inoperative and prevents them from playing their role safe. Such masking may result, for example, from jets of paint or dust which would cover the peripheral grid, the air of the room then being unable to penetrate into the detection chamber, or be caused by a lamp whose lamp shade is imposing and prevents smoke from reaching the ceiling, etc ... In these conditions, access to the detector is more or less obstructed, and the latter may no longer perform its function properly in case of fire.

The present invention overcomes this disadvantage by proposing an obstruction detection device close to the active part of a smoke or CO ₂ detector, or in other words, an obstacle detection device capable of masking a detector of smoke or CO _2. smoke for example as described above.

• d'au moins un émetteur émettant des ondes en direction d'une surface de réflexion présentant un axe de symétrie centrale et positionnée relativement à l'émetteur de manière à réfléchir les ondes émises vers une zone de détection d'obstacles entourant à 360° le détecteur de fumée, la grille périphérique étant incluse dans cette zone de détection ;
• d'au moins un récepteur positionné relativement à la surface de réflexion en vue de capter les ondes réfléchies par la surface de réflexion en provenance d'un ou plusieurs obstacles présents dans la zone de détection d'obstacles.

According to the invention, this obstacle detection device is located inside the smoke detector housing and is composed of:

• at least one transmitter emitting waves towards a reflection surface having a central axis of symmetry and positioned relative to the transmitter so as to reflect the transmitted waves to an obstacle detection area surrounding the smoke detector, the peripheral grid being included in this detection zone;
• at least one receiver positioned relative to the reflection surface for sensing waves reflected from the reflection surface from one or more obstacles in the obstacle detection area.

This device makes it possible to establish a map of the environment in which the smoke detector is located. In particular, some waves emitted ricochet on the grid and are thus captured by the receiver (s), while other waves pass through the slots of the grid to reach the external environment of the detector then, or not encounter no obstacle, either ricochet on an obstacle (suspension, decoration, etc.) and are then also picked up by the receiver (s).

More precisely, the device first establishes initial mapping at time t ₀ serving as reference or offset. It then periodically establishes a map at the instant t that it compares to the initial mapping, so as to identify a possible change in the environment of the smoke detector. This change consists in the appearance of obstacles, resulting in the modification of the shape of the wave picked up by the receiver (s). These obstacles can for example correspond to the dust accumulated around the detector and blocking the peripheral grid, or to the paint inadvertently projected on the detector and also blocking the grid in certain places, or to objects (lampshade, decoration ) added in the room at the detection zone.

Any change in the environment of the smoke detector causes the activation of an alarm (visual or audible). The informed user can take any appropriate action, such as cleaning the smoke detector or moving the new objects so as not to mask the smoke detector.

Ideally, the obstacle detection area is a half-sphere with a radius of 1.5m around the smoke detector, which can be attached to the ceiling or a wall such as a wall light. In order to be able to detect obstacles in such a zone, many parameters intervene in practice, in particular the shape of the reflection surface, the relative positions of the various constituent elements of the device, the orientation of the surface of the box covered by the grid, etc. .

In order to get as close as possible to this goal of maximum peripheral coverage, the reflection surface can take different forms: a cone shape, a dome shape, or a multiple form. facets arranged to reflect the waves emitted 360 ° around the smoke detector.

Other forms allowing such 360 ° reflection around the smoke detector are of course possible.

In all cases, the reflection surface has a culminating shape towards the transmitter (s).

The angle of inclination of the reflection surface is also a parameter on which it is possible to play in order to widen the detection zone.

According to a possible configuration of the invention, a single emitter is centered with respect to the central axis of symmetry of the reflection surface so that the transmitted waves cover the entire reflection surface.

According to another possible configuration of the invention, several emitters distributed in the housing of the smoke detector emit waves covering the entire reflection surface.

According to one possibility of the invention, a single receiver may also be centered with respect to the central axis of symmetry of the reflection surface so as to capture the waves reflected by the reflection surface from obstacles present in the detection area.

Alternatively, several receivers may be distributed in the smoke detector housing and positioned relative to the reflection surface also to capture all the waves reflected by the reflection surface from obstacles in the detection zone.

In general, the transmitter (s) and the receiver (s) can be combined into one or more devices, reducing on the one hand the bulk in the housing of the smoke detector, and further facilitating their positioning relative to the reflection surface.

