• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
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  • 优先权
    • 专利摘要:
    System and method of prevention against electric shock and/or electric arcs. The object of the present invention refers to a system and method of prevention against electrical discharges and/or electric arcs on individuals who are close to an electrical installation (20). Specifically, this system comprises an actuator device (200, 200 '), capable of interrupting the electrical flow of said electrical installation (20) and which is connected wirelessly with a sensor device (100) capable of wirelessly detecting electric fields emitted by the device. Body of the individual and/or by the electrical installation (20), additionally capable of indicating to the individual that he is at risk of suffering an electric shock and/or an electric arc. (Machine-translation by Google Translate, not legally binding)
    公开号:ES2610031A1
    申请号:ES201531367
    申请日:2015-09-24
    公开日:2017-04-25
    发明作者:Juan CHARNECO FERNANDEZ;Ricardo Palacios De La Olla;Manuel DELGADO RESTITUTO
    申请人:Consejo Superior de Investigaciones Cientificas CSIC;
    IPC主号:
    专利说明:

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    SYSTEM AND METHOD OF PREVENTION AGAINST ELECTRIC SHOCK AND / OR
    ELECTRIC ARCHES
    D E S C R I P C I O N
    OBJECT OF THE INVENTION
    The object of the present invention relates to a prevention system and method against electric shocks and / or electric arcs on individuals that are close to an electrical installation.
    The present invention is based on the study of the behavior of the electric fields that are around the system.
    More specifically, the present invention detects a risk of electric shock or electric arc, and interrupts the electrical flow of an installation of both low voltage and high voltage before said risk occurs. Additionally, the present invention can warn the individual of the existence of the risk of electric shock and / or electric arc.
    BACKGROUND OF THE INVENTION
    Currently, various prevention systems against electric shocks and / or electric arcs are known.
    An example of an electrical protection system is described in the Spanish invention patent with publication number ES2029416A6. Specifically, this document describes an electronic equipment for the safety, electrical protection and optimization of an electrical power connection. Said equipment basically comprises electronic measurement, comparison and actuation circuits.
    Through these circuits, the equipment is able to avoid sparks and explosions when a short circuit occurs in an electrical installation, as well as to carry out the self-disconnection of a load connected to the electrical installation due to the
    short circuit, without activating the magneto-thermal switch installed in the electrical installation.
    Additionally, this equipment notifies the individual audibly in case 5 detects a short circuit or an overload in the electrical installation.
    Although this document describes how to detect a short circuit and an electrical overload, it does not prevent the individual from receiving a shock or an electric arc.
    10 Another example of an electric detection device is that described by the Spanish patent ES2259421T3. More specifically, this document describes a device for determining the absence, or presence, of tension in a single-phase, or multi-phase electric line, provided with an external insulation. This device is primarily designed to be used in a high-voltage line, especially 15 of cable connections with voltages of the order of 1000V. Additionally, this device is provided with a housing containing a meter and an electronic analyzer, as well as a detector head consisting of at least three measuring electrodes that are attached to the meter and electronic analyzer. Thus, by means of the electronic meter and analyzer, the received signals 20 from the measuring electrodes are analyzed when they are pressed against the external insulation of the electric line.
    This device can only be used when it is positioned on high voltage lines, and for a very specific use, which is the detection of tension in an electric line. Therefore, this device only notifies the presence or absence of electrical voltage in an electrical line with external insulation, but does not prevent or prevent electric shock or arc on the individual that is nearby, or that is checking the electrical line.
    On the other hand, differential circuit breakers can also be considered as background of the invention, since they interrupt the electric flow when a person suffers an electric shock. More specifically, these differential circuit breakers are installed in each electrical installation, specifically in their corresponding electrical switchgear.
    Currently the efficiency of differential circuit breakers is very questionable, since to interrupt the electric flow they need the individual to come into contact with earth and a mass subjected to electrical voltage. That is, it requires that an electric intensity circulate to the earth through the body of the individual.
    Additionally, these differential circuit breakers only protect the individual from contacts between a phase conductor and a ground conductor of the electrical installation, being totally inoperative when the individual enters into direct contact with a phase conductor and a neutral conductor, or with a phase conductor and a phase conductor.
    It should be noted that said phase-neutral and phase-phase electrical contact is very frequent and dangerous. This is because if there is no earth current, the differential circuit breaker considers the individual's body as a simple electric receiver with an approximate resistance of between 1,500 and 2,000 ohms, and therefore does not automatically cut off the electrical flow of the electrical installation.
    An example of this problem is that in a case of electric shock by direct contact with a phase conductor and a neutral conductor, an approximate intensity of 0.11 Amps (230 V / 2000 Ohms = 0) would circulate through the individual's body. , 11 Amps). Said level of amps can cause the death of a person without being able to be saved by the differential circuit breaker, even if it has a sensitivity of 0.03 Amps.
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    DESCRIPTION OF THE INVENTION
    The present invention relates to a prevention system and method against electric shocks and / or electric arcs on individuals that are close to an electrical installation.
    The protection against electric shock offered by this invention is the result of tests and measurements in the bodies of more than 100 individuals, of different morphology, sex and age, when they were in physical contact with an element
    electrically active, using these results to develop a system capable of detecting the risk of electric shock before it happens.
    The results show that the body of any individual being physically attached to an electrically active element, is electrically charged and emits an electric field capable of being detected wirelessly by the system of the invention, even if no electric current flows through it.
    More specifically, when the individual's body comes into physical contact with an electrically active element, without external insulation, and which is subject to an electrical potential greater than 25V, the body emits an electric field that can be detected by the present invention. .
    Additionally, when the individual's body comes into physical contact with an electrically active element 15, with external insulation, and which is subject to an electrical potential greater than 100V, the body emits an electric field capable of being detected by the present invention.
    Regarding the protection against electric arcs, the system of the invention uses 20 as a base, the result of the comparative analysis of the level of existing electric fields against the individual and the risk of suffering an electric arc that runs.
