FR2946540A1 - TERMINAL FOR DEFIBRILLATOR. - Google Patents

Abstract

A defibrillator terminal (10) comprising a housing (20) and a defibrillator (100) detachably disposed in a housing (30) of the housing (20) such that the defibrillator can be removed from said housing (30), said defibrillator including transmission means (105) of an omnidirectional test radiation, said terminal (10) being characterized in that the housing (20) comprises means (25) for detecting the omnidirectional test radiation emitted by the defibrillator (100 ).

Description

The present invention relates to the field of defibrillators. More specifically, the present invention relates to the field of terminals or cabinets for housing a defibrillator to keep it available. Every year, many people are victims of cardiac arrest. According to statistics, for the French territory alone, 60,000 people are victims of such discomfort. Without intervention with a defibrillator, the survival rate is only around 5%. On the other hand, it is accepted that the use of a defibrillator within the first five minutes after cardiac arrest, combined with cardiopulmonary resuscitation techniques, increases the chances of survival by more than 30%. Despite this diagnosis, today, it is clear that in many situations, there is no defibrillator in acceptable conditions. The difficulties encountered seem to stem, in particular, from the fact that hitherto it has not been possible to reliably guarantee the availability of defibrillators in an immediate state of operation. The present invention aims, in this context, to improve the situation. This object is achieved in the context of the present invention, thanks to a defibrillator terminal comprising a housing and a removable defibrillator placed in a housing of the housing so that the defibrillator can be removed from said housing, said defibrillator comprising means for emission of an omnidirectional test radiation, said terminal being characterized in that the housing comprises means for detecting the omnidirectional test radiation emitted by the defibrillator. According to an advantageous characteristic of the invention, the omnidirectional test radiation is a sound vibration, preferably emitted at a regular timing. Other features, objects and advantages of the present invention will appear on reading the detailed description which follows, and with reference to the appended drawings, given by way of non-limiting example and in which: FIG. 1 represents an example embodiment of a terminal box according to the present invention, and - Figure 2 shows schematically, in the form of functional blocks, the structure of a device according to the present invention. The expression "defibrillator terminal" used in the context of the present invention must be understood in a broad sense that includes, in the pure sense of the term, any terminal fixed to the ground in any public or private place, as well as any cabinet fixed permanently in a public place or private, for example any wall cabinet, or any mobile cabinet made available, for example at public events, including sports. As indicated above and as shown in Figure 1 attached, the terminal 10 comprises a housing 20 which has a housing 30 for receiving a defibrillator 100 removable. Removable means that the defibrillator 100 can be freely removed from the housing 30 when its use is required. In the context of the invention, the defibrillator 100 may be in accordance with any defibrillation device known from the prior art, whether automatic or semi-automatic. As shown in FIG. 2, the defibrillator 100 comprises, in a conventional way, a central unit 102 managing the operation of the defibrillator 100, a control system 101 enabling a user to control the mode of operation of the defibrillator 100, a power supply 103 , for example of battery or battery type, and 104 electrodes to place on the appropriate area of the chest of a person to rescue. The terminal 10 is provided with protection means 32 of the housing 30 intended to receive the defibrillator 100, as well as a detection device 23 for detecting and signaling any withdrawal or opening of said protection means 32, by the production of an appropriate signal. Similarly, the detection device 23 can detect the closing or the replacement of the protective means 32 of the housing 30, and thus produce a corresponding signal. The protection means 32 and the detection device 23 mentioned above may be subject to any appropriate means, for example a door 32 closing the opening contour of the housing 30 associated with an opening sensor 23. The terminal 10 comprises in in addition to remote transmission means 38 to a monitoring center 40. The monitoring center 40 is advantageously permanently available, that is to say, twenty four hours a day, seven days a week. act in particular from a telephone back-up center, such as for example a reception and dispatch center of the SAMU. The transmission means 38 are bidirectional, and can transmit as well as receive information. Said transmission means 38 may for example transmit a signal representative of the detection of opening or withdrawal of the protection means 32 produced by the detection device 23, as well as a certain number of other signals and information which will be detailed by following, such as voice communications and / or signals from test units integrated in the housing 20. These remote transmission means 38 may for example comprise wired telephone link means and / or a mobile telephone device. These means may also include means for transmission by electromagnetic waves, such as Wi-Fi or any equivalent means, or IP transmission means. Furthermore, the terminal 10 has voice communication means between a user of said terminal 10 and the monitoring center 40. These voice communication means allow the monitoring center 40 to communicate with the user and to assist him / her. where appropriate, in rescue operations. These communication means also allow the monitoring center 40 to provide an access code to the user for unlocking the protection means 32, in the case where an access code, optional, has been programmed. The user can thus access the housing 30 and seize the defibrillator 100. The communication means between the user and the emergency center 40 may be identical to the remote transmission means 38 previously mentioned. In this case, the user can communicate with the monitoring center 40 via a wired telephone line and / or a mobile telephone device. In the case of a wired telephone line communication, the terminal 10 conventionally comprises a speaker and a microphone integrated in the housing 20. The mobile telephone device can be grasped and moved by the user to the place where the person to be rescued is, which allows the user to communicate with the monitoring center 40 even though it has moved away from the terminal 10 for defibrillator. Advantageously, the mobile telephone device is able to operate in roaming mode (known to those skilled in the art according to the English terminology roaming mode), that is to say, it is able to select the telephony network mobile service providing the best service at a given time and place. This eliminates the dependency on a given mobile operator, which can, in some places, such as sparsely populated areas, have a network with little or no coverage. The mobile telephone device may also include a satellite tracking device, in particular a GPS chip, so that the monitoring center 40 and / or the rescue teams (firefighters, EMS, etc.) can identify the precise location. where the user implements a rescue operation via the defibrillator 100.

