Electrical installation having an emergency signal input for receiving an emergency signal transmitted by radio

Various aspects of the present disclosure are directed to a system for increasing the protection against electric shocks of a person working in proximity to an electrical system. In one example embodiment, the system includes a plurality of first radio terminals, via each of which a radio link for receiving an emergency signal can be established. The system further including a protective device to be worn by the person and for detecting an electrical body current. The protective device including a second radio terminal that, in the event that an unacceptable body current is detected, outputs and transmits an emergency signal via a radio link established between one of the first plurality of radio terminals and the second radio terminal.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a national stage filing based upon International PCT Application No. PCT/EP2019/066125, filed 19 Jun. 2019, which claims the benefit of priority to Austria application No. A 50516/2018, filed 21 Jun. 2018.

BACKGROUND

The present invention relates to an electrical system having an emergency signal input for receiving an external emergency signal sent via a radio link, wherein a predetermined action is triggered in the electrical system when the emergency signal is received. The invention also relates to an arrangement and a method to perform work on the electrical system by a person.

It is common in electrical systems, especially in an industrial environment, to provide an emergency stop in order to switch off a conducting or live component that is part of the emergency stop circuit if a person touches the same. With such safety devices, the protection against electric shock due to an unintentional contact of people working on conducting parts or live parts can be increased by other people present triggering the emergency stop in the event of a fault. However, this requires that at least one further person is in the vicinity of an electrical accident and has knowledge of the electrical accident, which is not always the case.

Other common safety devices in electrical systems are circuit breakers for switching off circuits in the event of an unacceptable electrical current and ground-fault circuit interrupters that are intended to respond in the event of unacceptable earth fault currents. However, these can only provide protection if they actually trip in the event of an error. Due to possible high operating currents or slow reaction times, there may be a danger for people working on the electrical system despite such safety devices.

Methods and devices for a better protection of persons against unacceptable electrical body currents are therefore already known. DE 39 03 025 A1, for example, describes such a method and such a device, wherein an electrode connected to a control device is arranged on at least two extremities of the person, for example on the arms or legs. Via the electrodes, the control device detects a body current caused by a contact with an external electrical potential. If such a current flow is detected, the control device activates a shutdown device with which the further supply of current to the contact point is interrupted. The electrodes and the control device can be arranged on an item of clothing with a wireless connection between the control device and the switch-off device. DE 44 38 063 A1 describes a similar protective device. Such protective devices can increase the safety of persons working on conducting parts or live parts against electric shock due to unintentional contact.

In the case of a wireless connection between the control unit and the disconnection device, the function of the protective device also depends on whether there is a radio channel for the data transmission. This can be problematic in large electrical systems or in buildings if it is not noticed that the radio channel between the control unit and the disconnection device is interrupted, for example if the person is in a radio shadow, or if the radio channel is impaired, for example by electromagnetic interference fields in the vicinity of electrical systems.

It is therefore the object of the present invention to increase the safety of persons in the area of an electrical system against electric shock when touching conducting or live parts of the electrical system.

SUMMARY OF THE INVENTION

According to the invention, this object is achieved in that a plurality of first radio terminals are provided on the electrical system, via each of which a radio link for receiving the emergency signal can be established. This way, even in large or distributed electrical systems, the probability can be increased that at least one radio link can be established to receive an emergency signal. A disruption of the radio link for transmitting the emergency signal, in particular one that is unnoticed, can thus be largely avoided.

A person working on the electrical system preferably wears a protective device for detecting an electrical body current, with a second radio terminal being provided on the protective device and, in the event of an unacceptable body current being detected, the protective device outputs and transmits an emergency signal to the emergency signal input via a radio link generated between one of the first radio terminals and the second radio terminal. As soon as the protective device detects an unacceptable body current (which can be configured accordingly), an emergency signal is triggered, which then triggers the preset action. In this way, the protection of the person is no longer tied to the presence of another person or on the activation of other safety devices.

Further advantageous embodiments and effects of the invention can be gathered from the dependent claims and the following description.

