WO2015114170A1 - Device for detecting fire or gas leakage and system for securing premises comprising said device - Google Patents

Abstract

The invention relates to a device (50) for detecting fire or gas leakage, comprising: a sensor (510) for detecting a value of a physical variable representing the presence of a fire or a gas leak, a detector (515) for detecting a fire or a gas leak according to the value detected and a threshold value, and a presence detector (505), the threshold value varying according to the detection of a presence by the presence detector.

Description

 DEVICE FOR DETECTING FIRE OR GAS LEAKAGE AND SECURING SYSTEM OF A LOCAL COMPRISING SAME

TECHNICAL FIELD OF THE INVENTION

 The present invention relates to a fire detector or gas leak, a room security system comprising such a detector, a housing, a room security system comprising such a housing and a construction method of a wall comprising such a housing. It applies, in particular, to the securing of residences or activity sites.

STATE OF THE ART

 Securing premises against hazards, such as fires, currently uses systems that include:

 sensors capturing a physical quantity whose value may represent the danger, such as the temperature of a room for example,

 an alarm center receiving the values transmitted by the sensors, detecting an anomaly in a physical quantity measured by a sensor and

 possibly, means of securing the site, such as, for example, winches opening hatches of openings of the site when an anomaly is detected.

 The disadvantage of current systems is that, for example in the case of a fire detector positioned in a kitchen, the detection of a fire is triggered either too easily or too difficult. For example, when an individual cooks, the temperature in the kitchen is likely to increase and the chances of catching smoke, from cigarettes or matches, are greater. The detection of a fire for these reasons causes inconvenience to the individual and a risk that the system is disabled.

Systems, such as those described in patent application US5486810, are known in particular. These systems aim to detect both a fire and an intrusion into a room. However, these systems do not reduce the risks of false detection of a fire when a user who is not an intruder in the room is present.

 In addition, systems are known as described in patent application US2008291036 whose function is similar to the systems described above. Thus, these systems also do not reduce the risk of false detection of a fire when a user in the room.

 Finally, systems are known as described in the patent application WO2010043272 whose function is to perform a joint detection of several fire type risks. These systems also do not reduce the risk of false detection of a fire when there is a user in the room.

OBJECT OF THE INVENTION

 The present invention aims to remedy all or part of these disadvantages. For this purpose, according to a first aspect, the present invention aims at a device for detecting fire or gas leakage, which comprises:

 a sensor with a value of a physical quantity representative of the presence of a fire or a gas leak,

 - a fire detector or a gas leak according to the sensed value and a limit value,

further comprising a presence detector, the limit value varying according to the detection of a presence by the presence detector.

 In this way, depending on the detection of a presence or not in a room, the detection of a fire or a gas leak is made more or less sensitive. For example, when no user is in the room, the limit value of the detection of a fire or a gas leak is lower, whereas the reverse is implemented when a user is in the room. local.

 In embodiments, the presence detector includes a motion sensor, a presence being detected when motion is sensed.

 These embodiments make it possible to implement inexpensive technologies that reduce the cost of the device.

In embodiments, the detection of a presence depends on a timestamp information of that detection. These embodiments make it possible, for example at night, although no presence is detected due to immobility of a drowsy user, to maintain the detection of a presence.

 In embodiments, the presence detector includes means for receiving a wireless signal from a communicating portable terminal, which detector detects a presence when a wireless signal is received.

 These embodiments make it possible to detect a presence as a function of the communication of a communicating portable terminal of a user, this communication being representative of the presence of this user,

 In embodiments, the device that is the subject of the present invention comprises means for communicating a wireless signal comprising information representative of the detection of a presence.

 These embodiments make it possible to communicate to a remote sensor-detector assembly of the presence detector information representative of this presence detection so that the limit value varies.

 In embodiments, the device that is the subject of the present invention comprises means for transmitting a wireless signal comprising information representative of the detection of a fire or a gas leak.

