CH708729A2 - Remote control system for an electromedical apparatus, in particular an automatic external defibrillator. - Google Patents

Abstract

A remote control system (10) for an electromedical device (3) provides: a remote control device (14), which performs at least a remote control operation of the electro-medical device (3) upon detection of at least one predetermined event associated with the same electromedical device, the remote control device (14) normally maintaining a rest, or stand-by condition. An activation circuit (15), distinct from, and operatively coupled to the remote control device (14) detects the predetermined event and awakens the remote control device (14) so that it exits the rest condition and activates the remote control operation.

Description

Description

[0001] The present invention relates to a remote control system for an electromedical device; in particular, the following discussion tare reference, without thereby losing in généralité, to a system for the remote control of a defibrillator, more precisely of the automatic external type (AED).

[0002] In recent times the use of electromedical devices in generic outdoor environments, or in places generally not used for medical treatments and on the part of the medical device, is spreading for reasons of safety and to guarantee rapid intervention in emergency situations. of non-medical personnel and not having specific training.

[0003] For example, in public places, especially if used for sports purposes, such as gyms or swimming pools, automatic defibrillator devices are installed, to allow emergency resuscitation operations. These automatic defibrillator devices are generally positioned in special cases, or wall-mounted housings, from which they can be taken and used when necessary.

[0004] A particularly felt need, with regard to such electromedical devices, is to guarantee their correct functioning when their use is required. The satisfaction of this requirement is however not easy, given their positioning in public, even outdoors, being therefore subject to possible tampering and in some cases to atmospheric agents, and in virtue, moreover, to prolonged periods of inactivity, which may example involving the exhaustion of a relative source of autonomous electric power, or the emergence of electrical or mechanical problems of various kinds.

[0005] To overcome these problems, and to guarantee the expected functionalities of electromedical devices on an ongoing basis, remote control solutions have therefore been proposed, designed to allow automatic monitoring and control of the same electromedical devices, in particular at a distance, from remote location.

[0006] A telecontrol solution is described for example in patent application WO 201 1/048 286 A1 and implemented in the device called DOC®, marketed by the company BST - Butler Safe Technologies and described at www.doc-saves- lives.com.

[0007] The telecontrol system in question, illustrated in figs. 1 and 2 and generally indicated with the reference numeral 1, comprises a rigid and shell-shaped casing 2 which is fixedly mounted on an electromedical apparatus 3, in particular an external automatic defibrillator, by means of screws, clips, glue or other fasteners.

[0008] The casing 2 comprises two half-portions, a front portion 2a and a rear portion 2b, which interlock with one another on the electromedical apparatus 3 and have a comical shape; the front portion 2a, in particular, is arranged around a user interface of the same electromedical device 3.

[0009] The front portion 2a of the casing 2 further defines, with the rear portion 2b, a seat 5, suitable for releasably accommodating a remote control device 6, provided with an autonomous electric power source (for example a rechargeable type battery ).

[0010] The remote control system 1 further comprises a light sensor 8, shown schematically, carried internally by the casing 2 and operatively coupled to the remote control device 6.

[0011] The light sensor 8 detects the light signal emitted, in use, by a status LED 9a (Light Emitting Diode - light emitting diode), illustrated schematically, of the electromedical device 3. The characteristics of this light signal they are a function of the operating condition of the electromedical device 3, and may indicate: a malfunction, represented for example by a low battery state; an operational stand-by status; or an operational state of use (with relative electrodes applied to a patient) of the same electromedical device 3.

[0012] The light signal is received from a control unit of the remote control device 6, which, based on the same signal, determines the operating condition of the electro-medical device 3.

[0013] The control unit also receives, from an accelerometer integrated in the remote control device 6, a movement signal, indicative of the movement of the electromedical device 3 (as a result, for example, of its removal from a relative wall housing) , for its use in an emergency condition).

[0014] Depending on the determined operating condition and the movement signal, the management unit commands a communication module of the remote control device 6 to emit, via a relative antenna, a radio communication to a remote surveillance station. This radio communication includes the transmission of information on the determined operating condition.