In an advantageous embodiment, the transmission means 38 rely solely on a mobile telephone device, without using a wired telephone line. This mobile telephone device then transmits voice communications between the user and the monitoring center 40 as well as the signals transmitted by the detection device 23 and the detection or test means (21, 25, 27, 28, 29 ) of Figure 2, detailed in the following description. As stated above, this mobile telephone device can advantageously operate in roaming mode and include a satellite positioning device. As previously indicated, in the context of the present invention the defibrillator 100 comprises means 105 for transmitting an omnidirectional test radiation and the housing 20 comprises means 25 for detecting said omnidirectional test radiation emitted by the Defibrillator 100. Test radiation is understood to mean radiation indicating the operating state of defibrillator 100. This radiation may be emitted by defibrillator 100 when it is operational, or conversely, only when it encounters a problem. Operating. This radiation can also be emitted continuously, but in this case a characteristic (for example, the frequency) of said radiation varies as a function of the operating state of said defibrillator 100. The use of the term omnidirectional in the context of the present invention means that the test radiation is emitted in most or all directions of space. Nevertheless, the power of the test radiation is not necessarily homogeneous in all directions of space and can be variable. In an advantageous embodiment, the omnidirectional test radiation is a sound vibration, preferably emitted at a regular timing. This may be a timed sound or beep emitted as a proper operating signal by existing defibrillators on the market today. Conversely, it may be a timed acoustic signal or a beep emitted in the event of a malfunction of the defibrillator 100. In the context of the invention, the sound vibration emitted by the defibrillator 100 is not necessarily perfectly omnidirectional, but may have some directivity. Nevertheless, it is clear that a sound vibration emitted in an enclosure, in this case the housing 30, propagates in most or all directions of the space, which greatly facilitates the detection by the means 25. radiation detection means measures the test sound signal, for example via a microphone-type sensor, and then analyzes said signal to determine whether it is a test sound signal or a sound signal. external sound disturbance. To do this, these means 25 analyze different characteristics of the signal, including the frequency, and / or the duration of the beeps and / or the duration of the intervals between the beeps and / or the signal power. These means 25 may implement operations of filtering and / or Fourier transforming type, via integrated filtering and calculation means. The means 25 may advantageously filter the external noise disturbances (horn, urban noise ...). In general, this analysis is carried out over a time interval of between 2 and 5 minutes. In an advantageous embodiment, the analysis of the sound signal makes it possible to determine the type of defibrillator and / or its mark, since the characteristics of the test sound signal are generally specific to a type and / or a mark of defibrillator. The invention is not limited to a sound signal and relates to any omnidirectional radiation (whether magnetic, electrostatic, electromagnetic ...) in all frequency ranges. Compared to attempts to detect the signal emitted by operating LED type LEDs, already proposed according to the state of the art, the detection of an omnidirectional radiation has the decisive advantage of incomparable reliability. The present invention makes it possible to detect any deficiency of the defibrillator, regardless of the positioning and the orientation of the defibrillator 100 in the housing 30. On the other hand, a detection of the light radiation emitted by a light-emitting diode requires, on the one hand, a precise positioning of the defibrillator 100, and secondly, perfect cleanliness of the optical detection means, without risk of disturbance for example by condensation phenomena. In the case of the detection of a test sound signal emitted by the defibrillator 100 by the means 25, another advantage lies in the fact that the sound signals do not induce any disturbance on the operation of the defibrillator 100, while signals electromagnetic test output from the defibrillator 100 could, in some cases, disrupt the operation of said defibrillator 100 by inducing electromagnetic disturbances. On the other hand, the detection of omnidirectional radiation has the additional advantage of being flexible. Indeed, whatever the mark or the type of defibrillator, it is possible to detect said radiation without having to modify and adapt the entire architecture of the detection means and in particular the positioning of the detection sensors, which is not the case in the solution for detecting the signal emitted by operating LEDs of the LED type, for which a precise positioning of the photosensitive sensors is necessary. With the detection means 25, it is possible to detect the operating state of the defibrillator 100. Advantageously, these detection means 25 transmit a detection signal, characteristic of the