    Taking as reference the fimite levels of electric field specified in resolution 295/2003 of the Ministry of Labor, Employment and Social Security on "technical specifications on ergonomics and manual lifting of loads, and 25 on radiation."
    More specifically, the system notifies the individual when he is at a distance between his body and the elements subjected to high voltage that implies that there is a level of electric fields in front of the same or greater than 15 kV / m.
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    Optionally, the system allows the user to adjust said warning between 5 kV / m and 15 kV / m.
    Additionally, the system warns with a specific warning when the individual is at a level of electric fields compared to or equal to 20 kV / m, which indicates that
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    It is at a distance smaller than the allowed one and that additionally if it reduces it in a proportion that implies imminent risk of suffering an electric arc, the electric flow interruption system will be activated.
    It should be noted that the system of the invention presents the possibility of programming new reference levels, equivalent to new electric field limit levels modified in new regulations.
    For complete protection, the present system can achieve the interruption of the electrical supply in low voltage and high voltage each time it dictates that the individual is at imminent risk of suffering an electric shock and / or an electric arc. This system comprises at least one actuator device capable of interrupting the electrical flow of the electrical installation, and at least one sensor device that is capable of wirelessly detecting nearby electric fields and that is wirelessly connected to the actuator device.
    More specifically, an actuator device may be connected to a plurality of sensor devices. These sensor devices can be located in the area of the electrical installation and / or carried by individuals.
    Additionally, in areas with a plurality of different electrical installations a plurality of sensor devices linked to at least one actuator device can be used.
    More specifically, the sensor device of nearby electric fields comprises:
    - at least one electric field detector antenna,
    - at least one amplification circuit linked to the detector antenna,
    - at least one pass-band filtering circuit linked to the amplification circuit,
    - a comparison circuit linked to the pass-band filter circuit,
    - a control and command circuit linked to the comparison circuit and the amplification circuit,
    - a communication circuit linked to the comparison circuit and capable of sending a control signal to the actuator device,
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    - at least one power supply that electrically feeds these circuits, and
    - a wrapping and electrical insulating frame that includes at least these circuits.
    Additionally this sensor device comprises:
    - a warning circuit, linked to the comparator circuit and the control and command circuit, and
    - an electromagnetic wave generation circuit with a frequency between 50 Hz and 60 Hz, with an electromagnetic wave emitting antenna, and linked to the control and command circuit.
    More specifically, the detector antenna is integrated into at least one of the outer or inner faces of the surrounding frame. Additionally, this wrapping frame has on one of its outer faces fastening means that allow it to be linked to the body, or clothing of the individual, and / or even to a solid structure such as a wall or a ceiling of a room, a table or other furniture
    Optionally, the detector antenna incorporates means for the extension of the detection zone of the antenna by means of an electrically conductive element of any physical form.
    Said amplification circuit comprises a preamplifier, linked to the sensing antenna, and an amplifier with controllable gain, linked to the preamplifier, the pass-band filtering circuit and the control and command circuit.
    Additionally, the pass-band filtering circuit comprises a pass-band filter that allows the passage of electrical signals between 10 Hz and 100 Hz.
    Specifically, the comparison circuit comprises a first comparator circuit linked to the control and command circuit and the communication circuit, and a second comparator circuit linked to the control and command circuit and the warning circuit.
    The control and control circuit comprises at least one control stage linked to a control interface that allows modifying at least one control parameter previously programmed in the control stage.
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    Additionally, the communication circuit comprises a radioelectric transmitter which, when activated, transmits wireless radioelectric signals intended to communicate with the actuator device, and a transmission interface capable of adjusting the radioelectric transmitter.
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    The warning circuit comprises an output stage linked to the control and command circuit and with at least one of the following indicator elements: an acoustic indicator, an optical indicator or a vibrating indicator. In this way the warning circuit warns the individual when there is a risk of electric shock and / or electric arc.
    15 It should be noted that the detector device can be used autonomously for all warning functions, even if the actuator device is not operational Finally, the generation circuit through its wave emitting antenna generates a plurality of electric waves that allow checking the correct detection of electric fields of the detector antenna.
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    Alternatively, the communication circuit of the sensor device comprises a generator and elevator circuit of amplitude of interruption radioelectric pulses, which is activated by the first comparator circuit and which is linked to an emitting electrode. This configuration allows the generation of a radioelectric pulse
    25 interrupt that is capacitively transmitted from the emitting electrode to the device through the individual's body and the electrical network. Thus, when the individual comes into physical contact with an electrically active element, it transmits said radioelectric interruption pulse from its body to the actuator device using the electrically active element with which the individual comes into contact.
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    It should be noted that the impulse is carried out during a very short time of the order of milliseconds. That is, during the time that the individual comes into contact with the electrically active element and at the instant that the actuator device disconnects the electrical installation.
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    In this way, the radioelectric pulse would be the same in all sensor devices and to which all actuator devices would respond by interrupting the electric flow.
    Optionally, the sensor device in addition to the elements described above comprises:
    - an additional detector antenna,
    - an additional preamplifier linked to said additional antenna,
    - an additional amplifier with adjustable gain linked to said additional preamp, and
    - an additional bandpass filter linked to said additional amplifier.
    More specifically, one of the sensing antennas is integrated in an outer face of the enclosure, while the other sensing antenna is integrated in one of the inner faces of the enclosure. Additionally, each detector antenna is connected to its respective preamplifier, which is linked to its adjustable gain amplifier, and this in turn is linked to its pass-through filter. Both bandpass filters are connected to the comparison circuit.
    Thanks to this configuration, when the sensor device is linked with the individual or with their clothing, the sensing antenna of the outer face is faced with the electrically active elements and therefore detects the electric fields emitted by these elements located in front of the individual. While the indoor sensing antenna detects the electric fields emitted by the individual's body when it undergoes physical contact with an electrically active element.