 These embodiments make it possible to transmit to a control panel information representative of the detection of a fire or a gas leak.

 In embodiments, the limit value is increased by a constant value as long as a presence is detected.

 These embodiments make it possible to limit the detection of a fire or a gas leak when a user is present in a room.

 In embodiments, the limit value is increased by a constant value for a first predetermined duration as soon as a presence is detected.

 These embodiments make it possible to limit the detection of a fire for a predetermined duration as soon as a user is detected.

In embodiments, the increased limit value decreases after a second predetermined duration following detection of a presence. These embodiments allow a linear or exponential decay of the detection limit value as soon as a presence is no longer detected.

 In embodiments, the device of the present invention comprises an autonomous power source.

 These embodiments make it possible to limit the installation constraints of the device by reducing the wiring requirements in particular.

 According to a second aspect, the present invention aims at a system for securing premises, which comprises:

 at least one detection device that is the subject of the present invention and

 an alarm control unit configured to communicate with at least one detection device.

 The aims, advantages and features of the system object of the present invention being similar to those of the device object of the second aspect of the present invention, they are not recalled here.

 According to a third aspect, the present invention aims a housing security box, which comprises:

 a means for emitting a light beam,

 a detection device according to the present invention, in which:

 the sensor is a sensor of a light beam reflected outside the housing;

 - the fire detector is a fire detector configured to detect a fire according to the light beam captured and

 the presence detector is a presence detection means,

 means for emitting an audible and / or visual signal if a fire is detected and

 a communication means configured to emit a signal representative of the detection of a presence by the detector.

Thanks to these arrangements, the emission-capture device is protected from dust and can therefore allow the reliable detection of a fire. In addition, the combination of a presence detector and a fire detector makes it possible to reduce the number of devices to be installed in a room and / or to have additional information allowing automatic management of the room, as example heating, air conditioning or cleaning the premises. In this way, the installation and maintenance of all the devices are facilitated. In addition, the integration of these two devices reduces the impact on the aesthetics of the room compared to systems comprising each device separately. Finally, the communication means makes it possible, in particular, to send a signal to a means for regulating the temperature or lighting of the room as a function of the detection or not of a presence.

 In embodiments, the housing object of the present invention comprises a remote means of reflection of the light beam emitted towards the sensor. These embodiments have the advantage of improving the reliability of the detector by increasing the reception power of the beam. bright captured.

 In embodiments, the communication means is configured to output a digital signal representative of fire detection by the detector.

 The advantage of these embodiments is that they make it possible to transmit, to a central alarm or telephone line of emergency services for example, a signal representative of the detection of a fire.

 In embodiments, the object of the present invention comprises an autonomous power source.

 These embodiments have the advantage of reducing the amount of cables to deploy and hide during the installation of the housing.

 In embodiments, the object of the present invention comprises, facing the transmitting means and the sensor, a transparent surface at least for a wavelength of the transmitted light beam and captured.

 The advantage of these embodiments is that they limit the aesthetic impact of the housing on the premises. In particular, for infrared light beams, the surface may be opaque in the wavelengths visible to the eye.

 In embodiments, the detector is configured to detect a fire based on the comparison between a sensed beam characteristic value and a predetermined limit value, which predetermined limit value varies depending on the presence detection by the presence detection.

These embodiments have the advantage of making it possible to make the fire detector less sensitive when a user of the room is present in the room. Of in this way, the detection of smoke equivalent to cigarette smoke can trigger the detection of a fire when no user is present in the room.

 According to a fourth aspect, the present invention aims at a system for securing and controlling a room, which comprises a housing object of the present invention embedded in a wall of the room.

 Thanks to these provisions, the aesthetic impact of the housing on the appearance of the room is low.

 In embodiments, the system that is the subject of the present invention comprises means for regulating the temperature of the controlled room as a function of the detection of a presence.

 These embodiments have the advantage of allowing, when a user is present in the room, to increase or decrease the temperature in the room as a function of the temperature outside the room.