operating state of the defibrillator 100, to a monitoring center 40, via the remote transmission means 38 described above. This is very advantageous since it is possible to have information on the state of operation of the remote defibrillator 100. The monitoring center 40 can thus detect at any time a failure of the defibrillator 100. The invention therefore guarantees the reliability of the operational state of the defibrillator 100 at all times, which implies that in case of emergency, the defibrillator 100 will be in immediate working condition. In addition, it avoids an expensive and unreliable control requiring the movement of a natural person to inspect the defibrillator 100. In addition to monitoring the operating status of the defibrillator 100, it is necessary to ensure that the defibrillator 100 is present in the housing 30 of the terminal 10. To do this, is provided in the terminal 10 defibrillator according to the invention a detection system 21 of the presence of the defibrillator 10 in its housing 30. This detection system 21 of the presence of the defibrillator may include but not limited to weight sensors, pressure sensors, acoustic sensors, optical or electrical. Said system 21 for detecting the presence of the defibrillator emits an alert signal in the absence of the defibrillator 100 from its housing 30. This alerting signal is transmitted to the monitoring center 40 via the transmission means. distance 38 previously described. Similarly, when the defibrillator is available in the housing 30, the detection system 21 can emit a signal confirming the presence of said defibrillator 100 in the housing 30, which is transmitted to the monitoring center 40 via the transmission means The advantage is again able to have permanently and remotely available information on the availability of the defibrillator 100 in the housing 30 of the terminal 10. The signal emitted by the detection system 21 on the presence of the defibrillator 100 in its housing 30, as well as the signal emitted by the device 23 for detecting the opening or withdrawal of the protection means 32 may advantageously be combined and thus constitute a confirmation for the monitoring center 40 that an operation rescue is being conducted. Indeed, these signals can confirm that a user has opened the door 32 of the housing 30 and removed the defibrillator 100. Moreover, the terminal 10 for defibrillator according to the invention advantageously comprises means 27 for testing the power supply. in energy 33 of the housing 20. In general, the housing 20 is powered by an external electrical outlet, connected to the general power grid of the area where the terminal 10 is located. In case of failure of this power supply, a power supply autonomous backup, such as a backup battery, takes over to supply the housing 20 with energy. The test means 27 detect any malfunction of the power supply 33 of the housing 20 and in particular the triggering of the emergency power supply, relying for example on a backup battery, and inform the monitoring center 40 by the intermediate of the remote transmission means 38 described above. The housing 20 also comprises control means 31, such as for example an electronic control card, ensuring in particular the control of the protection means 32 of the housing 30 (for example, opening or closing a door 32), the control of the power supply of the housing 20, as well as various auxiliary functions, such as the control of the temperature in the housing 30. In the event of a malfunction of said control means 31, a test system 28 of the operation of the control means 31 sends a signal at the monitoring center 40 via the remote transmission means 38 previously described. Finally, the housing 20 advantageously comprises automatic warning means 29 of a monitoring center 40, in particular for sending rescue teams (firefighters, SAMU ...) to the place where the user implements an emergency operation with the defibrillator 100. These means are for example a button to be pressed by the user triggering the immediate call from the monitoring center 40 via the remote transmission means 38. The signal transmitted by the means automatic alert 29 may also be related to the signals emitted by the device 23 for detecting the withdrawal or the opening of the protection means 32 and / or the detection system 21 for the presence of the defibrillator 10 in its housing 30, which in fact give information on the use of the terminal 10 and the defibrillator 100 by the user. The emergency center 40 can then judge whether the withdrawal or opening of the protection means 32 and the removal of the defibrillator 100 are indeed following an emergency call by a user. The invention proposes a defibrillator terminal reliably guaranteeing the provision of defibrillators in immediate operating state, by means of remote maintenance and a so-called intelligent defibrillator terminal. The defibrillator terminal according to the invention has many applications in everyday life, both in private spaces (businesses, individuals ...) and public (town halls, prefectures ...) or occasional events ( sporting events, cultural events ...). Naturally, the present invention is not limited to the particular embodiment which has just been described but extends to any variant within its spirit.