    Thus, when the sensor device detects an increase in the electric field around it, it notifies the individual through the warning circuit, and / or transmits wireless radio signals by means of a communication circuit designed to communicate with the actuator device to interrupt the flow. electrical of the electrical installation.
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    On the other hand the actuator device comprises:
    - a radioelectric signal receiver circuit, capable of receiving the wireless radioelectric signals sent by the communication circuit,
    - a reception interface capable of adjusting the receiver,
    - a coupling unit of the actuator device to the electrical installation,
    - a disconnection circuit that can be linked to the electrical installation,
    - a safety circuit to check the correct operation of the actuator device,
    - an enclosure and electrical insulating framework that includes at least both circuits, and
    - a power supply to power all its circuits.
    In an embodiment of the actuator device, this is insertable in the electrical installation switchgear, therefore being considered the actuator device in permanent configuration.
    In this way, the coupling unit of the actuator device is located on one of the outer faces of the enclosure whose configuration is likely to be linked to a DIN rail of an electrical panel of the switchgear of the electrical installation or of an independent electrical panel . Additionally, this body comprises at least one electrical input and output capable of being linked to the wiring of said low or high voltage electrical switchgear so that it can cut off the electrical flow.
    The disconnection circuit of the actuator device in permanent configuration comprises a contactor block consisting essentially of a switch contactor with contacts capable of being linked to the electrical installation to interrupt the electric flow when it separates its contacts from each other, and a power circuit linked to the block contactor that separates or joins your contacts.
    Alternatively, the disconnection circuit for a high voltage installation comprises at least one input and one electrical output that can be connected to the
    switchgear of disconnection of the own high voltage electrical installation.
    While the safety circuit of the actuator device in permanent configuration comprises a power interface linked to the power circuit that allows to check the operation of the contactor block, rearm the power circuit, rearm and select the type of reassembly.
    In another embodiment of the actuator device, this is insertable in the electrical installation by means of its connection to an AC outlet existing in the electrical installation, 10 thus being the actuator device considered in temporary configuration. In this way, the coupling unit is located on one of the outer faces of the enclosure and comprises a male plug capable of being able to be inserted into an AC outlet of the electrical installation.
    More specifically, the disconnection circuit of the actuator device in temporary configuration comprises an electronic circuit capable of causing a grounding of the electrical flow of the electrical installation and causing a controlled overcurrent of the same flow in the electrical installation, so that less a differential automatic and / or mandatory magneto-thermal switch of said installation is triggered and the electric flow is interrupted.
    Additionally, the actuator device, in both permanent and temporary configuration, comprises a receiver of interruption radioelectric impulses linked to the disconnection circuit and therefore capable of being connected to the electrical installation. 25 This receiver is capable of recognizing the radioelectric impulse sent from the sensor device and activating the disconnection circuit of the actuator device so that it interrupts the flow of the electrical installation.
    The method of prevention against electric shocks and / or electric arcs on individuals 30 that are close to an electrical installation used by the system described above comprises the following steps:
    - position at least one actuator device in the electrical installation,
    - position at least one sensor device,
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    - select a mode of use of the sensor device via a control interface included in the sensor device,
    - detect a nearby electric field by means of a detector antenna comprised in the sensor device,
    - amplify the signal of the nearby electric field by means of an amplification circuit,
    - compare said signal of the electric field, by means of a comparison circuit, with warning and / or communication threshold values comprised in a control and command circuit,
    - send a radioelectric signal, through a communication circuit, to the actuator device to prevent the electrical flow of the electrical installation when any of the communication threshold values is exceeded, and
    - send an acoustic, visual, or vibratory signal by means of a warning circuit, to the individual who is close to the installation when any of the warning threshold values is exceeded.
    Thus, depending on the positioning of the actuator device, the positioning of the sensor device and the type of electrical installation, that is, if the installation is of low voltage or high voltage, the individual selects a mode of use.
    Each mode of use has a warning and communication threshold value included in the control and command circuit. In this way, if the communication threshold value is reached, the sensor device sends, by means of the communication circuit, a radioelectric signal to the actuator device so that it interrupts the electrical flow of the electrical installation. While in case of reaching the warning threshold value, the sensor device warns by means of a warning circuit, which comprises an acoustic, visual or vibratory indicator to the individual that is approaching electrically active elements, or to the individual that is trying to identify which elements in front of it are electrically active.
    Thus, the present invention prevents electric shock and electric arc based on the detection of electric fields, specifically allows to detect the risk of electric shock, when the individual comes into physical contact with an electrically active element, with or without insulation and independently of the type of contact
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    electric.
    Additionally, the present invention also allows detecting the risk of electric arc when the individual approaches high voltage elements, regardless of the magnitude of said high voltage.
    In other words, the present invention allows to detect the electric field, emitted by the individual's body when it comes into contact with an electrically active element, as well as the electric field emitted by the electrically active element itself.
    Therefore this system allows to prevent electric shock even before it happens, as well as the electric arc, also before it happens.
    It should be noted that the systems known so far only detect discharges when a connection is made, through the individual's body, between a single-phase conductor and a ground conductor of the electrical installation, without taking into account that today they are more frequent the connections between a conductor of a phase and a conductor of neutral, or between a conductor of a phase and a conductor of another phase, due to the footwear with insulating sole used today. In this way, the present invention protects both contacts between phase-phase, phase-neutral and phase-earth and can interrupt the electrical flow for any type of connection by improving the reliability of the system with respect to the state of the art.
    This system allows interrupting the electric flow of any electrical installation, when there is a contact of the individual with an electrically active conductor without isolation and / or there is an imminent risk of electric arc, before an intensity circulates through the individual's body. As well as to warn the individual who has come into contact with an electrically active conductor with isolation, or to warn him that he is very close to an area of the electrical installation in which there is a danger of electric arc.
