• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a surge protection device for protecting luminaires against strong surges. The surge protector includes shunt impedance elements (510, 520) positioned in connections (150, 155) between a driver (120) and a light emitting diode module (130) to direct current generated by the surge protector. differential mode overvoltages and or common mode overvoltages to earth so that the light emitting diode elements (170) in the light emitting diode module (130) are not destroyed. Series impedance elements (710, 720) may also be provided between the pilot (120) and the shunt impedance element (510, 520).
    公开号:BE1024146A9
    申请号:E20145138
    申请日:2014-12-19
    公开日:2017-11-23
    发明作者:Yves Borlez
    申请人:Schreder Sa;
    IPC主号:
    专利说明:

    "Surge protection for light-emitting diodes"
    Light-emitting diode (LED) luminaires are often subject to high voltages with different origins. These overvoltages can be generated by lightning strikes, transient phenomena during switching on / off of inductive loads connected to the same network as the LED luminaire, or by heavy industrial machines.
    In addition, in some situations, overvoltages can be generated by electrostatic charges that have built up on the luminaire body and may find a way to discharge through the LEDs and the LED driver into the luminaire housing. to the connection lines to the distribution network. LEDs are particularly sensitive to high voltage discharges and could be damaged even without apparent damage to the LED driver. This may result in shorting some, if not all, LEDs in a group of LEDs since their chips have been destroyed by high voltages.
    These large overvoltages can be either in differential mode where the high voltage appears in the mains supply, that is to say between the line and neutral conductors of the mains supply, or in common mode where the two line conductors and neutral of the mains supply are subjected to a transient phenomenon of high voltage with respect to the earth. A combination of differential mode and common mode overvoltages is also possible.
    In order to protect a luminaire against high overvoltages, protection components are often provided on the luminaire input path, that is, between the network supply and a driver for an associated light emitting diode module and include often metal oxide varistors (MOV) or gas discharge tubes (GDT) or a combination of both. These protection components are relatively effective against differential mode overvoltages, since they are connected between the line and neutral conductors and absorb the energy of the overvoltage having a current whose intensity can be several kA. These protection components tend to provide good protection for the driver, since it is the most sensitive to differential mode overvoltages.
    But the problem is different for common mode overvoltages. There are two types of situations depending on the IEC protection class to which the luminaire is assigned. In the case of a class I luminaire, the presence of a protective earth connection (PE) allows the protection components to be connected between the line and the earth or between the neutral and the earth. These protection components tend to provide good surge protection in common mode. In addition, series fuses inserted between the input and the protection component will cut the circuit when the protection components are short-circuited.
    In the case of a Class II luminaire, there is no PE connection and no connection is allowed between the line and neutral conductors of the mains supply and the luminaire housing for reasons of electrical safety. . This means that only differential protection components can be used for Class II luminaires. Nevertheless, this does not mean that an overvoltage can not find a reliable return path to the earth, since a return path may inadvertently be provided by the metal frame or enclosure of the fixture mounted on a metal pole which is, in turn, in direct contact with the ground.
    In WO-A-2014/029772, an insulative member capable of withstanding the voltage levels of lightning strikes on the electrical path of a ground fixture frame is provided to isolate the LED fixture from the ground. Without return currents, there can be no damage to the luminaire. This is possible when the luminaire frame is mounted on a fiberglass or concrete post but is difficult to implement when the luminaire frame is mounted on a metal post.
    In addition, it is also important to consider the potential danger to LEDs due to high static voltages that can be accumulated by electrifying the luminaire frame due to the presence of heavily charged clouds during a thunderstorm. In this case, it is also beneficial to avoid the high voltage differences between the LEDs and the luminaire frame. Summary of the invention
    Therefore, an object of the present invention is to provide surge protection for LEDs which are the most sensitive components to high overvoltages.
    Another object of the present invention is to provide an inexpensive, easy to implement measure to improve the protection of luminaire LEDs against overvoltages both in common mode and in differential mode.
    According to one aspect of the present invention, there is provided an overvoltage protection device for protecting a luminaire, the luminaire comprising a frame, at least one driver and at least one light emitting diode module, each driver and each light emitting diode module being mounted on the frame with an electrical connection between a driver and its associated light emitting diode module, the overvoltage protection circuit including at least one shunt impedance element located between the electrical connection between each driver and its diode module Each associated electroluminescent element and the frame, each shunt impedance element comprising at least one of: a capacitor, a resistor and a semiconductor-based component.