[0015] The communication module is equipped with a SIM card (Subscriber Identity Module), for access to the cellular network, and a suitable cellular transmitter / receiver.

[0016] The remote surveillance station, through radio communication, is made aware of the operating condition of the electro-medical device 3, and in response to this communication it can activate appropriate signals or emergency actions.

[0017] In particular, if a condition of emergency use of the electro-medical device 3 is revealed, the remote surveillance station is able to establish an audio communication through the cellular network for

2 driving in real time an operator of the same electromedical device 3; for this purpose, the communication module of the remote control device 6 is equipped with a microphone and a loudspeaker.

[0018] Furthermore, the remote surveillance station can command the intervention of specialized personnel on the site in which the emergency condition has occurred, where the location is determined by means of a location module, for example satellite GPS (Global Positioning System) of the same remote control device 6.

[0019] Despite having many advantageous features, the remote control system 1 suffers from some problems.

[0020] In particular, the casing 2, during use, in emergency conditions, of the electromedical device 3 constitutes an additional element, which can hinder the normal use of the same electromedical apparatus 3, compromising for example the ergonomics and the ease and convenience of use.

[0021] The presence of the casing 2 and of the relative remote control device 6 can generally interfere with the electrical and mechanical characteristics of the electro-medical device 3, possibly compromising the safety requirements (particularly stringent in the case of this type of apparatus) and / or electromagnetic compatibility.

[0022] In particular, due to its conformation, the casing 2 hides, when coupled to the electromedical device 3, the status LED 9a which indicates any malfunctions of the same electromedical device 3. Consequently, the operator can not have no direct feedback regarding the functionality of the electromedical device 3, in the event that the remote control device 6 is faulty or unloaded.

[0023] In this regard, it has furthermore been verified that the battery of the remote control device 6 is not able to guarantee a high autonomy, requiring frequent recharges from the electric network (or from another source of external electric power). Consequently, the possibility that a condition occurs in which the remote control device 6 does not operate correctly, due to a low battery state, is not infrequent.

[0024] The object of the present invention is therefore to provide a remote control system for an electromedical device, which allows to overcome, in whole or at least in part, the problems associated with known solutions.

[0025] According to the present invention a telecontrol system is therefore provided, as defined in the attached claims.

[0026] For a better understanding of the present invention, preferred embodiments thereof are now described, purely by way of non-limiting example and with reference to the accompanying drawings, in which: FIG. 1 is an exploded perspective view of a known type of remote control system for an electromedical apparatus; fig. 2 is a perspective view of the remote control system of fig. 1, mounted on the electro-medical device; fig. 3 is a block diagram of a remote control system for an electromedical device, according to an aspect of the present solution; fig. 4 is a flow chart relating to operations carried out by a circuit for activating the remote control system of fig. 3; fig. 5 is a block diagram of a remote control device of the telecontrol system of fig. 3; fig. 6 is a flow chart relating to operations performed by the remote control device of fig. 5; fig. 7 is a perspective view of a housing housing the remote control system of fig. 3, in an open configuration; fig. 8 is a perspective view of components of the remote control system of Fig. 3; fig. 9 is a perspective view of the housing housing the remote control system of fig. 3, in a closed configuration; fig. 10 is a perspective view of an enclosure housing the telecontrol system, in an open configuration, according to a further embodiment; fig. 1 1 shows, broken away, the assembly of a container and a battery in the remote control system of fig.

10; and fig. 12 is a perspective view of an enclosure housing the telecontrol system, in an open configuration, in a still further embodiment.

[0027] With reference to fig. 3, a telecontrol system is now described, indicated in general with 10, for an electromedical apparatus, for example for a defibrillator, in particular of the external automatic type.

3 [0028] According to an aspect of the present solution, and as will be clarified in detail below, the remote control system 10 is distinct and separate from the electromedical apparatus, thus not interfering with use during an emergency condition, but at the same time it is coupled to the electromedical device, so as to be close to the same electromedical device during the emergency condition and thus allow its location and also the assistance to the operator.