    Another advantage of the present invention is that it allows a plurality of sensor devices to be connected to a single actuator device that can be used simultaneously by one or more individuals.
    Finally, this system also allows detecting, at a distance of at least 4 meters, at least one individual who comes into physical contact with an electrically active element without insulation. In this way, there can be several individuals in the same area, and they would all be protected by a single system, that is, a sensor device and an actuator device, without the need to have any additional elements.
    DESCRIPTION OF THE DRAWINGS
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    To complement the description that is being made and in order to help a better understanding of the characteristics of the invention, in accordance with a preferred example of practical realization thereof, a set of drawings is accompanied as an integral part of said description. where, with an illustrative and non-limiting nature, the following has been represented:
    Figure 1.- Shows a schematic view of the electric field sensor device.
    Figure 2.- Shows a schematic view of an embodiment of the actuator device in permanent configuration.
    Figure 3.- Shows a schematic view of an embodiment of the actuator device in temporary configuration.
    25 Figure 4a.- Shows a schematic view of the positioning of the sensor device on the wall of a room.
    Figure 4b.- Shows a schematic view of the positioning of the sensor device on the ceiling of a room.
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    Figure 5a.- Shows a schematic view of the positioning of the sensor device in a belt.
    Figure 5b.- Shows a schematic view of the positioning of the sensor device in
    The outside of a pocket.
    Figure 5c.- Shows a schematic view of the positioning of the sensor device inside a pocket.
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    Figure 6.- Shows a schematic view of the positioning of the sensor device in an arm of the individual.
    Figure 7.- Shows a realization of the actuator device in permanent configuration.
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    Figure 8.- Shows an embodiment of the actuator device in permanent configuration installed in an electrical panel.
    Figure 9.- Shows an embodiment of the actuator device in temporary configuration.
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    PREFERRED EMBODIMENT OF THE INVENTION
    In a preferred embodiment of the invention, the prevention system against electric discharges 20 and / or electric arcs on individuals that are close to an electrical installation (20), is formed by a sensor device (100) and an actuator device (200 , 200 ') that controls the electrical flow of the electrical installation (20). Both devices comprise a wrapping and electrical insulating frame that contains the rest of the elements that make them up.
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    More specifically, as shown schematically in Figure 1, the sensor device (100) comprises in an enclosure frame:
    - a detector antenna (1) of nearby electric fields that is integrated into one of the outer faces of the enclosure that forms the
    sensor device (100).
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    - a control and control circuit (103) comprising a control stage (7) linked to a control interface (8) with which the individual can select and program the sensor device (100).
    - an amplification circuit (101) linked to the detector antenna (1) and with the control and control circuit (103), composed of a preamplifier (2) that amplifies the electrical signals that come from the detector antenna (1), and composed of an amplifier with controllable gain (3) that amplifies the electrical signals from the preamplifier (2) with a gain determined by the control stage (7).
    - a pass-band filtering circuit (4) composed of a pass-band filter located at the output of the amplifier with controllable gain (3) of the amplification circuit (101) that only allows the passage of electrical signals of frequency between 10 Hz and 100 Hz.
    - a comparison circuit (102) linked to the output of the band-pass filter, consisting of a first comparator circuit (5) linked to a communication circuit (104), a second comparator circuit (6) linked to a warning circuit (105), both comparators (5,6) being linked to the control and command circuit (103).
    - a communication circuit (104) activated by the first comparator circuit (5) when the communication threshold level exceeded in the control stage (7) is exceeded, which comprises a radioelectric transmitter (13) for transmitting specific wireless radioelectric signals and a transmission interface (14) that allows the individual to make the radio transmitter settings (13).
    - a warning circuit (105) linked to the comparison circuit (102) and the control and command circuit (103), to warn of the risk of electric shock and / or electric arc to the individual. Specifically, the warning circuit (105) comprises an output stage (9) that activates an acoustic indicator (10), an optical indicator (11) and / or a vibrating indicator (12), when the second circuit
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    comparator (6) exceeds the warning threshold level included in said control stage (7).
    - a circuit of generation (17) of electromagnetic waves with a frequency between 50 Hz and 60 Hz, linked to the control and command circuit (103), comprising a built-in emitting antenna, which operates with sequential emission levels stored in the control stage (7), to check the correct detection of electric fields of the detector antenna (1) and consequently to also check the correct operation of the entire system.
    More specifically, the detector antenna (1) is capable of detecting the electric field emitted by the body of the individual to which the sensor device (100) is adapted; detect at a distance of at least 4 meters the electric field emitted by the body of at least the individual that is included in said range; detect the existing electric field in the elements subjected to high voltage that remain in front of at least the individual; and detect the existing electric field in the low voltage elements that are confronted with the detector antenna itself (1).
    The control stage (7) controls the gain value of the amplifier with controllable gain (3), the communication threshold that activates the output of the first comparator circuit (5), the warning threshold that activates the output of the second comparator circuit ( 6), the status of the acoustic indicator (10), the optical indicator (11) or the vibrating indicator (12) and the generation circuit (17).
    Additionally, the control stage (7) includes the communication and warning threshold levels that activates the output of the first and second comparator circuit (5.6) for low and high voltage.
    More specifically, the warning and / or communication threshold values at least depend on the type of electrical installation (20), that is, if the installation is of low voltage or high voltage.
    In the case of a low voltage installation, the first comparator (5) activates its
    output, and therefore activates the radio transmitter (13), when it detects a field
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    electrical equivalent to the electric field emitted by the body of an individual who comes into physical contact with an element without insulation and subjected to an electrical voltage greater than 50 V.
    5 While the second comparator (6) activates its output, and therefore through the output stage (9) some of the indicators (10, 11, 12), when it detects an electric field equivalent to the electric field emitted by the body of an individual when it is in physical contact with an element without insulation and subjected to an electrical voltage between 25 V and 50V.