    By providing at least one shunt impedance element between the electrical connection between the driver and its associated electroluminescent module and the frame, the strong currents generated due to overvoltages are redirected to earth via the frame and do not affect the light-emitting diodes in the light-emitting diode module. It should be understood that at least one shunt impedance element is provided for each of the LEDs + and LEDs of the LED module.
    Advantageously, by using capacitors, resistors, and semiconductor-based components, a reliable and relatively inexpensive solution can be provided for overvoltage protection for light-emitting diode modules and their associated light-emitting diodes. In particular, by using capacitors and resistors, there is no threshold at which capacitors and resistors will always operate and any overvoltage will be drifted through the frame and then back to earth.
    In one embodiment, the at least one light emitting diode module comprises a printed circuit board and the at least one shunt impedance element is mounted thereon.
    In another embodiment, said at least one shunt impedance element is located in a junction box between the driver and the light emitting diode module.
    In one embodiment, the at least one shunt impedance element comprises a capacitor. Each capacitor may comprise either a capacitor X or a capacitor Y having predetermined electrical safety characteristics. Said capacitors may have a capacitance value between 10 nF and 1000 nF.
    In another embodiment, said at least one shunt impedance element comprises a resistor. Said resistor may have a resistance value between 1 ΜΩ and 10 ΜΩ.
    In a further embodiment, said at least one shunt impedance element comprises a semiconductor-based component having a tripping voltage that is less than an insulating voltage between the light-emitting diode module and the frame. The semiconductor-based component may comprise a zener diode or a semiconductor surge suppressor.
    In addition, at least one serial impedance element can be positioned between the at least one driver and the at least one shunt impedance element.
    In one embodiment, said at least one shunt impedance element comprises an inductance coil.
    In another embodiment, said at least one serial impedance element comprises a common mode filter. The common mode filter may comprise two coupled inductance coils.
    Brief description of the drawings
    For a better understanding of the present invention, reference will now be made, by way of example only, to the accompanying drawings in which:
    Figure 1 illustrates a schematic view of a typical outdoor LED fixture;
    Figure 2 is similar to Figure 1 but illustrates the propagation of a differential mode surge across the luminaire;
    Figure 3 is similar to Figure 1 but illustrates the propagation of a common mode overvoltage across the luminaire;
    Figure 4 illustrates a schematic overview of the use of protection components at the entrance of a luminaire;
    Figure 5 is similar to Figure 1 but illustrates surge protection components for LED elements according to the present invention;
    Fig. 6 is similar to Fig. 5 but illustrates a current flowing through the overvoltage protection components in the case of an overvoltage; and
    Fig. 7 is similar to Fig. 5, but illustrates overvoltage protection components for LED elements according to the present invention.
    Description of the invention
    The present invention will be described in connection with particular embodiments and with reference to certain drawings but the invention is however not limited thereto. The drawings described are only schematic and are non-limiting. In the drawings, the size of some of the elements may be exaggerated and not drawn to scale for illustrative purposes.
    Luminaires are often composed of a metal frame connected to the ground by a protective earth connection (PE). This is the case for a class I luminaire (IEC protection class). In the case where the luminaire is not equipped with a PE connection, the luminaire is called a class II device. Nevertheless, this does not mean that there is no possibility of a return to earth, since the metal frame may be in contact with a metal pole which is, in turn, in relatively good contact with the metal. Earth. However, the earth is not as reliable in providing electrical safety but can be very good for the return of surge currents.
    Referring first to Figure 1, there is shown a typical outdoor luminaire 100. The luminaire 100 comprises a metal frame 110 on which an LED driver 120 and an LED module 130 are mounted. The metal frame 110 has a transparent or lens portion 140 which is aligned with the LED module 130 so that the light provided by the LED module can be directed to a suitable area or region to be illuminated by the luminaire 100.
    The term "metal frame" as used herein is meant to refer not only to a frame in the housing or housing of the luminaire in which luminaire components are mounted but also to the housing or luminaire housing, in many cases. Embodiments, the metal frame includes the housing or housing of the luminaire.
    The LED driver 120 includes a primary side 120A and a secondary side 120B which are isolated from each other (not shown), the primary side being connected to the mains supply 160 and the secondary side being connected to the module. LED 130 by means of electrical connections 150, 155, an electrical connection being connected to the LED line + (not shown) and the other electrical connection being connected to the LED line (also not shown). As shown, the mains supply 160 has a line conductor 160L and a neutral conductor 160N. The metal frame 110 has a PE connection 165 as is the case for class I luminaires as described above.