[0029] In particular, the remote control system 10 comprises a status sensor 12, configured to detect information associated with an operating status of the electromedical device.

[0030] The electro-medical apparatus can for example be provided with a status LED, which emits a luminous signal indicative of an operating status of the apparatus itself, such as: a malfunction, represented for example by a low battery state (to which corresponds to switching off the status LED); an operational stand-by status (which corresponds to an intermittent flashing of the status LED, with a certain interval or périodicité); or a state. operational use of the same electromedical device, with relative electrodes applied to a patient (which corresponds to a continuous activation of the status LED over time).

[0031] The state sensor 12 can in this case comprise a light detector, such as for example a photodiode or other kind of photo-detector, arranged so as to detect the luminous signal emitted by the status LED of the electromedical device .

[0032] The remote control system 10 further comprises: a remote control device 14; an activation circuit 15, operatively coupled to the remote control device 14; and a power supply module 16.

[0033] The power supply module 16 comprises: a battery 17, for example of the Lithium type, for example providing an output voltage equal to 3.6 V and having a high capacity, for example equal to 26 Ah; and a voltage regulation circuit 18, electrically connected to the battery 17 to adjust an output voltage Vout.

[0034] The remote control device 14 has the functionalities of: geographically localizing the system itself and the electromedical device to which it is associated; establish a data communication and, if necessary voice, with a remote surveillance station, a service center or a service center; and, in particular, to send position data and data relating to conditions or parameters of use of the electro-medical device to the remote monitoring station (including any failures, operating states, operating anomalies).

[0035] The remote control system 10 further comprises: a microphone / speaker module 19, which is operatively coupled to the remote control device 14, to allow an operator to perform a voice communication, for example with the aforementioned remote monitoring station ; and a light-emitting element 9b, for example of the LED type, whose function will be explained later.

[0036] According to an aspect of the present solution, the activation circuit 15 is configured to detect an operating state of the electro-medical apparatus and to send to the remote control device 14 a status signal indicative of the detected operating state.

[0037] The same status signal, or a different and further activation signal (so-called interrupt signal) appropriately generated, is used to awaken the functions of the remote control device 14 from a state of rest or stand-by, with reduced consumption energy (so-called wake up function), upon detection of certain operating conditions of the electro-medical device.

[0038] In particular, the activation circuit 15 is configured to wake up the remote control device 14 upon detecting particular events, and also to send messages with well-defined encodings, such as to allow the same remote control device 14 to discriminate the nature of the events detected.

[0039] In greater detail, the activation circuit 15 comprises a processing unit 20, including for example a microcontroller, a microprocessor or similar digital processing element, which is connected to the status sensor 12, to receive the associated information to the operating status of the electro-medical device, for example according to the light signal detected by the relative photo-detector.

[0040] The activation circuit 15 further comprises an accelerometric sensor 22, in particular of the triaxial type (ie capable of detecting accelerations acting along each of three directions defining a set of orthogonal axes).

[0041] The processing unit 20 receives as input the acceleration signals detected by the accelerometric sensor 22, indicative of movements associated with the electromedical apparatus (due, for example, to its removal from a relative housing, for its use in an emergency condition).

[0042] The activation circuit 15 further comprises a driving stage 26, controlled by the processing unit 20 and configured to generate a suitable driving signal for the light emitting element 9b of the remote control system 10.

[0043] In particular, for reasons to be clarified below, the light-emitting element 9b is driven so as to emit a luminous signal which is completely equivalent to that emitted by a status LED of the electromedical device which is monitored (for example, having the same intermittent pattern, the same light characteristics, etc.), thus acting as a repeater of the same light signal.

4 [0044] In use, reference should also be made to fig. 4, the processing unit 20 acquires and processes the acceleration signals and the status signal (step 30) and, as a function of these signals, determines the occurrence of events requiring the activation of the remote control device 14 (phase 31).