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    Additionally, the second comparator (6) also activates its output when it detects that the electric field emitted by the body of an individual that is in physical contact with an insulated element subjected to an electrical voltage of at least 100 V.
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    It should be noted that in this preferred embodiment, by means of the sensor device (100) the electric field emitted by a variety of individuals has been measured when they are subject to a range of different voltages but without circulating intensity, in order to establish the warning threshold values and communication for electrical installations of 20 low voltage.
    In the case of a high voltage installation, the first comparator (5) activates its output, and therefore activates the radioelectric transmitter (13), when it detects an electric field, emitted by an electrically active element, greater than 20 kV / m in a proportion such that it implies imminent risk of suffering an electric arc
    While the second comparator (6) activates its output, and therefore through the output stage (9) some of the indicators (10, 11, 12), when it detects an electric field, of at least 5kV / m, emitted by an electrically active element.
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    Optionally, the second comparator (6) also activates its output, and therefore through the output stage (9) some of the indicators (10, 11, 12), when it detects an electric field emitted by an electrically active element that exceeds that selected by the individual in the interface (8). Specifically this electric field is included
    within preferential safety limits between 5 kV / m and 15 kV / m.
    Additionally, the second comparator (6) also activates its output when it detects an electric field emitted by an electrically active element of a value close to 20 5 kV / m. In this case and because it is a high risk of electric arc, the output stage (9) activates in order of the control stage (7) all the indicators (10, 11, 12), remaining activated until the user moves away of the electrically active conductor.
    10 Additionally, the individual through the command interface (8) can select and program:
    - the mode of use in low voltage or high voltage, that is the type of electrical installation (20) in which the system is used,
    15 - the maximum gain level of the amplifier with controllable gain (3) for
    the utilization of the sensor device (100) in a normal sensitivity mode or a high sensitivity mode,
    - a variable threshold level from which the warning circuit (105) will be activated within preset margins,
    20 - status of the acoustic indicator (10), the optical indicator (11) or the indicator
    vibratory (12) and,
    - the activation of the generation circuit (17) of electromagnetic waves with a built-in emitting antenna to check the correct functioning of the system.
    25 More specifically, the sensor device (100) has the following operating modes: low voltage mode with normal sensitivity, low voltage mode with high sensitivity and high voltage mode. Consequently, one of the low voltage modes is selected when the individual is close, or is ready to work, in a low voltage electrical installation, and the high voltage mode is
    30 selects when the individual is close, or willing to work, in a high-voltage electrical installation.
    Low voltage mode with normal sensitivity is used when the individual has
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    Positioning the sensor device (100) linked to your wardrobe by means of a clamp-like clamping means (15) inserted in an outer face of the enclosure, as shown in Figures 5a and 5b, specifically a shirt pocket (28), or to a belt (16). Additionally, as can be seen in Figure 5c, the sensor device (100) may be inside a pocket of the pants (29).
    Alternatively, the detector (100) can also be linked to a limb of the individual's body, as shown in Figure 6, by an elastic band (32).
    In this way and selecting the low voltage mode with normal sensitivity, the sensor device (100) detects when the individual is in physical contact with an electrically active element with or without insulation.
    Additionally, in low voltage mode with normal sensitivity the individual can face the sensor device (100) to any elements connected to a low voltage network, to recognize if this particular element is electrically active.
    The low voltage mode with high sensitivity is used when the sensor device (100) is positioned by other means of fastening holes capable of receiving screws to be coupled to a wall or ceiling of a room, as shown in Figures 4a and 4b. Thus, when the individual is within the detection range of the sensor device (100) that can exceed a radius of 4m, the sensor device (100) detects, and recognizes when the individual is in physical contact with an electrically active element With or without isolation.
    More specifically, in the low voltage mode with both high sensitivity and low sensitivity, the sensor device (100) can detect that an individual suffers an electrical contact by comparing the electric field emitted by the body of the individual detected by said sensing antenna (1 ) with communication threshold values programmed in the control stage (7). Additionally, it can detect that an individual is at risk of electric contact when the warning threshold values are exceeded.
    On the other hand, in the high voltage mode, the sensor device (100) can be used
    to warn the individual when he begins to reduce the safety distance Kmite between his body and the elements under high tension. This limit distance is calculated by the sensor device (100) based on the comparison of the existing emitted electric field against the individual's body at that precise moment, detected 5 by the detector antenna (1) with warning threshold values programmed in the control stage (7). These specific threshold values can be modified, within pre-established margins, by the individual through the command interface (8).
    Additionally, in the high voltage mode it is also possible to interrupt the electric flow 10 of a high voltage installation when the individual reduces the safety limit distance with the elements subjected to high voltage by a percentage that may present an imminent risk of producing a Electric arc. For this, the sensor device (100) based on the comparison of the emitted electric field that exists in front of the individual's body at a precise moment and detected by the detector antenna (1) 15 with communication threshold values that are programmed in the stage of control (7).
    In this high voltage mode, the sensor device (100) is carried by the individual in the front part of his wardrobe, as shown in figures 5b in a pocket of the shirt (28), or in the hand of the individual who faces him at a great distance with the elements with the possibility of being subjected to high tension. Therefore, the sensor device (100) can detect concrete elements that are electrically active and can prevent possible electric arcs and / or electric shocks.
    25 In a non-limiting way, when the detector antenna (1) detects the electric field, the electrical signals it detects pass to the preamp (2), and from this to the amplifier with controllable gain (3) which amplifies with a gain determined by the control stage (7), depending on the selection of high sensitivity or normal sensitivity mode of use made by the individual in the command interface (8).
    30
    The electrical signals from the amplifier with controllable gain (3) pass to the pass-band filter, which only allows the passage of electrical signals between 10 Hz and 100 Hz. The electrical signals present at the output of the pass-band filter pass to the first comparator circuit (5) which activates the radioelectric transmitter (13) in case
    of exceeding the transmission threshold programmed in the control stage (7).