Claims (14)

REVENDICATIONS1. A defibrillator terminal (10) comprising a housing (20) and a removable defibrillator (100) disposed in a housing (30) of the housing (20) such that the defibrillator (100) can be removed from said housing (30), said defibrillator comprising means (105) for transmitting an omnidirectional test radiation, said terminal (10) being characterized in that the housing (20) comprises means (25) for detecting the omnidirectional test radiation emitted by the defibrillator (100). Defibrillator terminal according to claim 1, wherein the detection means (25) are means for detecting a sound vibration emitted by the defibrillator (100). Defibrillator terminal according to Claim 2, in which the means (25) for detecting a sound vibration comprise means for filtering sound disturbances. 4. Terminal for defibrillator according to one of claims 1 to 3, comprising a detection system (21) the presence of the defibrillator (10) in its housing (30). Defibrillator terminal according to claim 4, wherein the detection system (21) for the presence of the defibrillator (10) comprises a pressure sensor. 6. Defibrillator terminal according to one of claims 1 to 5, comprising means (32) for protecting the housing (30), and a device (23) for detecting the withdrawal or opening of said protection means (32). ). Defibrillator terminal according to one of claims 1 to 6, comprising means for testing (27) the power supply (33) of the housing (20). Defibrillator terminal according to one of claims 1 to 7, comprising automatic warning means (29) of a monitoring center (40). 9. Defibrillator terminal according to one of claims 1 to 8, comprising a test system (28) of the operation of control means (31) of the housing (20). Defibrillator terminal according to one of claims 1 to 9, comprising remote transmission means (32) capable of transmitting signals produced by radiation detection means (25) and / or by a detection system ( 21) and / or by a device (23) for detecting withdrawal or opening and / or by means of test (27) of a power supply and / or by a test system (28) of operation of control means and / or by automatic warning means (29) to a monitoring center (40), for the remote maintenance of said terminal. The defibrillator terminal of claim 10, wherein the remote transmission means (32) comprises a wired telephone line and / or a mobile telephone device. The defibrillator terminal of claim 10, wherein the remote transmission means (32) includes only a mobile telephone device, without the need for a wireline telephone line. Defibrillator terminal according to one of claims 11 or 12, wherein the mobile telephone device operates in roaming mode (roaming mode). The defibrillator terminal according to one of claims 11 to 12, wherein the mobile telephone device comprises a satellite location device, in particular a GPS chip.