 In embodiments, the system that is the subject of the present invention comprises a lighting means of the controlled room as a function of the detection of a presence.

 The advantage of these embodiments is that they allow, when a user is present in the room, to increase the lighting in the room when the user is detected. Conversely, when no user is detected for a predetermined duration, the lighting of the room can be turned off.

 According to a fifth aspect, the present invention aims a system for securing a room, which comprises:

 at least one housing object of the present invention and

 an alarm control unit configured to communicate with at least one housing.

 Thanks to these provisions, the alarm center can perform a plurality of actions during the detection of a fire. In particular, the alarm center may in particular trigger actuators positioned in a site comprising the premises.

 According to a sixth aspect, the present invention is directed to a method of constructing a wall, which comprises:

 a step of assembling a prefabricated wall comprising a recess configured to receive a housing object of the present invention and

- A step of embedding the housing in the hollow. Since the aims, advantages and characteristics of the method which are the subject of the present invention are similar to those of the system that is the subject of the second aspect of the present invention, they are not recalled here.

 The features of the various aspects of the present invention are intended to be combined to provide other embodiments of the methods and devices of the present invention.

BRIEF DESCRIPTION OF THE FIGURES

 Other advantages, aims and particular characteristics of the invention will emerge from the following nonlimiting description of at least one particular embodiment of the housing, systems and method that are the subject of the present invention, with reference to the appended drawings. wherein :

 FIG. 1 represents, schematically and in section, a first particular embodiment of the object of the present invention,

 FIG. 2 represents, schematically and in perspective, a first particular embodiment of the system that is the subject of the present invention,

 FIG. 3 represents, schematically and in perspective, a second particular embodiment of the system that is the subject of the present invention,

FIG. 4 represents a logic diagram of steps of a particular embodiment of the method that is the subject of the present invention,

 FIG. 5 represents, schematically and in section, a first particular embodiment of the device which is the subject of the present invention and

 FIG. 6 represents, schematically and in perspective, a third particular embodiment of the system that is the subject of the present invention.

DESCRIPTION OF EXAMPLES OF EMBODIMENT OF THE INVENTION

 The present description is given in a non-limiting manner.

 A "short distance" is a distance less than one-tenth of the communication range.

 FIG. 1, which is not to scale, shows a sectional view of one embodiment of the housing 10 which is the subject of the present invention. This housing 10 comprises:

a means 105 for emitting a light beam, a remote means 135 for reflecting the light beam emitted towards the sensor 1 10,

 a sensor 1 10 of a light beam reflected outside the housing,

 a transparent surface 145,

 a fire detector 1 configured to detect a fire according to the light beam captured,

 a means 120 for emitting an audible and / or visual signal if a fire is detected,

 a means 125 for detecting presence,

 a communication means 130 configured to transmit a signal representative of the detection of a presence by the detector and

 an independent electric power source 140

 The assembly formed by the sensor 1 10, the fire detector 1 15 and the detection means 125 of presence is, for example, formed by a detection device 50 as described with reference to Figure 5.

 The housing 10 is, for example, a steel housing configured to be embedded in a recess of a wall of a room. In particular, one of the faces of the housing 10 is transparent at least for the beam emitted and captured. This face 145 is the only visible face from the room, the other faces of the housing 10 being concealed by the wall of the room in which the housing 10 is recessed.

 The transmission means 105 is, for example, an emitter of an infrared beam to a remote reflection means 135. This infrared beam is, for example, a beam of a single wavelength. Preferably, this ray is focused.

The remote reflection means 135 is, for example, a retro-reflector positioned on another wall of the room facing the transmission means 105 of the housing. This reflection means 135 is configured to reflect the transmitted beam towards the sensor 1 10. In variants, the reflection means 135 is configured to reflect the beam emitted near the sensor 1 10. In other variants, the means reflection 135 is a reflective paint deposited on a wall. The advantage of these variants is that the presence of the assembly formed by the transmission means 105, the reflection means 135 and the sensor 1 10 is more discreet. The sensor 1 10 is, for example, an infrared sensor configured to receive the beam reflected by the reflection means 135. In variants, this sensor 1 10 is configured to receive a dispersed portion of the reflected beam.

