JP6634580B2 - Light-emitting diode lighting - Google Patents

Description

  The present invention relates to a light-emitting diode lamp applied in the light-emitting diode technology, in particular, has a main lighting load and an afterglow lighting load at the same time, and when the main lighting load is turned off, the afterglow lighting load is used as an auxiliary afterglow light source. The present invention relates to a light-emitting diode lamp.

  Generally, after the lamp as the main lighting is turned off, the darkness makes it impossible for the human eyes to identify the direction suddenly, but in this case, it is necessary to wait for the eyes to adapt to the environment. In order to solve this problem, please refer to FIG. 1 which is a block diagram showing a configuration of a well-known lighting device of a system that gradually darkens after power is turned off. This well-known illumination lamp of a system that gradually darkens after the power is turned off includes a charging control unit 92, a built-in power storage unit 93, a light amount gradually decreasing drive control unit 94, a switching control unit 96, and a light emitting source 95 in a lamp body 90. Is provided. When the commercial power supply 91 is not interrupted, the switching control unit 96 is switched to the commercial power supply use mode, and the light emitting source 95 is directly driven to emit light stably. The built-in power storage unit 93 is charged. When the commercial power supply 91 is cut off, the switching control unit 96 is switched to the power mode using the built-in power storage unit 93, so that the light emission luminance of the light emission source 95 is controlled by the light amount gradually decreasing drive control unit 94, and the light emission state is changed from a bright state. The light emission luminance of the light emission source 95 is gradually changed to a dark state.

  This illumination lamp of a system that gradually darkens after the power is turned off employs the same light emitting source 95 as a main light source and a residual light source and employs the same drive circuit to drive the main light source and the residual light source. In general, the luminance of the residual light source is generally required to be such that the human eyes can roughly recognize the azimuth in the dark, and since the luminance of the main light source is not necessary, the light source 95 remains at the same time. In addition to using the light source, driving the main light source and the residual light source using the same drive circuit may encounter the following problems in design.

  1. When a high operating voltage is adopted for the LED lamp, the operating current of the light emitting source 95 is exceptionally higher than DC 15 V because the operating current is small and the efficiency of the driver is high. If an energy storage element such as a battery is employed, and its voltage is only a few volts, and if the light source 95 is employed as a residual light source, a plurality of series connected supercapacitors or batteries may be used. Otherwise, a booster circuit is required, but this not only increases the cost, but also occupies the layout space of the circuit board, resulting in design difficulties. .

  2. It may be desirable for the color of the residual light source to be different from the color of the main light source, but if there is only one set of light sources 95, only the same one set of colors can be used, and If there is a need for a different color for the residual light source, the need cannot be met, and the product loses competitiveness.

  3. The light emitting source 95 can meet the required brightness by adopting a highly efficient light emitting diode to meet the needs of the brightness. When a high-efficiency light emitting diode is used as the afterglow light source, the rated current value is almost several hundred times the afterglow work current value, and it becomes difficult to control the afterglow circuit. When an independent low-efficiency LED is used as an afterglow LED, its rated current is approximately several tens of times the afterglow work current value. In addition, since the current feedback resistor can be provided independently, the design of the afterglow circuit is simplified.

  4. When the power supply is cut off, the residual light source is forcibly emitted, so that the need for the unnecessary residual light source cannot be met.

  5. When the power is cut off by the wall switch, the switching control unit switches to the residual light source. However, when the power is turned off by the remote control or the power line communication control, the commercial power supply is not cut off and the residual light source does not emit light, so that the feet can be seen. About the brightness cannot be secured.

  In view of this point, how to research and improve the above-mentioned known disadvantages, to provide afterglow assistance when the main light is turned off, the volume of the afterglow drive circuit, the variety of types of energy storage elements The simplicity of selectivity and the complexity of circuit design, as well as enabling / disabling the persistence function according to the needs of the persistence function, are just the goals that the relevant industry has to research. ing.

  In order to solve the above-mentioned deficiencies of the prior art, the present invention provides a light emitting diode lamp including a main lighting circuit module and an afterglow circuit module. The main lighting circuit module includes a main lighting driving device and a main lighting load, and the main lighting driving device is used to drive the main lighting load to emit light. The afterglow circuit module is electrically connected to the main lighting circuit module and receives a DC partial voltage provided by the main lighting circuit module, and is electrically connected to the DC constant voltage circuit device. The energy storage device includes a current control device electrically connected to the energy storage device, and an afterglow lighting load driven by the current control device to emit light.