[0045] Such events may for example comprise one or more of the following:

- a failure of the electro-medical device (phase 32), which corresponds for example to the absence of a light signal received, or an irregular, unforeseen trend of the same light signal within a given time interval;

- a state of movement associated with the electromedical apparatus (step 33), such movement having certain characteristics, for example indicative of the movement of the electro-medical apparatus from a seat in which it is normally housed in the rest or stand-by condition, and being associated with detected acceleration signals, having certain expected characteristics; or

- use of the electromedical device (step 34), which corresponds for example to the continuous presence of the light signal for a duration greater than a given time interval (the light signal detected being in this case associated with the ambient light, for opening of an enclosure in which the electro-medical device is housed, as will be explained in detail later on).

[0046] Following the determination of the occurrence of one of the events reported above, the processing unit 20 generates an interrupt signal INT, phase 36, destined to be received by the remote control device 14 to determine its awakening, and furthermore a information signal INF, which carries the information relating to the type of event detected, which is also intended to be received by the remote control device 14.

[0047] In greater detail, according to an aspect of the present solution, the processing unit 20 is configured to store and execute a computer program (so-called "firmware") which provides for: determining a movement condition of the electromedical device , depending on the characteristics (for example in terms of amplitude and frequency) of the acceleration signals acquired by the accelerometric sensor 22; and, following the determination of the movement condition, performing an elaboration and filtering of the acceleration signals acquired by the accelerometric sensor 22, by means of a suitable processing and filtering algorithm.

[0048] This processing and filtering algorithm, on the basis of the analysis of averages performed on a sample acquisition or test acquisitions performed during the movement, evaluates whether the type of movement detected (in terms, for example, of the extent and duration) may be attributable to a real displacement of the electromedical device for its use (for example, to a withdrawal of the same electromedical device from its housing seat), or may be due to vibrations, temporary shocks suffered by the electro-medical device (in general, to spurious noise events).

[0049] Only if it determines the presence of an effective shift, the processing unit 20 proceeds to the generation of the interrupt signal INT and of the information signal INF, in the aforementioned step 36.

[0050] Otherwise, and in general in the case where a significant event is not detected, the processing unit 20 discards the acquisitions of the acceleration and status signals, as they are not considered relevant, returning to step 30 for acquisition of new samples of the same signals.

[0051] Referring now to fig. 5, the architecture of the remote control device is described in greater detail 14.

[0052] This remote control device 14 may optionally comprise a control unit 40, including for example a microcontroller, a microprocessor or a similar digital processing element, intended to be electrically coupled to the processing unit 20 of the activation circuit 15 to receive the interrupt signal INT and the information signal INF.

[0053] In an alternative embodiment, the same processing unit 20 of the activation circuit 15 can control the operation of the remote control device 14, which in this case does not have its own control unit.

[0054] The remote control device 14 further comprises a location module 41, for example a satellite of the GPS type (Global Positioning System), operatively coupled to the control unit 40; and a communication module 42, controlled by the control unit 40 and coupled to an antenna 43, - to transmit / receive radio communications to / from a remote surveillance station, indicated schematically by 45. The information transmitted includes information on the events associated with the electromedical device, detected and signaled by the activation circuit 15, and / or location information, which the control unit 40 obtains from the location module 41.

[0055] The communication module 42 can be equipped with a SIM card (Subscriber Identity Module), for access to the cellular network, and a suitable cellular transmitter / receiver.

[0056] The communication module 42 is also operatively coupled to the microphone / loudspeaker module 19, to allow a voice communication between the operator of the electro-medical device and the. monitoring station 45.

[0057] In a possible embodiment, the remote control device 14 can comprise an internal power source 48, for example of the lithium ion type, having a reduced capacity, for example equal to 1 100 mA / h (much lower with respect to the capacity of the battery 17 of the supply module 18); in this case the internal power source 48 supplies the control unit 40, the localization module 41 and the communication module 42, in the condition

5 of operation. In a possible embodiment, the remote control device 14 can further comprise a casing 49 (shown schematically in Fig. 5), which encloses and houses the components listed above, constituting a protection and an interface with respect to the external environment.