DETAILED DESCRIPTION

The present invention uses a protective device1, the basic function of which is known from prior art and which is explained in more detail with reference toFIG. 1for a better understanding. The protective device1, or at least parts thereof, is arranged on or integrated in an item of clothing2, in this case a shirt. Of course, other items of clothing2, for example trousers, a sweater, a T-shirt, a jacket, overalls, etc., can also be used. Even combinations of several items of clothing2are also possible, for example a combination of trousers and shirt, etc. At least one sensor3is arranged on the item of clothing2in order to detect an electrical body current flowing through the human body. Electrodes5can, for example, be used as a sensor3in order to detect an electrical potential or an electrical current. The electrodes5are preferably arranged at exposed locations on the item of clothing2, for example in the region of the extremities, i.e., for example on sleeves, trouser legs or hoods. A biometric sensor7can also be used as a sensor3in order to detect a biometric signal, for example the heart rate, the amplitude or the course of the heartbeat, the respiratory rate, the skin resistance, etc. By evaluating the biometric signal, in particular the heartbeat (frequency, amplitude and/or course), conclusions can also be drawn about a flowing electrical body current.

For this purpose, the sensor3, or the sensors, can preferably be integrated in the item of clothing2but can also be applied separately, for example by means of a cuff, bracelet or belt. In a possible embodiment, a sensor3could be designed as an electrode5in the form of a known Rogowski coil (as inFIG. 1) in order to detect an electrical current flowing through an extremity or another part of the human body. For this purpose, the electrode5can be placed in a ring around an extremity, for example in a waistband of a sleeve or a trouser leg of the item of clothing2. In order to detect an electrical potential, the electrode5must be in contact with the skin in an electrically conductive manner, whereas this would not be absolutely necessary in the case of a Rogowski coil, for example. In order to detect the heartbeat, a corresponding biometric sensor7, for example a heart rate sensor, could be integrated in the item of clothing2in the region of the chest, or a corresponding chest strap could be applied.

A sensor3is connected via at least one signal line4to an evaluation unit6(for example, in the form of a computing unit, possibly also with corresponding software). The signals detected by the at least one sensor3are evaluated in the evaluation unit6. An electrical potential detected with an electrode5as the sensor3or a detected flowing electric current can be evaluated, for example. An applied electrical voltage can be determined between two detected electrical potentials, for example with two sensors3designed as electrodes5, and evaluated in the evaluation unit6. A resistance measurement can also be carried out regularly or continuously between two electrodes5in order to check whether the item of clothing2is properly connected to the body of the person8. The evaluation of the body current or of a potential difference can likewise be carried out with suitable hardware or digitally, which requires an A/D conversion and the corresponding hardware and software. In the event that a dangerous body current is detected, for example when an abnormal heartbeat, a dangerous current flow or a dangerous potential difference (voltage) between two electrodes5is detected, which in turn indicates a current flow through the body, the evaluation unit6generates an emergency signal S which can be used to trigger a desired action. For this purpose, corresponding limit values for an acceptable body current, for example an acceptable potential difference or an acceptable current, can of course also be stored or specified in the evaluation unit6, which can also be adjustable. Likewise, patterns of a biometric signal that indicate a dangerous body current can also be stored in the evaluation unit6.

Advantageously, different sensors3can be provided on the item of clothing2in order to increase the reliability of the detection of dangerous electrical body currents. For example, electrodes5could be provided on extremities and additionally a biometric sensor7for detecting the heartbeat, as shown inFIG. 1.

The safety of the protective device1can also be increased by providing redundancies. For example, more than one signal line4can be provided per sensor3so that possible cable breaks or contact errors do not have to lead to a failure of the safety function, or a cable break or contact error can even be recognized and possibly also indicated.

The evaluation unit6is preferably held or carried by the person8who wears the protective device1. This evaluation unit could be arranged, for example, in a shoulder bag or a backpack, but could also be pouched into a pocket of the item of clothing2or could also advantageously be integrated, wholly or partially, in the item of clothing2, for example in the form of an intelligent item of clothing with integrated electronics.

The protective device1thus consists, for example, of an item of clothing2with at least one sensor3and an evaluation unit6which is connected to the at least one sensor3by at least one signal line4and which evaluates a signal detected by the sensor3in order to detect a dangerous electrical body current. The emergency signal S of the evaluation unit6, or generally of the protective device1, can be used by the electrical system10or parts thereof to set certain configured actions in order to increase the protection of a person8against electric shock. Preferably, switching actions are configured in order to disconnect the electrical system10or parts thereof from voltage.