 The transparent surface 145 is, for example, a pane covering at least a portion of the face of the housing 10 unconcealed. This surface 145 is transparent for at least one wavelength of the emitted light beam and captured. This surface 145 is positioned on the path of the transmitted beam and the captured beam. In particular, this surface 145 makes it possible to make the housing 10 discrete in the room.

 The fire detector 1 is, for example, an electronic circuit configured to detect a density of smoke in the air as a function of the received beam. In variants, the detector 1 is configured to detect a density of smoke in the air as a function of the power of the dispersion of the received beam. When this density is greater than a predetermined limit value, the detector 1 15 detects a fire. This predetermined limit value may be increased or decreased when the presence detection means 125 detects a presence. Thus, for example, when no presence is detected in the room, the predetermined limit value is lowered. In variants, this limit value is adaptive, that is to say slowly varying with respect to the variations in smoke density detected.

 The transmission means 120 for emitting an audible and / or visual signal if a fire is detected is, for example, a flash light configured to be actuated during the detection of a fire. In variants, the transmission means 120 is a loudspeaker configured to emit an audible alarm signal upon detection of a fire.

 The means 125 for detecting a presence in the room is, for example, an infrared motion sensor. In variants, this detection means 125 operates by means of a sound sensor. When a sensed value is greater than a predetermined limit value, the sensing means 125 detects a presence.

The communication means 130 is, for example, a wireless antenna configured to communicate with a central. This communication means 130 is configured to transmit a digital signal representative of the detection of a presence. Depending on this signal, the control panel allows a user to performing actions of which examples are detailed in the description of Figure 2. In addition, the communication means 130 is configured to transmit to a control panel, a digital signal representative of the detection of a fire. In variants, the communication means 130 is wired and connected to a network of the local.

 In variants, the communication means 130 communicates with an alarm present in the room. When a fire is detected, this alarm emits a sound and / or light signal so as to warn a user present in the premises of the presence of a fire. In other variants, the communication means 130 communicates to this alarm a signal representative of the detection of a presence and the alarm emits a sound and / or light signal when receiving this signal.

 In other variants, the communication means 130 communicates both with an alarm in the room and with a remote alarm center.

 In other variants, the communication means 130 communicates with an alarm in the room and / or with a remote alarm center according to the detection of a presence in the room. Thus, if no presence is detected, the communication means 130 communicates with the remote alarm center, for example.

 The stand-alone electric power source 140 is, for example, a battery or a battery. This power source 140 is configured to supply each means of the housing 10. When the amount of electrical energy of this power source 140 is less than a predetermined limit value, the transmission means 120 of a sound signal and / or visual is configured to emit a periodic signal representative of this low level of electrical energy. In variants, when the amount of electrical energy of the power source 140 is less than a predetermined limit value, the communication means 130 is configured to transmit a digital signal representative of the crossing of this limit.

 FIG. 2, which is not to scale, shows a perspective view of an embodiment of the system 20 of the present invention installed in a room. This system 20 comprises:

 a wall 205 comprising a hollow,

a housing 10 as illustrated in FIG. 1, castrated in the hollow, a means 210 for regulating the temperature of the room,

 a means 215 for lighting the room and

 a reflector 220 configured to reflect a light beam emitted by the means 105 for emitting a beam of the housing 10.

 The wall 205 is, for example, a wall of a hotel room having a recess configured to allow the recessing of the housing 10. The recess is, for example, made in such a way that an undisclosed face of the housing 10 is continuous with respect to the surface of the wall 205 in which the housing is recessed.

 The means 210 for regulating the temperature of the room is, for example, a reversible air conditioning unit for heating or cooling the room.