[0058] However, it is emphasized that, as will also be illustrated in. subsequently, the remote control device 14. can alternatively be realized in a circuit integrated with the activation circuit 15, in this case neither the housing 49 nor the internal power source 48 is provided. In this case, the remote control device 14 and the activation circuit 15 are realized in a single electronic card, housed inside the same container, and are also supplied by a same power supply source (in particular, the battery 17 of the power supply module 16).

[0059] In use, reference is also made to fig. 6, with the remote control system 10 operating (on, or electrically powered), the remote control device 14 normally remains in a standby (or "stand-by"), energy saving condition (phase 50), with both modules location and communication 41, 42 in an off or disabled state, until it receives the interrupt signal INT from the activation circuit 15 (step 51).

[0060] As previously highlighted, this interrupt signal INT is indicative of the detection of a predetermined event associated with the electro-medical device, such as a failure, an abnormal operation or the use of the same electromedical device in an emergency condition. The interrupt signal INT can be advantageously received at an interrupt input of the microprocessor or microcontroller of the control unit.

10 40. After receiving the INT interrupt signal, the remote control device 14 implements appropriate remote control actions; in particular, the control unit 40 can process the information signal INF (step 52), to determine the type of the event detected by the activation circuit 15, and consequently implement the appropriate telecontrol actions (step 53). Such remote control actions, as previously highlighted, may for example include; sending / receiving information to / from the monitoring station 45 and / or establishing a voice communication with an operator of the electro-medical device through the communication module 42 of the remote control device 14.

[0061] Alternatively, in the case where the control unit 40 is not present, the interrupt signal INT can directly awaken one or more components of the remote control device 14 to. activate the appropriate remote control actions required.

[0062] According to a particular aspect of the present solution, which is now discussed with reference to FIG. 7, 8 and 9 ,. the remote control system 10 further comprises a housing 60, adapted to house the electromedical apparatus, here again indicated with 3, and together the other constituent elements of the same remote control system 10, namely: the status sensor 12; the remote control device 14; the activation circuit 15; the power supply module 16; and the light-emitting element 9b.

[0063] In particular, the housing 60 has a suitcase conformation, having two halves, a lower half 60a and an upper half 60b, coupled for example by a hinge 61, which extends along a respective perimeter, or edge, with the exception of of a junction portion 63; both the lower and upper halves 60a, 60b have a tank shape, having a bottom and side walls defining a recess and at least one seat (alternatively, - the two halves can be coupled by means of a different, coupling system, for example of the "tear" type).

[0064] In particular, the lower half 60a is configured to house the electromedical device 3, which is positioned so as to present an upper face, which carries a relative user interface and moreover the status LED 9a, arranged at a distance from the bottom of the same lower half 60a.

[0065] The upper half 60b is shaped (having suitable partitions and separation walls, generally indicated with 65), to define: a first seat 66a, intended to house the battery 17 of the supply module 16; a second seat 66b, intended to house the status sensor 12, so that the relative light detector is arranged at a distance from the bottom of the upper half 60b, facing the status LED 9a when the lower and upper half 60a, 60b of the housing 60 are coupled to each other (i.e., when the housing is closed, a condition illustrated in FIG. 9); and a third seat 66c, intended to house a container ("box") 68.

[0066] The second seat 66b is also intended to house, in a position adjacent to the bottom of the upper half 60b, the light-emitting element 9b (as illustrated in Fig. 9); the same bottom of the upper half 60b presents, at said light emitting element 9b, a window 69 (see in particular the same fig. 9), through which the light emitting element 9b emits a light radiation, in this way is visible from the outside of the housing 60.

[0067] Advantageously, this feature allows a user to monitor the operating status of the electromedical device 3 without having to open the housing 60 or remove the same housing 60 from a seat in which it is housed, since it can in fact observe the light signal emitted by the light emitting element 9b, which, as previously highlighted, replicates the light signal emitted by the status LED 9a of the same electromedical device 3.