    For class II luminaires (not shown), there is no PE connection and the frame 110 is connected to the ground via the metal frame 110 and the metal pole or mast (not shown) on which the metal frame is mounted. The isolation between the primary and secondary sides 120A, 120B of the LED driver 120 may, depending on the type of LED driver, be able to withstand a limited high voltage to prevent overvoltage from reaching the driver's secondary side 120B. LED 120.
    The LED module 130 includes a plurality of LED elements 170 arranged in a pattern on a printed circuit board 180, the printed circuit board including LED + and DEL- lines to be connected to the respective electrical connections 150, 155 as described above. above. It will be readily appreciated that the LED elements 170 can be arranged in any suitable pattern on the printed circuit board 180 according to the desired lighting requirements.
    The LED module is mounted on a heat sink 190 for the dissipation of heat generated by the LEDs 170 when the luminaire 100 is turned on.
    As described above, the line and neutral conductors 160L and 160N feed the primary side 120A of the LED driver 120 to the grid voltage, typically including an AC voltage of about 230V (at least in continental Europe). The secondary side 120B transforms the mains voltage to provide a DC current (and voltage) for the LED module 130, and in particular, to the printed circuit board 180 on which the LEDs 170 are mounted.
    As described above, the LED driver 120 provides, most of the time, electrical isolation between its side or primary circuit 120A and its side or secondary circuit 120B that can withstand some large overvoltages as described above. However, this may not be the case for all LED drivers and additional surge protection is required for the LED module 130.
    The LED elements 170 and the circuit board 180 on which they are mounted are insulated from the metal frame 110 of the luminaire 100 by an insulating layer 185 provided between the printed circuit board 180 and the heat sink 190.
    FIG. 2 illustrates the propagation of a differential mode overvoltage occurring between the line and neutral conductors 160L, 160N of the luminaire 100 shown in FIG. 1. The elements of the luminaire 100 previously described in FIG. 1 have the same numbers and do not will not be described again here.
    In this case, the high voltage is applied mostly to the components in the primary side 120A of the LED driver 120 (not shown in detail). These components may include capacitors with electromagnetic capacitance (EMC), common mode filters, rectifier bridges, and switching transistors.
    In the majority of situations as described above, the input of the LED driver 120 will be the victim of such an overvoltage 200 which has an input path 210 and an output path 220, and the isolation between the the primary side 120A and the secondary side 120B in the LED driver 120 may be sufficient to protect the LEDs 170. Nevertheless, if such a differential overvoltage propagates in the secondary side 120B as indicated by the input path 230 and the output path 240 and causes a strong surge 250 between the LED + and DEL- connections (not shown) on the printed circuit board 180, it is also capable of destroying the LED elements 170 as well as the printed circuit board proper on which they went up.
    FIG. 3 illustrates the propagation of a common mode surge occurring on the two line and neutral conductors 160L, 160N of the luminaire 100 shown in FIG. 1 with respect to the earth. The elements of the luminaire 100 previously described in FIG. 1 have the same numbers and will not be described again here.
    This type of situation is more dangerous for the LED elements 170, since a common mode overvoltage can propagate through the LED driver 120 because the isolation barrier between the primary side 120A and the secondary side 120B is often avoided by some EMC capacitors, indicated for example at 300, which provide a high speed path through the LED module 130.
    In addition, the LED drivers for class II luminaires are also insulated from the metal frame 110 of the luminaire 100 and do not provide an internal return to earth. Therefore, an overvoltage striking the primary side 120A (input) of the LED driver 120 is almost completely transferred to the secondary side 120B (output) and then to the LED module 130 through the connections 150, 155, as indicated by the arrow 310, until a break in voltage, as indicated at 320 and 330, occurs on the printed circuit board 180 on which the LEDs 170 are mounted.
    As the heat sink 190 tends to be electrically and thermally conductive, the current passes from the voltage break as indicated at 320, 330, through the insulating layer 185 (which is also destroyed by the surge) to the heat sink. 190 in the metal frame 110 on which the heat sink 190 is mounted, as indicated by the arrows 340A, 340B, 340C, 340D, 340E, 340F. The flow of current merges into the metal frame 110 and then passes along the metal frame 110, as indicated by the arrow 350, to the earth via the PE connection 165. This is how the overvoltage common mode finds its way back to the ground, that is to say via the metal frame 110 and its connection PE 165.