• réalisation et mémorisation d'un premier diagramme d'acquisition temporelle de l'onde, correspondant à un offset à l'instant t₀ représentant l'environnement normal autour du détecteur de fumée ;
• émission périodique à l'instant t_x d'une impulsion sonore et mémorisation du diagramme d'acquisition temporelle obtenu en retour après réflexion ;
• comparaison des deux diagrammes d'acquisition temporelle à l'instant t₀ et t_x ;
• en cas de différence des résultats, déclenchement de l'alarme.

The invention also relates to an obstacle detection method masking the smoke detector as described above. This process comprises the following steps:

• producing and storing a first temporal acquisition diagram of the wave, corresponding to an offset at time t ₀ representing the normal environment around the smoke detector;
• periodic emission at the instant t _x of a sound pulse and memorization of the temporal acquisition diagram obtained in return after reflection;
• comparing the two temporal acquisition diagrams at time t ₀ and t _x ;
• in case of difference in results, triggering the alarm.

• la figure 1 est une vue en coupe d'un dispositif de détection d'obstacles masquant un détecteur de fumée ;
• la figure 2a représente un enregistrement graphique de l'environnement normal du détecteur de fumée;
• la figure 2b consiste en un enregistrement graphique de l'environnement du détecteur de fumée encombré par un obstacle.

The invention will now be described in more detail, with reference to the appended figures, for which:

• the figure 1 is a sectional view of an obstacle detection device masking a smoke detector;
• the figure 2a represents a graphical record of the normal environment of the smoke detector;
• the figure 2b consists of a graphical recording of the environment of the smoke detector obstructed by an obstacle.

With reference to the figure 1 , a smoke detector (1) is attached to a ceiling (2).

This smoke detector (1) is traditionally composed of a housing (3) to which is attached a peripheral grid (4), in this case located at its lower part. The housing (3) has a central axis of symmetry (X).

The openings (5) of the grid (4) allow the surrounding air to circulate inwardly of the housing (3). A detection chamber (6) is in practice delimited by the housing (3).

A light source assembly (7) / photoelectric cell detector (8), for example located in the upper part of the housing (3) is provided to detect if smoke enters the detection chamber (6).

An ultrasonic transmitter / receiver (9) controlled by an electronic card (16) is also located in the upper part of the housing (3), more precisely centered on the central axis (X) of the housing (3), integrated in this last so as not to disturb the normal operation of the smoke detector (1).

A reflective surface (10) having the shape of a cone rests in the lower part of the housing (3), also centered with respect to the central axis (X), pointing towards the transmitter / receiver (9).

The peripheral grid (4) surrounds the reflection cone (10) substantially over its entire height.

The transmitter / receiver (9) and the reflection cone (10) are in fact the obstacle detection device of the invention intended to prevent any masking of the smoke detector (1).

In operation, the transmitter / receiver (9) emits ultrasonic waves towards the reflection cone (10), which thus reflects them in the air towards the peripheral grid (4). The distance between the emitter (9) and the cone (10) is calculated so that the emitted waves preferably cover the entire surface of the cone (10), and not only a part of it. The shape of the cone (10) itself as well as the angle of inclination of its wall make it possible to reflect the waves on a peripheral zone which is as large as possible under the casing (3) so as to widen as much as possible the zone of detection (11) of obstacles.

• laisser passer l'air environnant vers l'intérieur du boîtier (3) pour la détection de fumée ;
• laisser passer les ondes ultrasonores vers l'extérieur du boîtier (3) pour la détection d'obstacles.

The grid (4) thus has two functions:

• let the surrounding air to the inside of the housing (3) for smoke detection;
• let the ultrasonic waves to the outside of the housing (3) for the detection of obstacles.

In the configuration illustrated in figure 1 , a zone without detection (12) remains under the cone (10), the waves can not propagate through the reflection surface that it constitutes. In practice, the obstacle detection zone (11) has the appearance of a half-sphere surrounding the gate (4) of the detector (1) to which said non-detection zone (12) is subtracted.

When the transmitted waves encounter an obstacle, for example the grid (4), or any potentially troublesome object for the passage of fumes, they are reflected towards the reflection cone (10) then to the receiver (9). The wave finally makes a round trip between the transceiver (9) and the obstacle.

An obstacle detection control LED (13) and a smoke detection control LED (14) are placed on the outer face of the housing (3) so as to visually alert the user in case of masking. smoke detector (1) or in case of fire.

The figure 2a consists of a graph illustrating the environment of the smoke detector under normal operating conditions.

Specifically, it is a temporal acquisition diagram of the wave produced following the sending of an ultrasonic pulse. The further the obstacle is from the transceiver, the longer the path of the wave and the longer the feedback signal is received late. The shape of the signals appears on the diagram, temporally on the abscissa axis while the ordinate marks the measured amplitude in volts.