This is explained by way of example with reference toFIG. 2, which shows a device11as an example of an electrical system10or part of an electrical system10. A current and/or voltage generator25is provided in the device11, which generates the required electrical currents and/or voltages at the current and voltage outputs22of the device11. For this purpose, the device11is connected to a power supply24, which can be external (for example, a power grid or an external battery) or also internal (for example, in the case of a battery-operated device). In the device11, a disconnection unit23is provided between the current and/or voltage generator25and the current and voltage outputs22. The disconnection unit23could, however, also be provided upstream from the current and/or voltage generator25or at another suitable point in the device11. The disconnection unit23can, of course, also have a multi-pole design, depending on the number of current and voltage outputs22. The emergency stop switch20, when actuated, activates the disconnection unit23, for example a disconnection relay, in the device11, which switches off and/or short-circuits the current and voltage outputs22of the device11. An emergency signal input21is additionally provided on the electrical system10, which, when an emergency signal S is received, in particular from the protective device1, actuates the disconnection unit23of the emergency stop circuit. According to the invention, the emergency signal input21is consequently also connected to the disconnection unit23and activates the disconnection unit23when an emergency signal S is received via the emergency signal input21. However, several serially connected disconnection units23, each of which is controlled separately, could also, of course, be provided in the device11with the same effect, for example a disconnection unit for the emergency stop switch20and a disconnection unit23for the emergency signal input21. The emergency signal input21does not necessarily have to be integrated into the electrical system10, but could also be designed as a separate unit that is connected to the electrical system10in a suitable manner.

Other examples of an electrical system10are an electrical energy distribution network in a building or an electrical energy supply in a production system, in which an emergency stop circuit does not necessarily have to be provided, but in which an emergency signal input21is provided for receiving an emergency signal S to make it possible to trigger a configured (switching) action in the electrical system10.

The electrical system10, or a part thereof, can also, of course, be switched off in other ways. A switch could be activated, for example. Likewise, a circuit could be short-circuited (for example, by connecting a phase to the neutral conductor) in order to trigger a circuit breaker to disconnect the circuit from the network. A sufficiently high ground fault current could also be generated (for example, by connecting a phase to the ground with a resistor) to trip a ground-fault circuit interrupter. There are, of course, also other options for switching off the electrical system10or parts thereof.

The invention assumes that the emergency signal S is emitted wirelessly and received wirelessly at the emergency signal input21. For this purpose, a suitable radio link can be provided between the protective device1and the emergency signal input21, for which existing standards can also be used. This naturally means that a first radio terminal90is provided on the emergency signal input21and a second radio terminal91is provided on the protective device1, between which the radio link is established. The radio link can also be bidirectional.

The second radio terminal91of the protective device1is preferably arranged on the item of clothing2or integrated into the item of clothing2(e.g., again in the form of intelligent clothing with integrated electronics) and connected to the evaluation unit6or another control unit in the protective device1.

In certain applications, for example in buildings or on large electrical systems, the radio link between the protective device1and the emergency signal input21can be interrupted easily and without noticing, in particular when the person8wearing the protective device1is moving. This can lead to false activations of the protective device1if a missing radio signal in the emergency signal input21triggers a switching action. In the worst case, the protective device1no longer provides protection for the person8carrying said device with this circumstance going unnoticed.

The electrical system10could also be configured differently depending on how dangerous the application is so that an interruption of the radio link forces a switch-off if the application is very dangerous but does not do so if the application is less dangerous.

In order to prevent an unnoticed interruption of the radio link, it is provided according to the invention that a plurality of first radio terminals90a,90bare spatially distributed in the region of the electrical system10, as shown inFIG. 3. An emergency signal input21can be integrated in a first radio terminal90a,90bsuch that a first radio terminal90a,90bwith the emergency signal input21triggers the intended action in the electrical system10, as shown inFIG. 3. The emergency signal input21can also be implemented in the electrical system10and connected to the plurality of first radio terminals90a,90b, as shown inFIG. 4. Mixed forms are conceivable as well.

The second radio terminal91of the protective device1can establish a radio link to each first radio terminal90a,90b.

In a simple embodiment of the invention, all the first radio terminals90a,90buse the same radio channel for the radio link. If the first radio terminals90a,90bare arranged sufficiently close, it can be assumed that there is always at least one radio link between a first radio terminal90a,90band the second radio terminal91on the protective device1, via which an emergency signal S can be transmitted. The arrangement of the first radio terminals90a,90bon the electrical system10can of course be planned accordingly.

In an improved embodiment, the radio link is a multichannel link with at least enough channels that a radio link can always be established via a clearly identifiable radio channel. This means that different radio channels do not necessarily have to be assigned for all first radio terminals90a,90b, but rather the same radio channels can also be used in different first radio terminals90a,90b, provided the radio channels do not overlap. However, each first radio terminal90a,90bcan of course also have its own radio channel assigned. Any multichannel radio links can be used here, for example on the basis of frequency division multiplex or time division multiplex. An example of a suitable radio link is a Long Range Network (LoRa).