    The electrical signals present at the output of the pass-band filter also pass to the second comparator circuit (6), which activates the warning circuit (105) in case of exceeding the warning threshold programmed in the control stage (7) .
    Therefore, in the event that the individual suffers an electrical contact, the level of the electric fields detected by the detector antenna (1), will cause the first comparator circuit (5) to activate its output and is in turn to the radioelectric transmitter (13) 10 that will emit specific wireless radioelectric signals that will reach the actuator device (200, 200 '), which will interrupt the electrical flow immediately.
    On the other hand, in the event that the individual is at imminent risk of suffering an electric arc, usually in high voltage installations, the level of electric fields 15 detected by the detector antenna (1) in front of the individual, before said arc If it occurs, it will cause the first comparator circuit (5) to activate the radioelectric transmitter (13), which will emit specific wireless radio signals that will instantly reach the actuator device (200), so that it acts on the high-voltage automatic interruption switchgear. and the electric flow is interrupted.
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    As for the actuator device (200, 200 ’), this is constituted by an electrical and electrical insulating shell that has two configurations, a permanent configuration and a temporary configuration. In other words, a configuration that is capable of being installed in the electrical installation (20) permanently or temporarily.
    25
    More specifically, the actuator device (200) in permanent configuration, as shown schematically in Figure 7, has on one of its outer faces of the enclosure a configuration capable of being linked to a DIN rail of an electrical panel which is part of the switchgear of the electrical installation 30 (20); and it comprises at least one electrical input and output that can be linked to the wiring of said electrical panel. As can be seen in Figure 8, this electrical panel is a conventional electrical panel that all low voltage electrical installations must have installed and that contain a plurality of circuit breakers to interrupt the flow of electricity in a
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    plurality of electrical installations.
    More specifically, the actuator device (200) as shown in Figure 2, comprises:
    - a radioelectric receiver circuit (23) that receives the wireless radioelectric signals emitted by the radioelectric transmitter (13) by means of the receiver antenna (24) of wireless radioelectric signals.
    - a reception interface (25) linked to the radioelectric receiver (23) that allows all types of programming, selection and adjustments to be made in said wireless signal receiver.
    - a contactor block (19) consisting essentially of a switch contactor, controlled from the power circuit (26) that interrupts the electrical flow when its contacts open.
    - a power circuit (26) that acts on the contactor block (19) so that it interrupts the electrical flow of the electrical installation (20).
    - a power interface (27) linked to the power circuit (26) that allows testing, rearming and selecting the type of reset.
    When the radioelectric receiver circuit (23) receives by means of the receiver antenna (24) the corresponding specific wireless radioelectric signals, coming from the radioelectric transmitter (13), it immediately activates the power circuit (26), which acts on the contactor block (19), getting it to instantly interrupt the electrical flow to the electrical installation (20).
    As for the actuator device (200 ') in temporary configuration as shown in Figure 7, it has on one of the external faces of the enclosure a male plug (22) that can be inserted into a socket of alternating current (21) of the electrical installation (20).
    More specifically, as shown in Figure 3, the actuator device (200 ’) in temporary configuration is composed of:
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    - a radioelectric receiver circuit (23) of wireless radioelectric signals that receives the wireless radioelectric signals emitted by the radioelectric transmitter (13) by means of the receiver antenna (24) of wireless radioelectric signals.
    - a reception interface (25) linked to the radioelectric receiver (23) that allows all types of programming, selection and adjustments to be made in said wireless signal receiver.
    - a controlled overcurrent and bypass circuit (30) that is capable of being able to simultaneously create a momentary shunt to ground and a controlled overcurrent in the electrical installation (20) to get the differential and / or circuit breaker circuit breakers of the general panel to trip (18) of the switchgear and therefore the electric flow is interrupted.
    - a branch interface (31) of the branch circuit and controlled overcurrent (30) that allows to adjust and check its operation.
    - a male plug (22) adapted to the enclosure box of the actuator device (200 ’), which is designed to be inserted into any AC outlet (21) of the electrical installation (20).
    In a non-limiting way when the radioelectric receiver circuit (23) receives through the receiver antenna (24) the signals coming from the radioelectric transmitter (13), it activates immediately to the bypass and controlled overcurrent circuit (30), to achieve that the circuit breakers and circuit breakers existing in the general panel (18) of the switchgear interrupt the electrical flow. The connection of the actuator device (200, 200 ’) is carried out by means of the male plug (22) connected to an AC outlet (21) belonging to said electrical installation (20).
    权利要求:
    Claims (1)
    [1]
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    R E I V I N D I C A C I O N E S
    1 Prevention system against electric shock and / or electric arcs on individuals that are close to an electrical installation (20) comprising at least one actuator device (200, 200 ') capable of interrupting the electrical flow of the electrical installation (20 ), characterized in that it additionally comprises at least one sensor device (100) that wirelessly detects electric fields, emitted by the individual's body and / or by electrically active elements of the electrical installation (20), which is wirelessly connected to the device actuator (200, 200 '), wherein the sensor device (100) comprises:
    - at least one detector antenna (1) of electric fields,
    - at least one amplification circuit (101), linked to the detector antenna (1),
    - at least one pass-band filter circuit (4), linked to the amplification circuit (101),
    - a comparison circuit (102), linked to the filtering circuit,
    - a control and command circuit (103), linked to the comparison circuit (102) and the amplification circuit (101),
    - a communication circuit (104), linked to the comparison circuit (102), capable of sending a control signal to the actuator device (200, 200 ’),
    - at least one power supply to electrically power these circuits, and
    - a wrapping and electrical insulating frame that includes at least these circuits.
    2 System according to revindication 1, characterized in that the sensor device (100) additionally comprises:
    - a warning circuit (105), linked to the comparison circuit (102) and the control and command circuit (103), and
    - a circuit of generation (17) of electromagnetic waves with a frequency between 50 Hz and 60 Hz comprising an electromagnetic wave emitting antenna.