The reflection due to the gate impacts the transmitted signal in a manner that is recorded as constituting the normal environment of the product.

The appearance of this first acquisition thus makes it possible to establish an initial mapping, called offset, at time t ₀ , of the environment in which the smoke detector is located.

The figure 2b , representing a graph similar to the figure 2a , illustrates a map of the environment in which the smoke detector is located at a time t, in the presence of a flat obstacle which impacts the signal in return and modifies the initial signal.

This is a flat target (15) of 20cm2 placed 25cm from the smoke detector.

• il réalise un offset à l'instant t₀ représentant l'environnement normal autour du détecteur de fumée ;
• puis il émet périodiquement une impulsion sonore ;
• il compare chaque réflexion obtenue avec l'enregistrement initial ;
• si les résultats sont sensiblement identiques, cela signifie que le détecteur de fumée n'est pas obstrué, alors que si les résultats diffèrent, le dispositif en infère que le détecteur de fumée risque d'être masqué, et l'alarme est alors déclenchée.

In concrete terms, the obstacle detection device operates as follows:

• it performs an offset at time t ₀ representing the normal environment around the smoke detector;
• then it periodically emits a sound pulse;
• he compares each reflection obtained with the initial recording;
• if the results are substantially identical, it means that the smoke detector is not obstructed, whereas if the results differ, the device infers that the smoke detector may be masked, and the alarm is then triggered.

The exemplary implementation of the device of the invention appearing in the preceding figures is not exhaustive of the invention, which on the contrary covers variations of shapes and configurations within the reach of those skilled in the art. . In particular, the choice of shapes for the different components may vary to the extent that they allow the implementation of appropriate detection as explained in detail before.

Claims (10)

An obstacle detection device capable of concealing a smoke detector (1), the latter consisting of a housing (3) delimiting a smoke detection chamber (6) provided with a peripheral grid (4), characterized in that that it is located inside the housing (3) of the smoke detector (1) and consists of: at least one transmitter emitting waves towards a reflection surface (10) having a central axis of symmetry (X) positioned relative to the emitter so as to reflect the waves emitted towards a detection zone of obstacles (11) surrounding the smoke detector (1) at 360 °, the peripheral grid (4) being included in this detection zone (11); at least one receiver positioned relative to the reflection surface (10) for sensing the waves reflected by the reflection surface (10) from one or more obstacles present in the obstacle detection area ( 11). An obstacle detection device masking a smoke detector (1) according to claim 1, characterized in that the reflection surface (10) is cone-shaped pointing towards the transmitter (s). An obstacle detection device masking a smoke detector (1) according to claim 1, characterized in that the reflecting surface (10) is dome-shaped culminating towards the transmitter (s). An obstacle detection device masking a smoke detector (1) according to claim 1, characterized in that the reflection surface (10) has multiple facets arranged to reflect the waves transmitted 360 ° around the smoke detector (1). An obstacle detection device masking a smoke detector (1) according to one of the preceding claims, characterized in that a single transmitter is centered with respect to the central axis of symmetry (X) of the reflection surface so that the transmitted waves cover the entire reflection surface (10). An obstacle detection device masking a smoke detector (1) according to one of the preceding claims, characterized in that several emitters distributed in the housing (3) of the smoke detector (1) emit waves covering the entire surface of reflection (10). An obstacle detection device masking a smoke detector (1) according to one of the preceding claims, characterized in that a single receiver is centered with respect to the central axis of symmetry (X) of the reflection surface ( 10) so as to capture all the waves reflected by the reflection surface (10) from obstacles present in the detection zone (11). An obstacle detection device masking a smoke detector (1) according to one of the preceding claims, characterized in that a plurality of receivers are distributed in the smoke detector housing (3) and positioned relative to the surface reflection device (10) to capture all the waves reflected by the reflection surface (10) from obstacles in the detection zone (11). An obstacle detection device masking a smoke detector (1) according to one of the preceding claims, characterized in that the transmitter (s) and the receiver (s) are combined into one (s) same device (s) (9). An obstacle detection method masking a smoke detector operating with a device according to the preceding claims, characterized by the following steps: - Realization and storage of a first time acquisition diagram of the wave, corresponding to an offset at time t ₀ representing the normal environment around the smoke detector; - Periodic emission at time t _x of a sound pulse and storing the time acquisition diagram obtained in return after reflection; comparing the two temporal acquisition diagrams at time t ₀ and t _x ; - if there is a difference in the results, triggering the alarm.

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