    For class II luminaires, the common mode overvoltage is transferred to earth by the mechanical connection between the frame and the metal pole or mast on which they are mounted.
    Although six current paths are represented passing through the heat sink (190) to the frame 110, it is to be understood that this is for illustrative purposes only and that any number of current paths can be generated through the heat sink according to the break zones on the circuit board 180 and / or the failure of the LED elements 170.
    In addition, the circuit board 180 on which the LEDs 170 are mounted often includes large areas of copper for heat dissipation purposes. These large areas create a relatively large capacitance that can allow high-speed overvoltages to pass and generate damaging currents through the LEDs 170. On the other hand, when an electrostatic charge builds up on the metal frame 110 of the fixture 100 or when the local earth experiences a sudden increase in potential due to a local lightning strike, as indicated in 360, the voltage between the metal frame 110 and the respective line and neutral conductors 160L, 160N will be so high that the surge will find a return by the connection PE 165 due to the potential difference of plus kV between the frame 110 and the mains supply lines 160. A break in voltage will take place between the frame and the line and neutral conductors 160L, 160N, passing through the LED elements 170 and the LED driver 120.
    As described above, for class I luminaires protection components will be provided for common mode overvoltages. A schematic diagram 400 is shown in Figure 4, which illustrates the location of such protective components.
    In Fig. 4, a trunk-side input 410 includes the respective line and neutral terminals 410L, 41 ON and a PE connection 41 OPE, and is connected to an input 420 at the primary side 120A on the LED driver 120 as shown in FIG. The terminals at the input 420 are respectively labeled 420L, 420N and 420PE and each terminal is connected to one of the respective terminals 41OL, 41 ON and 41 OPE via a connecting wire 430L, 430N and 430PE as shown.
    Serial fuses 440, 450 are shown in the respective line and neutral lead wires 430L, 430N. Protection elements 460, 470 and 480 are also shown, which are respectively located between the line connecting wire 430L and the PE connection wire 430PE; the 430N neutral connection wire and the PE 430PE connection wire; and the line and neutral lead wires 430L, 430N as shown.
    Protection elements 460, 470, 480 may comprise metal oxide varistors (MOV), gas discharge tubes (GDT) or a combination of MOV and GDT as described above.
    The 440, 450 series fuses work in conjunction with the protection components 460, 470, 480 and can be operated to close the circuit, i.e. the fixture's mains supply, when the protection components 460, 470 , 480 are short-circuited.
    However, although these protection components 460, 470, 480 operate to protect the LED driver 120, they may not be sufficient to prevent the destruction of at least a portion of the circuit board 180 and at least some of the LEDs 170 mounted thereon before they are activated.
    Therefore, in order to avoid destruction of the LEDs 170, a good approach is to ensure that no dangerous voltage can be generated between the circuit board 180 on which the LEDs 170 are mounted and the metal frame. 110 of the luminaire 100.
    FIG. 5 shows a luminaire 500 which is identical to the luminaire 100 in FIG. 1, except for the addition of protection components according to the present invention. Bypass impedance elements 510, 520 which are inserted between each of the respective electrical connections 150, 155 (between the LED driver 120 and the LED + and LED lines on the printed circuit board 180 to which the LED elements 170 are connected) and the metal frame 110 of the luminaire 500.
    In the case of a common mode overvoltage, these shunt impedance elements 510, 520 provide a direct return path for the overvoltage currents via the metal frame 110 of the luminaire 500 to earth. These shunt impedance elements 510, 520 may also be used to prevent the development of electrostatic charge and a high static voltage between the circuit board 180 and the metal frame 110 of the luminaire 500 during the development of an electrostatic charge in clouds as a precursor to or during thunderstorms.
    Since the LED driver 120 is generally more resistant to large surges than the LEDs 170, it tends to survive such large surges as the LEDs will be destroyed. In addition, the LED driver 120 is also capable of absorbing the electrostatic charges delivered by the shunt impedance elements 510, 520 so that it prevents electrostatic discharges from passing through the LEDs 170. This is shown more clearly in Figure 6.