 The illumination means 215 is, for example, a light source configured to be switched off or on by the transmission means 130 of the housing 10.

 The reflector 220 is, for example, a reflective film positioned on a wall facing the transmission means 105 of the housing 10. The ray reflects on the reflector 220 is picked up by the sensor 1 10 of the housing. This reflector 220 corresponds to the reflection means 135 detailed in the description of the housing 10 in FIG.

 In this system 20, when a presence is detected by the detection means 125 of presence of the housing 10, the communication means 130 transmits a digital signal to a central, not shown. When a presence is detected in the room, the lighting means 215 is activated. In addition, if a presence is detected and the room temperature is below a predetermined limit value, the control means 210 of the temperature controls room heating. Conversely, if a presence is detected and the temperature of the room is greater than a predetermined limit value, the control means 210 controls the heating stop or cooling of the room. This temperature limit value can be determined by a user of the local. In the case where the room is a room in a hotel, the central can allow the hotel staff to know when the room is free so that it can be maintained.

In variants, this system 20 comprises means for emitting a fragrance configured to emit a fragrance into the room when a presence is detected. In other variants, this system 20 comprises a second means for transmitting a sound signal configured to read an audio signal, such as a music for example, when a presence is detected.

 In Figure 3, which is not to scale, a perspective view of an embodiment of the system object of the present invention is observed. This system 30 comprises:

 two housings 10, as illustrated in FIG. 1, each recessed in a wall of a room,

 an alarm center 305 configured to communicate with at least one housing 10,

 a means 210 for regulating the temperature of each room and

 a means 215 for lighting each room.

 The alarm center 305 is configured to communicate with each housing 10 of the system 30. When receiving a digital signal representative of the detection of a fire by the control panel 305, the alarm control unit 305 the transmission of an audible and / or light signal by each housing 10. Each housing 10, moreover, controls a regulating means 210 and a lighting means 215 in a manner similar to the operation detailed in the description of FIG. .

 FIG. 4 shows a particular flow diagram of the process 40 of the present invention. This method 40 comprises:

 a step 405 for assembling a prefabricated wall comprising a recess configured to receive a housing 10 as illustrated in FIG.

 a step 410 of embedding the housing 10 in the hollow.

 The assembly step 405 is performed, for example, by the implementation of fasteners for assembling a wall from prefabricated elements. The wall thus assembled comprises, in addition, a recess configured to receive a housing 10.

 The embedding step 410 is performed, for example, by screwing the housing 10 to the prefabricated wall when the housing 10 is positioned so that a non-concealed wall face is continuous with respect to the surface of the wall.

FIG. 5, which is not to scale, shows a particular embodiment of the device 50 which is the subject of the present invention. This device 50 for detecting fire or gas leakage comprises: a sensor 510 of a value of a physical quantity representative of the presence of a fire or a gas leak,

 a fire detector 515 or a gas leak according to the sensed value and a limit value and

 a presence detector 505, the limit value varying according to the detection of a presence by the presence detector.

 The sensor 510 is, for example, an optical sensor configured to emit a light beam through a volume of fluid formed, when no gas leak or fire is nearby, of ambient air. The light beam thus emitted is transformed into wavelength or orientation depending on the presence of smoke or gas.

 In variants, this sensor 510 is a thermometer for sensing the temperature of the room in which the sensor 510 is positioned.

 In variants, this sensor 510 is a barometer for sensing the pressure in the room.

 Any other type of sensor 510 usually implemented in a smoke or gas detector can also be implemented.

 The fire detector 515 is, for example, an electronic circuit comprising a calculation unit for comparing the value of the sensed physical quantity with a limit value. If the value of the sensed physical quantity is greater than the limit value, then the detector 515 detects the presence of a fire or a gas leak according to the function of the device 10. If the physical quantity sensed is less than the value limit, the detector 515 does not detect the presence of a gas leak or a fire.