[0068] In greater detail, reference should also be made to fig. 8, the container 68 disposed in the third seat 66c is configured to house inside it: the location device 14 (which can be equipped with its own casing 49, as shown in Fig. 7, or be integrated together with the activation circuit 15 in the same envelope); the activation circuit 15 (shown schematically); the voltage regulation circuit 18 of the power supply module 16; and

11 microphone / speaker module 19.

6 [0069] In particular, the container 68 presents a generically parallelepiped conformation, with a front main face 68a and a rear main face 68b (illustrated partially removed in Fig. 8, so as to show the interior of the same container 68 ), the latter intended to be positioned in contact with the bottom of the upper half 60b of the housing 60.

[0070] The front main face 68a can present a window 69, in correspondence with which the casing 49 of the remote control device 14 (in case it is present) faces, so as to address a respective user interface (including for example of keys, buttons and status LEDs towards the outside of the same container 68. Alternatively, the same front main face 68a can carry the aforementioned user interface, in the event that the casing 49 of the remote control device 14 is not present; as illustrated below).

[0071] The container 68 also carries: a first connector 70a, adapted to receive a first connection cable 71 a for the electrical connection with the battery 17, which carries the feed signal Vai; a second connector 70b, adapted to receive a second connection cable 71 b, for the electrical connection with the status sensor 12 and with the light-emitting element 9b; and a switch 72, operable to control the selective activation of the remote control system 10 by an operator.

[0072] Inside the container 68, suitable electrical connection elements, indicated in general with 73 (and not all illustrated in Fig. 8), also connect: the first connector 70a to the voltage regulation circuit 18 of the module power supply 16; the regulation circuit 18 to the activation circuit 15; the activation circuit 15 to the remote control device 14 and to the second connector 70b (not shown in the same Fig. 8); and the remote control device 14 to the microphone / speaker module 19.

[0073] Conveniently, as shown in FIG. 7, a closing element 74, having a bulkhead conformation, fixed to a lateral inner wall of the upper half 60b of the housing 60, is available above the bottom of the upper half 60b itself, to cover and avoid the leakage of the battery 17 and of the container 68.

[0074] In particular, it has become apparent from what has been described that the accelerometric sensor 22 of the activation circuit 15 is in fact integral with the housing 60 of the remote control system 10, in particular with the upper half 60b of the same housing 60.

[0075] Therefore, in this embodiment, the acceleration signals generated by the same accelerometric sensor 22 are indicative of the displacement of the housing 60, for example for its removal from a relative housing, and / or of the opening of the same housing 60 , with the removal of the upper half 60b from the lower half 60a of the same housing 60.

[0076] Advantageously, the processing unit 20 of the activation circuit 15 is therefore configured to process these acceleration signals, with the possibility also to discriminate between displacement events of the housing 60 or opening events of the same housing 60, generating corresponding information for the remote control device 14 (via the information signal INF).

[0077] Moreover, in this embodiment, the status sensor 12, when the housing 60- is open, or when the upper half 60b is not facing the lower half 60a, - detects a condition of continuous light, and therefore generates a status signal having a constant trend over time, or in any case non-zero. This characteristic of the status signal can therefore be detected by the processing unit 20 of the activation circuit 15 as proof of the possible use of the electro-medical device 3.

[0078] The advantages of the solution described emerge clearly from the previous discussion.

[0079] In particular, it is emphasized that the remote control system 10 is not mounted on the electro-medical apparatus 3 of which it performs monitoring and surveillance, as in traditional solutions, and therefore does not interfere in any way with the same electromedical device 3, without altering the mechanical and / or electrical characteristics. In fact, the electro-medical apparatus 3 is housed in the housing 60, from which it can be extracted and used by the operator without any obstruction or additional element.

[0080] The remote control system 10 does not even hinder the detection by the operator of the operating status of the electro-medical device 3; the status LED 9a of the same electromedical device 3 is not only visible once the housing 60 is opened, but is also replicated externally to the same housing 60, through the light emitting element 9b piloted by the remote control system 10.