    Figure 6 shows the luminaire 500 with an overvoltage 600 at the mains-side input 160. The overvoltage 600 passes through the primary side 120A (input) of the LED driver 120, as indicated by the arrow 610, and is almost completely transferred. to the secondary side 120B, as indicated by the arrow 620, and through it, as indicated by the arrows 630, 640 and in the connections 150, 155. Instead that the overvoltage causes damage to the LED elements 170 as described above with reference to FIG. 3, the current is channeled via the shunt impedance elements 510, 520 as indicated respectively by the arrows 650, 660 in the metal frame 110 and towards the earth via the PE connection 165, as indicated by arrows 670, 680 and 690.
    The two common-mode and differential-mode overvoltages at the input of the LED driver 120 can also generate a high voltage between the LED + and LED lines on the printed circuit board 180 connected to the LED driver 120B secondary side 120B. the respective connections 150, 155. The two branch impedance elements 510, 520 are effective to reduce this high voltage. In this case, the two shunt impedance elements 510, 520 act as if they were connected in series on the LED + and LED- lines, that is between the connections 150, 155 and the frame 110.
    It is also possible to limit the surge current and improve driver protection by inserting serial components before the shunt impedance elements 510, 520 as shown in FIG. 7.
    FIG. 7 shows a luminaire 700 similar to that shown in FIG. 5 but with the addition of shunt impedance elements 710, 720 in the respective connections 150, 155 between the LED driver 120 and the impedance elements These series impedance elements 710, 720 also further reduce the voltage between the printed circuit board 180 and the LEDs 170 and the metal frame 110 and act as current limiters in the event of any overvoltages. having no impact on the DC current that is supplied to the LEDs 170 by the LED driver 120.
    In a preferred embodiment, the shunt impedance elements 510, 520 and / or the serial impedance elements 710, 720 are located on the printed circuit board 180 on which the LEDs 170 are mounted. Alternatively, these impedance elements may also be available in a junction box located anywhere between the secondary side 120B of the LED driver 120 and the printed circuit board 180 on which the LED elements 170 are mounted (no shown). In another variant (also not shown), the series impedance elements 710, 720 may be located in a junction box located between the secondary side 120B of the LED driver 120 and the printed circuit board 180 with the elements d Bypass impedance 510, 520 located on the printed circuit board 180.
    The selection of the type of shunt impedance element is important to provide effective protection and such a shunt impedance element may include one of the following: a capacitor, a resistor and a semiconductor-based component such as, but not limited to, a zener diode and a semiconductor surge protector.
    If the bypass impedance elements 510, 520 comprise capacitors, they will form, with the primary to secondary parasitic capacitance of a transformer between the primary side 120A and the secondary side 120B of the LED driver 120 (shown as 300 on the FIGS. 3 and 6), a divider bridge which will significantly reduce the common-mode voltage at the output of the LED driver 120, provided that the bypass capacitance values are significantly larger than the parasitic capacitance values of the primary sides and secondary 120A, 120B of the transformer in the LED driver 120. Since these bypass capacitors are effectively positioned on an insulation layer (the layer 185 in the LED module 130), it is important to select capacitors which are suitable for this type of application, for example, line filter capacitors such as capacitors X (connectable between and neutral) and / or Y capacitors (connectable between line and ground), which have been tuned to meet the required international safety requirements. Capacitance values between 10 nF and 1000 nF are appropriate and it has been found that capacity values around 100 nF give good results.
    If the shunt impedance elements comprise resistors, these can be used to prevent the accumulation of electrostatic voltage between the metal frame 110 and the connection lines 150, 155 between the LED driver 120 and the LED lines + and DEL- on the circuit board 180 which could generate a disruptive discharge. The typical resistance values of these resistors are in the range of 1 Ω to 10 Ω, preserving the security of the electrical insulation between the printed circuit board 180 and the associated LEDs 170 relative to the metal frame 110.
    If the shunt impedance elements comprise semiconductor-based components, they will trigger a predetermined voltage, and it is important to ensure that their trigger voltage is significantly lower than the intrinsic isolation level of the semiconductor component. printed circuit board 180 and associated LED elements 170 relative to the metal frame 110.
    Of course, the shunt impedance elements may include any combination of capacitors, resistors, and semiconductor-based components depending on the protection requirements.
    The series impedance elements 710, 720 may include inductance coils which provide high impedance at high speed overvoltages while being nearly transparent to the DC current supplying the printed circuit board 180 and associated LEDs 170.