 The detection of a gas leak or a fire causes, for example, the emission of an audible and / or luminous signal, the means 545 for transmitting this signal being integrated into a housing 550 comprising the sensor 510 and the 515. In variants, the transmission means 545 is remote from the housing 550.

The presence detector 505 is, for example, an assembly formed by an optical signal sensor and an electronic pattern recognition circuit in the sensed optical signal. In variants, the presence detector 505 is an assembly formed by an infrared signal sensor and a presence determining circuit as a function of a captured infrared signal.

 In variants, the detection of a presence depends on a timestamp information of this detection. For example, when a presence was initially detected, and a timestamp information of this detection indicates that the detection took place during the night, although no presence has since been detected, the detector 505 detects despite everything a presence compared to the information of time stamping.

 In variants, the presence detector 505 comprises a means 525 for receiving a wireless signal from a communicating portable terminal, said detector 505 detecting a presence when a wireless signal is received.

 This receiving means 525 is, for example, an antenna configured to detect the transmission or reception of a wireless signal transmitted on a mobile data network or an Internet-type data network by the communicating portable terminal. . This reception can be performed independently of the communication between the device 10 and the communicating portable terminal. In other variants, the reception is performed during the communication between the device 10 and the communicating portable terminal, this communication can be bidirectional. The reception of a signal may also correspond to the detection of a connection of the communicating portable terminal to a home-automation data network.

 In variants, the presence detector 505 includes a motion sensor 520, a presence being detected when motion is sensed.

 The detector 505 can be integrated into the housing 550 or remote from this housing 550.

When a presence is detected by the presence detector 505, the limit value used to detect a fire or a gas leak is changed, for example:

 - by switching between a predetermined low limit value and a predetermined high limit value,

 - by adding a constant value to the limit value of detection or

by adding a variable value as a function of time during a determined period of time. In variants, the limit value is increased by a constant value as long as a presence is detected.

 In variants, the limit value is increased by a constant value for a first predetermined duration as soon as a presence is detected. At the end of this first predetermined duration, the limit value is reset to the initial detection value.

 In variants, the increased limit value decreases after a second predetermined duration following the detection of a presence. The decay is, for example, a particular mathematical function of linear or exponential type. In variants, the device 50 comprises a means 530 for communicating a wireless signal comprising information representative of the detection of a presence. This communication means 530 is, for example, an antenna configured to transmit a wireless signal to an alarm center or other remote device. In variants, the communication means 530 is a transmission wire.

 In variants, the device 50 comprises means 535 for transmitting a wireless signal comprising information representative of the detection of a fire or a gas leak. This transmission means 535 is, for example, an antenna configured to transmit a wireless signal to an alarm center or other remote device. In variants, the transmission means 535 is a transmission wire. In preferred variants, the communication means 530 and transmission 535 are merged.

 In variants, each means of the device 10 can be deported from the other means, the association between the different means being carried out via a wired or wireless connection.

 In preferred embodiments, the device 10 comprises an independent electric power source 540. This power source 540 is, for example, a battery or a battery for example.

In this way, when the presence of a user is detected in a room, the detection of a fire or a gas leak is made more difficult, the user being able to cause a false detection by the actions undertaken in the local. FIG. 6, which is not to scale, shows a particular embodiment of the system that is the subject of the present invention. This system 60 for securing a room comprises:

 at least one detection device 50 as described with reference to FIG.

an alarm central 605 configured to communicate with at least one detection device 50.

 Each detector 50 is positioned in a room different from the room so that when a presence detector 505 of a detection device 50 detects a presence, this detection device 50 transmits to the alarm center 605 a signal representative of this detection. The alarm center 605 transmits to another detection device 50 information representative of the detection of a presence by the first detection device 50. In this way, the limit value of fire detection or gas leakage varies. for this other detection device 50.

 In variants, this presence detection information is transmitted to another device (not shown) having no means of detecting a presence and whose treatment depends on the external detection of a presence.