[0081] Furthermore, the autonomy of the remote control system 10 is considerably increased compared to known remote control solutions.

[0082] In fact, the activation circuit 15 alone is temporarily active, for monitoring the acceleration and status signals, while the remote control device 14 is normally in a very low energy consumption stand-by condition. being awakened, and therefore absorbing energy from the relative power source, only to the detection of predetermined events by the activation circuit 15.

[0083] Tests conducted by the Applicant have shown that the power supply module 16 is able to ensure the power supply of the activation circuit 15, and therefore the correct operation of the. remote control system 10,

7

Claims (17)

without requiring refills from external power sources, for extended periods of time, for example for a period of 30 months. [0084] A further advantage of the present solution is represented by the accuracy with which the events associated with the electro-medical apparatus 3 are detected, thanks to the presence of the activation circuit 15, separate and independent from the remote control device 14. [0085] The remote control system 10 is further configured to allow the use of remote control devices 14 also of a known type, possibly already present on the market, by providing a suitable electrical interface with the activation circuit 15. [0086] Furthermore, advantageously, the remote control system 10, being housed in the same housing. 60 of the electromedical apparatus 3, follows the same electromedical apparatus 3 once taken by the user from a respective case or housing, thus allowing accurate location of the same apparatus and continuous communication with the operator during use in conditions of emergency. [0087] Finally, it is clear that modifications and variations may be made to what is described and illustrated herein. without for this departing from the scope of protection of the present invention, as defined in the attached claims. [0088] In particular, the remote control system 10 can advantageously include a distinct sensor for opening the housing 60, for example a reflection sensor, for example an infrared sensor, suitable for detecting the opening of the housing itself and providing a suitable signal. opening to the activation circuit 15 or directly to the remote control device 14. In this case, the information provided by the opening sensor can be processed jointly with, or independently of, the information provided by the accelerometric sensor 22 and / or by the status sensor 12. The opening sensor could possibly be made as a contact switch or a pressure cleaner, which detects the opening of the housing 60. [0089] Moreover, as shown in fig. 10, a different, currently preferred, embodiment of the housing 60 can be provided, which provides for the use of a single housing, - again indicated with 68, for example made by molding, designed to house both the remote control device 14 and the activation circuit 15, made integrally in a printed circuit board (not shown as it is contained in the aforementioned casing 68). [0090] As illustrated also in fig. 11, the battery 17 for power supply of the remote control device 14 and of the activation circuit 15 can in this case be coupled releasably, by means of suitable hooking elements, to the casing 68, so as to constitute, when attached, a single box-shaped body to be housed in the second half 60b of the housing 60. [0091] This embodiment is advantageous, since it allows to reduce the construction costs and simplify the assembly of the remote control system 10 and of the relative housing 60. [0092] Like shown in fig. 12, a further preferred embodiment provides that the casing 68 has an external surface 68a, which carries a user interface 72, which includes suitable buttons, and also the microphone / speaker module 19, to allow the user to carry out appropriate remote control functions, as discussed above. In the embodiment of fig. 12, the battery 17 has a shape that is substantially square, rather than rectangular. [0093] Finally, it is emphasized again that the remote control system 10 can be advantageously used for the surveillance and remote control of various types of electromedical devices, in addition to an external automatic defibrillator, to which it was previously made specific reference, in general for the control of electromedical devices whose operating status is indicated by a status LED (or similar indicator element). claims 1. Telecontrol system (10) for an electromedical apparatus (3), comprising: a housing (60), adapted to house said electromedical apparatus. (3); wherein said housing (60) has a suitcase conformation, having two mating halves: a first half (60a), configured to house said electromedical device (3); and a second half (60b), which can be coupled to said first half (60a) so as to close above the same first half (60a); a remote control device (14), configured so as to perform at least one remote control operation of said electromedical apparatus (3) upon detection of at least one predetermined event associated with said electromedical device (3), in which said remote control device (14 ) is normally configured in a state of rest, or stand-by, with reduced energy consumption; and in that it comprises an activation circuit (15), operatively coupled to said remote control device (14), configured so as to detect said predetermined and awakening event, said telecontrol device (14) so that it exits said rest condition and activates said remote control operation; wherein the second half (60b) of said housing (60) is adapted to house said telecontrol device (14) and said activation circuit (15). 