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    3 System according to claim 1 characterized in that at least the detector antenna (1) is integrated in one of the outer or inner faces of the surrounding shell of the sensor device (100).
    4 System according to claim 1, characterized in that the system comprises two detection antennas (1).
    5 System according to claim 4, characterized in that one of the detector antennas (1) is integrated in one of the outer faces of the surrounding shell of the sensor device (100), and the other detector antenna (1) is integrated in one of the faces interiors of the envelope frame of the sensor device (100).
    6 System according to claim 1, characterized in that the wrapping frame on at least one of its outer faces comprises fastening means.
    System according to claim 6, characterized in that the fastening means comprise an elastic band (32) that can be linked to the body of the individual.
    8 System according to claim 6, characterized in that the fastening means comprise a clamp (15) linked to the individual's clothing.
    System according to claim 6, characterized in that the fastening means comprise holes capable of receiving screws to engage a solid structure such as a wall, or ceiling of a room, or a piece of furniture.
    System according to claim 1, characterized in that the pass-band filter circuit (4) comprises at least one pass-band filter located between the amplification circuit (101) and the comparison circuit (102), which allows the passage of electrical signals between 10 Hz and 100 Hz.
    System according to claim 1, characterized in that the amplification circuit (101) comprises:
    - a preamp (2), linked to the detector antenna (1), and
    - an amplifier with controllable gain (3), linked to the preamp (2), to the
    pass-band filter and control and command circuit (103).
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    12 System according to claim 1, characterized in that the circuit of
    communication (104) includes:
    - a radioelectric transmitter (13) which, when activated, transmits wireless radioelectric signals to the actuator device (200, 200 ’) to interrupt the electrical flow of the electrical installation (20), and
    - a transmission interface (14) that allows the individual to adjust the radioelectric transmitter (13).
    13 System according to claim 1, characterized in that the transmitter
    radioelectric (13) sends a control signal to the actuator device (200, 200 ’)
    when the value detected by the detector antenna (1) exceeds the transmission threshold value programmed in the control and command circuit (103).
    System according to claim 1, characterized in that the warning circuit (105) is activated, when the value detected by the detector antenna (1) exceeds the specific warning threshold value programmed in the control and command circuit (103).
    15 System according to claim 1, characterized in that the circuit of
    comparison (102) comprises:
    - a first comparator circuit (5) linked to the pass-band filtering circuit (4), the control and command circuit (103) and the radioelectric transmitter (13), where the first comparator circuit (5) activates the communication circuit (104) so that the actuator device (200, 200 ') interrupts the electrical flow of the electrical installation (20) when the electric field emitted by the individual's body is detected wirelessly by the antenna (1) and exceeds minus a transmission threshold value, programmed in the control and command circuit (103), equivalent to the level of the electric field emitted by the individual's body when it comes into physical contact with an uninsulated element subjected to an electrical voltage greater than 50 V.
    16 System according to claim 1, characterized in that the comparison circuit (102) comprises:
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    - a first comparator circuit (5) linked to the pass-band filtering circuit (4), the control and command circuit (103) and the radioelectric transmitter (13), where the first comparator circuit (5) activates the communication circuit (104) so that the actuator device (200, 200 ') acts on the corresponding high voltage switchgear so that it interrupts the electrical flow of the electrical installation (20) when the electric field detected wirelessly by the antenna (1 ) in the elements subject to high voltage in front of the individual, it exceeds at least one transmission threshold value, programmed in the control and command circuit (103), equivalent to the level of the electric field that exists in front of the individual when he is at imminent risk of suffer an electric arc
    System according to claims 2 and 15, characterized in that the comparison circuit (102) additionally comprises:
    a second comparator circuit (6) linked to the pass-through filter circuit (4), the control and command circuit (103) and the warning circuit (105), wherein the second comparator circuit (6) activates the circuit warning (105) to notify the individual of the existence of a risk of electric shock when the electric field emitted by the individual's body wirelessly detected by the antenna (1) exceeds at least one warning threshold, programmed in the circuit control and command (103), equivalent to the electric field emitted by the body of an individual when it is in physical contact with an element without insulation and subjected to an electrical voltage between 25 V and 50V or when it is in physical contact with an insulated element subjected to an electrical voltage of at least 100 V.
    System according to claims 2 and 16, characterized in that the comparison circuit (102) additionally comprises:
    - a second comparator circuit (6) linked to the pass-through filter circuit (4), the control and command circuit (103) and the warning circuit (105), wherein the second comparator circuit (6) activates the warning circuit (105) to warn the individual that he is approaching an electrically active element in high voltage and there is a risk of an electric arc occurring when the electric field detected wirelessly by the antenna (1) in the elements
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    under high voltage located in front of the individual exceeds at least one warning threshold programmed in the control and command circuit (103).
    19 System according to claim 15, characterized in that the control and control circuit (103) comprises a control stage (7) linked to a control interface (8) capable of allowing the individual to modify, within a safety range, the warning threshold value.
    System according to claim 1, characterized in that the warning circuit (105) comprises an output stage (9) linked with an acoustic indicator (10), an optical indicator (11) or a vibrating indicator (12).
    21 System according to claim 1, characterized in that the communication circuit (104) additionally comprises a generator and elevator circuit of radioelectric interruption amplitude pulses, which is activated by the comparator circuit (102) and which is linked to a emitting electrode capable of transmitting said interrupting radioelectric pulse to the actuator device (200, 200 ') through the individual's body and at least one conductor of the electrical installation (20).
    22 System according to claim 1, characterized in that the detector antenna (1) additionally incorporates means for the extension of the detection zone of the antenna by means of an electric conductive element.
    23 System according to claim 1, characterized in that the sensor device (100) comprises a warning circuit (105) that allows its use for all the warning functions, even if the actuator device (200, 200 ') is not operational.