Claims

1. A device (50) for detecting fire or gas leakage, which comprises:  a sensor (510) with a value of a physical quantity representative of the presence of a fire or a gas leak,  a fire detector (515) or a gas leak according to the sensed value and a limit value, characterized in that it comprises a presence detector (505), the limit value varying according to the detection of a presence by the presence detector. The sensing device (50) of claim 1, wherein the presence detector (505) includes a motion sensor (520), a presence being detected when motion is sensed. 3. Detection device (50) according to one of claims 1 or 2, wherein the detection of a presence depends on a time stamp information of this detection. 4. Detection device (50) according to one of claims 1 to 3, wherein the presence detector (505) comprises means (525) for receiving a wireless signal from a communicating portable terminal, this detector detecting a presence when a wireless signal is received. 5. Detection device (50) according to one of claims 1 to 4, which comprises means (530) for communicating a wireless signal comprising information representative of the detection of a presence. 6. Detection device (50) according to one of claims 1 to 5, which comprises means (535) for transmitting a wireless signal comprising information representative of the detection of a fire or a leak gas. 7. Detection device (50) according to one of claims 1 to 6, wherein the limit value is increased by a constant value as a presence is detected. 8. Detection device (50) according to one of claims 1 to 7, wherein the limit value is increased by a constant value for a first predetermined time as soon as a presence is detected. 9. Detection device (50) according to one of claims 7 to 8, wherein the increased limit value decreases after a second predetermined time following the detection of a presence. 10. Detection device (50) according to one of claims 1 to 9, which comprises an autonomous power source (540). 1 1. System (60) for securing a premises, characterized in that it comprises:  at least one detection device (50) according to one of claims 1 to 10 and  an alarm center (605) configured to communicate with at least one detection device. 12. Box (10) for securing a room, characterized in that it comprises:  means (105) for emitting a light beam,  a detection device according to one of claims 1 to 10, wherein:  the sensor is a sensor (1 10) of a light beam reflected outside the housing;  the fire detector is a fire detector (1 15) configured to detect a fire according to the light beam captured and the presence detector is means (125) for detecting the presence, means (120) for emitting an audible and / or visual signal if a fire is detected and  communication means (130) configured to emit a signal representative of the detection of a presence by the detector. 13. Housing (10) according to claim 12, which comprises means (135) remote reflection of the light beam transmitted to the sensor (1 10). 14. Housing (10) according to one of claims 12 or 13, wherein the means (130) for communication is configured to output a digital signal representative of the detection of a fire by the detector (1 15) and / or presence by the presence detecting means (125). 15. Housing (10) according to one of claims 12 to 14, which comprises an autonomous power source (140). 16. Housing (10) according to one of claims 12 to 15, which comprises, facing the means (105) of emission and the sensor (1 10), a surface (145) transparent at least for a length of wave of the light beam emitted and captured. Housing (10) according to one of claims 12 to 1 6, wherein the detector (1 15) is configured to detect a fire according to the comparison between a characteristic value of the captured beam and a predetermined limit value, this predetermined limit value varying according to the detection of a presence by the presence detecting means (125). 18. System (20) for securing and controlling a room, characterized in that it comprises a housing (10) according to one of claims 12 to 17, embedded in a wall (205) of the premises. 19. System (20) according to one of claims 18, which comprises means (210) for controlling the temperature of the controlled room according to the detection of a presence. 20. System (20) according to one of claims 18 or 19, which comprises means (215) for lighting the controlled premises according to the detection of a presence. 21. System (30) for securing a premises, characterized in that it comprises:  at least one housing (10) according to one of claims 12 to 20 and an alarm central (305) configured to communicate with at least one housing. 22. A method (40) for constructing a wall, characterized in that it comprises:  a step (405) for assembling a prefabricated wall comprising a recess configured to receive a housing according to one of claims 12 to 20 and - A step (410) of embedding the housing in the hollow.