The protective device1can be in bidirectional radio communication with the first radio terminals90a,90bin the reception area in order to be able to receive a radio signal F that was sent by the first radio terminals90a,90bin the protective device1. The radio signal F from a first radio terminal90a,90bis transmitted continuously or at least at regular intervals and is received by the second radio terminal91of the protective device1.

The signal quality of a radio channel between the protective device1and a first radio terminal90a,90bcan thus be evaluated. The protective device1can, for example, receive radio signals F from the first radio terminals90a,90bin the reception area on different radio channels and evaluate the signal level of the radio signal F or another suitable property of the radio signal F. The protective device1can then decide via which radio channel an emergency signal S should be sent, if necessary. However, it can also be provided that the protective device1sends out a signal at regular intervals that is received by the first radio terminals90a,90bin the reception area and is used to assess the signal quality of the radio channels. In this way, the protective device1, for example from a first radio terminal90a,90b, can be informed via a radio signal F about the radio channel via which an emergency signal S should be transmitted.

This way, the person8who wears the protective device1can move through the building or in an electrical system without losing the radio link. The radio link may move along accordingly by assigning the best first radio terminal90a,90bor best radio channel (in the sense of the best or at least sufficient signal quality of the radio channel) for a radio link that may be necessary between the protective device1and the emergency signal input21.

For the invention, however, it is in principle unimportant where the decision which first radio terminal90a,90bis used for the communication is made. The decision could be made in the protective device1, in the second radio terminal91, in the first radio terminals90a,90b, in the emergency signal input21or also in the electrical system10.

In the protective device1, preferably on the item of clothing2or on an external unit that is in data connection with the protective device1, at least one further sensor9can optionally be provided for detecting a further variable (FIG. 1), which detects a further condition of the person8(in addition to a possible body current). The further sensor9can, for example, be an acceleration sensor in order to be able to determine a fall of the person8. A position sensor as a further sensor9can be used to detect if the person8is lying down. The further sensor9can be designed to record an ECG (electrocardiogram) which, in connection with an electrical accident, can provide important information about the condition of the person8having the accident. The respiration of the person victim8having the accident can also be recorded by means of an acceleration sensor or movement sensor as a further sensor9. Of course, several further sensors9can also be provided on the protective device1with any combinations of the above sensors9being conceivable.

Values acquired with the sensor3, or the sensors3, and/or values acquired with at least one further sensor9can also be stored in the protective device1in a memory unit, for example in evaluation unit6. This makes it possible to read stored values at a later point in time or to transmit them to other locations.

In many situations, the protective device1can successfully actuate a preset (switching) action via an emergency signal input21and thus switch the electrical system10or at least parts of it into a currentless and voltage-free state. When the protective device1is activated, however, an electric shock has already occurred in these situations. The affected person8can, however, sometimes work in remote places or alone, so that despite the activation of the protective device1, there is no help for the person8having the accident. The same applies if the protective device1fails for whatever reasons, i.e., the protective device1responds, but the voltage cannot be switched off.

It can likewise be provided that a protective device1does not only generate an emergency signal S but establishes a radio link62(indicated by the dashed line) with a transmitter unit64, such as a mobile radio transmitter63, to a configured remote location60so that help for the person8having the accident is initiated or coordinated, preferably by a further person61at the remote location60, as shown inFIG. 5. “Remote” means in this context that this further person61is at least so far away from the person8having the accident that this further person61can neither visually nor acoustically directly determine the condition of the accident victim. However, the second radio terminal91on the protective device1can of course also be used as the transmitter unit64if the range is sufficient. The further person61can, for example, be in an emergency center, which can be in a completely different location. The protective device1can establish the radio link62directly via the transmitter unit64, for example by means of a mobile radio transmitter63which is integrated in the item of clothing2, for example again as part of intelligent clothing.

Alternatively, the protective device1can also establish the radio link62indirectly, for example, in that the protective device1connects, via the transmitter unit64and a suitable data connection65, for example Bluetooth, to a mobile terminal66, for example a smartphone (e.g., using Bluetooth), of the person8, which then sets up the radio link62to the remote location60, as shown inFIG. 6. A specific message can be sent via the radio link62, for example a text message (SMS), a data transmission (for example, by e-mail) or a call can be made. The further person61in the remote location60can also carry a mobile terminal67with him, which can be connected to the radio link62if necessary, for example via a mobile radio network. It is obvious that the remote location60(e.g., the emergency center) does not have to be stationary, in particular, if the further person61also uses a mobile terminal67to be contacted.