    24 System according to claim 1, characterized in that the actuator device (200, 200 ') comprises:
    - a radioelectric receiver circuit (23), capable of receiving the wireless radioelectric signals sent by the communication circuit (104) of at least the sensor device (100),
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    - a reception interface (25) linked to the radioelectric receiver circuit (23) to allow the individual to perform all types of programming, selection and adjustments for the reception of the wireless signals,
    - a coupling unit of the actuator device (200, 200 ’) to the electrical installation (20),
    - a disconnection circuit that can be connected to the electrical installation (20),
    - a safety circuit to check the correct functioning of the actuator device (200, 200 ’),
    - a wrapping and electrical insulating framework that includes at least these circuits, and
    - a power supply to power all your circuits
    System according to claim 24, characterized in that the coupling unit is located on one of the outer faces of the enclosure whose configuration is likely to be linked to a DIN rail of a general panel (18) of the electrical installation switchgear ( 20), or of an independent electrical panel and comprises at least one electrical input and output capable of being linked to the wiring of said low switchgear, or high voltage to allow the actuator device (200) to interrupt the electrical flow.
    26 System according to claim 25, characterized in that the disconnection circuit of the electrical installation (20) comprises:
    - a contactor block (19) consisting essentially of a contactor that interrupts the electrical flow when it separates its contacts from each other, and
    - a power circuit (26) linked to the contactor block (19) that allows it to separate or join its contacts.
    27 System according to claim 25, characterized in that the safety circuit comprises a power interface (27) linked to the power circuit (26) that allows checking the operation of the contactor block (19), rearming the power circuit (26), reset and select the type of reset.
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    28 System according to claim 24, characterized in that the coupling unit is located on one of the outer faces of the enclosure and comprises a male plug (22) that can be inserted into an AC outlet (21) of the installation electric (20).
    29 System according to claim 28, characterized in that the disconnection circuit comprises a controlled overcurrent and bypass circuit (30) capable of causing a grounding of the electrical flow of the electrical installation (20) and of causing a controlled overcurrent of the same flow in the electrical installation (20), in order to ensure that an automatic circuit breaker and magneto-thermal switchgear of said installation is triggered and the electrical flow is interrupted.
    System according to claims 24, characterized in that the actuator device (200, 200 ') comprises a receiver of radioelectric interruption impulses linked to the disconnection circuit, capable of recognizing the interruption radioelectric impulse sent through the electrical installation itself (20) and from the sensor device (100) activating said disconnection circuit so that it interrupts the flow of the electrical installation (20).
    Method of prevention against electric shocks and / or electric arcs on individuals that are close to an electrical installation (20) which is used by the system described in any of the preceding claims, characterized in that it comprises the following steps:
    - position an actuator device (200, 200 ’) in the electrical installation (20),
    - position at least one sensor device (100),
    - select by means of a control interface (8), included in the sensor device (100), a mode of use of the sensor device (100),
    - wirelessly detect a nearby electric field by means of a detector antenna (1) comprised in the sensor device (100),
    - amplify the signal of the nearby electric field by means of an amplification circuit (101),
    - compare said electric field signal by means of a comparison circuit
    (102), with threshold values included in a control and command circuit
    (103),
    - send a radio signal, through a communication circuit (104), to
    5 actuator device (200, 200 ’) to prevent the electrical flow of the installation
    electric (20) when any of the threshold values is exceeded, and
    - send an acoustic, visual or vibratory signal, by means of a warning circuit (105), to the individual that is close to the electrical installation (20) when any of the threshold values is exceeded.
    10
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    同族专利:
    公开号 | 公开日
    EP3432008A1|2019-01-23|
    WO2017051054A1|2017-03-30|
    US20190020191A1|2019-01-17|
    ES2610031B1|2018-02-07|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    EP1296150A1|2001-09-25|2003-03-26|HD Electric Company|Wearable electric field detector|
    US7023350B2|2002-07-23|2006-04-04|Eliezer Sanchez|Personal protection device|
    ES2241467B1|2003-10-31|2006-11-16|Ricardo Palacios De La Olla|HIGH VOLTAGE LINE WARNING DETECTOR.|
    US7292045B2|2004-09-04|2007-11-06|Applied Materials, Inc.|Detection and suppression of electrical arcing|
    ES2407554B2|2011-11-21|2015-09-17|Universidad De La Rioja|AUTOMATIC PROTECTION SWITCH AGAINST DIRECT CONTACTS.|
    CN103091565B|2013-01-31|2016-02-03|北京森馥科技股份有限公司|Direct current formate field intensity detection method and system|
    ES2534702B1|2013-09-24|2016-02-09|Ontech Security, Sl|ELECTROSTATIC FIELD SENSOR AND SECURITY SYSTEM IN INTERIOR SPACES|AT521137B1|2018-06-21|2019-11-15|Adaptive Regelsysteme Ges M B H|Mobile electrical workplace with protective equipment against electric shock|
    IL267016A|2019-05-30|2019-12-31|Yaser Ahmed Roba Falah|Independent and wearable electric shock alerting and protecting device for individuals|
    法律状态:
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    ES201531367A|ES2610031B1|2015-09-24|2015-09-24|SYSTEM AND METHOD OF PREVENTION AGAINST ELECTRIC SHOCK AND / OR ARCOS ELECTRICAL|ES201531367A| ES2610031B1|2015-09-24|2015-09-24|SYSTEM AND METHOD OF PREVENTION AGAINST ELECTRIC SHOCK AND / OR ARCOS ELECTRICAL|
    EP16848195.0A| EP3432008A1|2015-09-24|2016-09-23|System and method for prevention against electric discharges and/or electric arcs|
    PCT/ES2016/070668| WO2017051054A1|2015-09-24|2016-09-23|System and method for prevention against electric discharges and/or electric arcs|
    US15/762,823| US20190020191A1|2015-09-24|2016-09-23|Prevention system and process against electric shocks and/or electric arcs|
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