8 2. System according to Claim 1, in which the said activation circuit (15) comprises a processing unit (20), configured so as to generate an activation signal (INT) for the said remote control device (14), designed to awaken said remote control device (14) from said rest condition. 3. System according to claim 2, wherein said activation circuit (14) integrates an acceleration sensor (22), configured so as to detect movements associated with said electromedical device (3) and / or said housing (60); and wherein said processing unit (20) is configured so as to process acceleration signals received from said acceleration sensor (22) to generate said activation signal (INT). 4. System according to claim 3, wherein said processing unit (20) is configured so as to process said acceleration signals to discriminate said displacements, from noise signals. 5. System according to any one of Claims 2 to 4, further comprising a status sensor (12), configured so as to detect an operating state of said electromedical device (3), and operatively coupled to said activation circuit (15); and wherein said processing unit (20) of said activation circuit (15) is configured to generate said activation signal (INT) also as a function of the operating state detected by said state sensor (12). 6. System according to claim 5, wherein said state sensor (12) comprises a light radiation detector, able to detect an emission of light radiation coming from a first emitter of light radiation (9a) carried by said electromedical apparatus ( 3), indicative of the operating status of the same electromedical device (3). 7. System according to claim 6, further comprising a second emitter of light radiation (9b), carried by the second half (60b) of said housing (60) and able to be driven so as to emit a second emission of light radiation, corresponding to said first light radiation; wherein said housing (60) presents a window (69) in correspondence with said second half (60b), able to allow the emission of the second light radiation emitted by said second emitter of light radiation (9b) towards the outside of said housing (60). 8. System according to Claim 7, in which the said activation circuit (15) is configured so as to drive the said second emitter of light radiation (9b) to emit the said second emission of light radiation, in a manner corresponding to the said first light radiation. 9. System according to any one of Claims 2 to 8, in which the said activation signal (INT) is an interrupt signal, able to be received by a control unit (40) of the said remote control device (14), on a related interrupt input. 10. System according to claim 9, wherein the remote control device (14) is provided with its own casing (49) which encloses and houses said control unit (40); and wherein said processing unit (20) of said activation circuit (15) is external to said casing (49). 1 1. System according to claim 10, comprising a container (68), housing inside said activation circuit (15) and having an outer surface (68a) defining a seat (69) for said remote control device (14); wherein said second half (60b) of said housing (60) is configured to house said container (68). 12. System according to any one of the preceding claims, comprising a container (68), housing inside said said activation circuit (15) and said remote control device (14) and having an outer surface (68a) defining a user interface (80 ) for said remote control device (14); wherein said second half (60b) of said housing (60) is configured to house said container (68). 13. System according to claim 12, further comprising a power supply module (16), including a battery (17), operatively coupled to said activation circuit (15) and to said remote control device (14), to supply electric power; wherein said battery (17) is releasably coupled to said container (68). 14. System according to any one of the previous claims, wherein said remote control operation performed by said remote control device (14) comprises one of: the geographical location of said electromedical device (3); the establishment of a communication via radio of data and / or voice with a remote location (45); sending to the remote location (45) of position data and operating parameters associated with said electromedical device (3). 15. System according to any one of the preceding claims, in which the said remote control device (14) and the said activation circuit (15) are distinct and separate with respect to the said electromedical device (3). 16. Housing (60), shaped like a case, for the telecontrol system (10) according to any one of the previous claims, configured so as to include an electro-medical apparatus (3) therein. " 17. Housing according to claim 16, wherein said electromedical apparatus (3) is an external automatic defibrillator. 9