    In addition, a common mode filter can be configured from two coupled inductance coils (not shown) having appropriate inductance values.
    It will be readily appreciated that the overvoltage protection device defined by the shunt impedance elements (and the series impedance elements, if any) can be supplemented by provision of series fuses and protection elements between the mains supply 160 and the primary side 120A of the LED driver 120 as described above with reference to FIG. 4.
    The present invention has been described with reference to a luminaire comprising a single LED module and a single LED driver. However, it will be appreciated that an LED driver can drive more than one LED module in the fixture. In addition, there may be more than one LED driver in the fixture that drives one or more LED modules. When there is more than one LED module in the luminaire, the bypass impedance elements may be positioned across each LED module in respective connections between the LED driver and each LED module.
    Although the present invention has been described with reference to specific embodiments, it will readily be appreciated that other embodiments are possible to prevent the destruction of LED elements in luminaires during overvoltages.
    权利要求:
    Claims (15)
    [1]
    1. Overvoltage protection device for protecting a luminaire, the luminaire comprising a frame, at least one driver and at least one light-emitting diode module, each driver and each light-emitting diode module being mounted on the frame with an electrical connection between a driver and its associated light emitting diode module, the overvoltage protection circuit comprising at least one shunt impedance element located between the electrical connection between each driver and its associated light emitting diode module and the frame, each shunt impedance comprising at least one of: a capacitor, a resistor and a semiconductor-based component.
    [2]
    The overvoltage protection device of claim 1, wherein said at least one shunt impedance element is located in a junction box between the driver and the light emitting diode module.
    [3]
    An overvoltage protection device according to any one of claims 1 to 3, wherein said at least one shunt impedance element comprises a capacitor.
    [4]
    The overvoltage protection device of claim 4, wherein each capacitor comprises one of: capacitor X or Y capacitor having predetermined electrical safety characteristics.
    [5]
    The overvoltage protection device of claim 5, wherein each capacitor has a capacitance value between 10 nF and 1000 nF.
    [6]
    An overvoltage protection device according to any one of claims 1 to 6, wherein said at least one shunt impedance element comprises a resistor.
    [7]
    An overvoltage protection device according to claim 7, wherein said resistor comprises a resistance value of 1 Ω and 10 MΩ.
    [8]
    The overvoltage protection device of any one of claims 1 to 8, wherein said at least one shunt impedance element comprises a semiconductor-based component having a trigger voltage which is lower than an isolation voltage between the light emitting diode module and the frame.
    [9]
    The overvoltage protection device of claim 9, wherein the semiconductor-based component comprises a zener diode.
    [10]
    The overvoltage protection device of claim 9, wherein the semiconductor-based component comprises a semiconductor surge suppressor.
    [11]
    An overvoltage protection device according to any one of claims 1 to 11 further comprising at least one in-series impedance element positioned between said at least one driver and said at least one shunt impedance element.
    [12]
    The overvoltage protection device of claim 12, wherein said at least one serial impedance element comprises an inductor.
    [13]
    The overvoltage protection device of claim 12, wherein said at least one serial impedance element comprises a common mode filter.
    [14]
    The overvoltage protection device of claim 14, wherein the common mode filter comprises two coupled inductance coils.
    [15]
    The overvoltage protection device of claim 14, wherein the common mode filter comprises two coupled inductance coils.
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    BE1024146B9|2017-11-23|
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    US10117301B2|2018-10-30|
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    EP3024302A1|2016-05-25|
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    CN105636261A|2016-06-01|
    PL3024302T3|2019-03-29|
    DK3024302T3|2019-02-18|
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    CN204089181U|2014-01-31|2015-01-07|北京通力盛达节能设备股份有限公司|A kind of lightning surge protection circuit and LED drive power|WO2019025213A1|2017-07-31|2019-02-07|Philips Lighting Holding B.V.|Surge protected luminaire|
    JP2020019404A|2018-08-01|2020-02-06|株式会社小糸製作所|Lighting fixture|
    NL2021706B1|2018-09-25|2020-05-07|Schreder Sa|Improved luminaire driver|
    法律状态:
    2018-02-12| FG| Patent granted|Effective date: 20171122 |
    优先权:
    申请号 | 申请日 | 专利标题
    EP14194411.6|2014-11-21|
    EP14194411.6A|EP3024302B1|2014-11-21|2014-11-21|Surge protection for light-emitting diodes|
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