The transmitting unit64, for example in the form of a mobile radio transmitter63, is preferably integrated in the evaluation unit6or also in the item of clothing2itself (for example, in the form of intelligent clothing). The transmitting unit64can be controlled by the evaluation unit6of the protective device1.

The further person61can then coordinate help for the person8having the accident. An emergency center may, for example, be aware of the location of persons8who work on electrical systems10that are live or under voltage. For example, maintenance work is planned on a power grid as an electrical system10(as inFIG. 5), and it is known when and where this will be carried out. The protective device1can be assigned to a specific person8and can also have a unique identifier (for example, a mobile phone number). This way, an emergency call (also as a text message or an e-mail) coming into the emergency center from a protective device1can be assigned to a location and/or a person8so that the further person61can be specifically coordinated help by an emergency helper.

The protective device1can also be equipped with a positioning unit72. For this purpose, for example, the positioning unit72such as a GPS (Global Positioning System) sensor can be arranged on the item of clothing2(as indicated by dashed lines inFIG. 7) or integrated in the item of clothing, for example intelligent clothing with integrated electronics. Other satellite navigation systems such as GALILEO can also be used, of course. However, there are naturally other ways of determining the position of a person8by means of a positioning unit72. A conclusion about the current position could be drawn, for example, from the availability of WLAN (Wireless LAN) networks. A position could also be determined via a mobile radio network, for example, by means of GSM positioning.

The protective device1can, however, also be connected to an external unit71, which can carry out a position determination, as a positioning unit72, as shown, for example, inFIG. 7. Today's mobile telephones or smart phones generally have a positioning system integrated in them so that a mobile terminal66can be used particularly advantageously as an external unit71for this purpose (as seen inFIG. 7). However, the external unit71can be a GPS receiver as well. The protective device1can thus be connected to the external unit71via a suitable data link65, for example Bluetooth, in order to receive the current position of the person8from the external unit71. To establish the link, a transmitting unit64could again be provided in the protective device1, for example.

The current position can be stored in the protective device1, preferably in the evaluation unit6of the protective device1, preferably with further details about an electrical accident such as the date, time, duration of the body current or the level of the current flow, in order to allow for a later evaluation. The current position is understood to refer both to geographic coordinates and a specific location. Since many external units71often also have a positioning function, the location can also be used directly as the current position.

Of course, the current position or the current location can also be transmitted to the remote location60(as inFIG. 5 or 6) in order to assist with the coordination of assistance for the person8having the accident. The current position or the current location could also be transmitted to the remote location60at certain time intervals in order to always know a current position or a current location of the person8.

Independently of the other functions of the protective device, the position or the location of the person8can be recorded and stored in the protective device1, for example in order to generate a documentation of electrical accidents or for statistical records or evaluations of electrical accidents. In addition, further details such as date, time, duration of power contact, etc. can be stored.

It is obvious that when a remote location60is notified by the protective device1in the event of an electrical accident, additional information, for example data from further sensors9on the protective device1, can also be transmitted about the condition of the person8, for example the physical position of the person8(fall, person is lying down), pulse, ECG, respiration. Such additional information can be important for coordinating the help and rescue operations.

The remote location60can, of course, also be automated to the extent that, in the event of an incoming message of an electrical accident of a person8, certain actions are automatically taken, for example the notification of an ambulance service or helper, possibly also with the specific position or location of person8, possibly also with other existing data. In this case, the further person61would not be absolutely necessary.

To this end, the remote location60could also determine the location of one or more helper in the vicinity of the person8having the accident and specifically inform him about the electrical accident. The helper who is locally closest to the person8having the accident is preferably determined. For this purpose, the helper can be equipped with a communication unit, for example a mobile phone or smart phone, which is contacted by the remote location60or by the further person61at the remote location60with a corresponding message. The message could be a text message, email, or the like, or a phone call.

A helper in the vicinity of the person having the accident could be determined in that the locations of all possible helpers are known at the remote location60. The current location could be continuously transmitted to the remote location60, for example, via the communication units of the EMT helpers at predetermined intervals. However, a proximity could also be determined in such a way that it is determined whether a communication unit of the person8having the accident, for example a mobile terminal66, can exchange messages with a communication unit of a helper, for example via Bluetooth, or whether both can receive the same WLAN network. This could also be continuously communicated to the remote location60by the respective communication unit so that the remote location60always has a current status.

Situations are conceivable in which a (switching) operation is carried out on the electrical system10by the emergency signal S, but this does not lead to the desired success, i.e., the absence of voltage on the part contacted. This can happen, for example, if an emergency electric circuit is interrupted but another electric circuit is available that is not connected to the emergency stop. It can therefore also be monitored in the electrical system10whether the switching action leads to the desired success within a predetermined time period, for example 100 ms. It can be determined, for example, whether the protective device1no longer receives an emergency signal S after the switching action. If the absence of voltage cannot be determined in the specified time period, a further (switching) action can be triggered in the electrical system10, for example, in order to switch off at least one further electric circuit. It is often the case, for example, that only certain sockets or power supplies are connected to an emergency electric circuit while other electrical parts are in a different electric circuit. In this way, the emergency electric circuit could first be disconnected as described, and in a second step, if the first step was unsuccessful, a defined additional electric circuit could be disconnected. Of course, different hierarchies of electric circuits can be defined, which are switched off one after the other. An emergency electric circuit could be switched off first, for example, then an adjacent emergency electric circuit or an electric circuit for normal sockets, then an electric circuit for the IT infrastructure in a certain part of a building, then the whole building and finally the power supply for a server room.

It is also conceivable for several people to be in the work area at the same time in order to carry out work on current-carrying parts. In such situations, however, it can happen that an electrical accident involving a person8is not noticed by other persons in the vicinity, not even those in the immediate vicinity. This can also put other people at risk, for example, because they touch the person8who has become part of the electric circuit or because they also touch the live part. Apart from this, an efficient action to rescue the person8having the accident or to protect other people in the vicinity, for example by switching off or short-circuiting the electrical circuit or also by pushing the person8having the accident away, is only possible if at least one further person in the vicinity becomes aware of the electrical accident. In such cases, a protective device1according to the invention can also advantageously be used, as described by way of example with reference toFIG. 8.

It is assumed that a plurality of people8a,8b, each with a protective device1a,1b, are in the vicinity of a live component and that the protective devices1a,1bare in communication. For this purpose, each protective device1a,1bcan be provided with a communication unit80a,80bin order to be able to set up a communication link81, for example via Bluetooth. The communication link81can, however, also be established indirectly, for example, as explained in connection withFIG. 6, via a mobile terminal66of a person8a,8b. The communication units80a,80bof the two protective devices1a,1bdo not have to communicate directly with one another. It would be conceivable, for example, for a communication center82to be set up in the work area with which the individual protective devices1a,1bare connected via their communication units80a,80b, as indicated inFIG. 8. In that case, the communication link81is established via the communication center82. The communication link81can be set up permanently or set up also on an event-related basis. If a protective device1aof a person8atriggers an emergency signal S, because this person8abecomes part of an electric circuit, the communication unit80aof the protective device1ainforms the at least one further person8bin the vicinity via the communication link81and the communication unit80bof the protective device1b. For this purpose, a corresponding signaling unit, for example an acoustic, visual or palpable alarm, can also be provided on a protective device1. If a protective device1is additionally provided with a unique identifier, it is possible to also transmit which protective device1is affected in order to be able to locate the person8ahaving the accident more easily. The help for a person8ahaving the accident can thus be considerably accelerated.

Instead of setting up a communication center82in the work area, the communication described could also take place via a remote location60(at any distance away) as a communication center, for example as described inFIG. 5 or 6.

The protective device1of the person8having the accident, or a communication unit80of the protective device1or an external device71coupled to the protective device, for example a mobile phone that the person8is carrying, can also make further persons in the surrounding area, who may not be trained or have any special equipment, aware of the danger and the help that is needed with a loud acoustic signal, optionally also with spoken warning text. An acoustic warning such as “Warning—electrical accident—this person is under voltage. Do not touch this person. Interrupt the circuit or remove the person from the circuit” or “Warning—electrical accident—this person has suffered an electric shock. Touchable parts under voltage are nearby” would be conceivable, for example.

It is, of course, also possible to check, either continuously or at least at the beginning of the work, whether a radio link exists at all between the protective device1and the emergency signal input21. If not, a corresponding alarm can be issued by the protective device1, for example acoustically, visually or palpably. The same naturally applies if a low state of charge of an energy supply for the protective device1is detected in the protective device1.