  For this reason, the main object of the present invention is to provide the afterglow lighting when the main lighting load and the afterglow lighting load are driven by the main lighting circuit module and the afterglow circuit module respectively, and when the main lighting is turned off. Another object of the present invention is to provide a light-emitting diode lamp in which the main lighting load and the afterglow lighting load can be appropriately selected according to the needs regarding the colors of the main lighting and the afterglow.

  A second important object of the present invention is to set the operating voltage of the afterglow lighting load according to the voltage of the energy storage element, since the operating voltage of the afterglow lighting load is independent of the operating voltage of the main lighting load. Another object of the present invention is to provide a light-emitting diode lamp that can enhance the selectivity of the energy storage element.

  Another object of the present invention is to provide a light emitting diode lamp for operating an afterglow circuit module via a current control device.

  It is still another object of the present invention to provide a light emitting diode lamp that functions by providing a stable direct current to a persistence circuit module by a direct current constant voltage device.

  Another object of the present invention is to provide a simple circuit in which the rated output of the afterglow lighting load is smaller than that of the main lighting load, and the main lighting circuit module and the afterglow circuit module are each provided with a current feedback resistor. An object of the present invention is to provide a light emitting diode lamp capable of realizing a function of afterglow.

  Another object of the present invention is to provide a switch so that the afterglow illumination load can be switched on and off in order to meet needs that do not require the afterglow illumination load.

  It is another object of the present invention to provide a light emitting diode lamp in which the simultaneous operation of the main lighting circuit module and the afterglow circuit module is avoided by the disconnect control device.

  Another object of the present invention is that when a light-off signal is input to a microcomputer by operating a remote controller or the like, the microcomputer turns off the power supply to the energy element of the DC constant voltage circuit, cuts off the disconnection control power supply, and afterglows. The ability to activate the circuit module and cause the afterglow illumination load to emit light by discharging the energy element.

  Another object of the present invention is that when a light-off signal is input to the microcomputer by operating a remote controller or the like, the microcomputer turns off the power supply for the main lighting load, turns off the main lighting load, and shuts off the disconnection control power supply. To activate the afterglow circuit module. This shutoff signal can be a PWM signal. The luminance of the afterglow can be changed by changing the duty ratio of the PWM signal. The activation time of this shut-off signal is configurable. At this time, the afterglow illumination load exerts the afterglow function. Further, the operation time need not be set. At this time, the afterglow illumination load performs the function of the night light. In addition, in the event of a power failure, the power supply of the disconnection control device operates naturally, thereby exhibiting the function of emergency lighting.

  Another object of the present invention is to cause the afterglow lighting load to emit light at a brightness that is higher than the brightness when the afterglow normal lighting is performed, so that the user can become accustomed to the brightness when the afterglow normal lighting is performed, and gradually. It changes to the luminance when the afterglow is normally lit. The brightness higher than the afterglow normal lighting can be the brightness of the main lighting load or lower. It is still another object of the present invention to provide a light emitting diode lamp that functions by providing a stable DC voltage to a persistence circuit module by a DC constant voltage device.

  The present invention discloses a diode lamp in which the principle of the light emitting diode used is one that can be understood by those skilled in the art, so that the description in the following text does not make a full description. . At the same time, the drawings referred to in the following text are representative of structures associated with features of the invention, and are not necessarily made exactly to the actual dimensions and need not be so. State clearly in advance.

FIG. 2 is a configuration block diagram of a well-known lighting device of a system that gradually becomes dark after a power supply is cut off. 1 is a block diagram illustrating a configuration of a light emitting diode lamp provided in the present invention. 1 is a block diagram illustrating a configuration of a light emitting diode lamp according to a first preferred embodiment of the present invention. FIG. 4 is a schematic view of the afterglow circuit module shown in FIG. 3 of the present invention. (A)-(C) are schematic diagrams of the current control device in the afterglow circuit module presented in the first preferred embodiment. FIG. 5 is a schematic diagram illustrating another implementation state of the afterglow circuit module presented in the first preferred embodiment; FIG. 5 is a schematic diagram illustrating another implementation state of the afterglow circuit module presented in the first preferred embodiment; FIG. 5 is a schematic diagram illustrating another implementation state of the afterglow circuit module presented in the first preferred embodiment; FIG. 4 is a block diagram illustrating a configuration of a light emitting diode lamp according to a second preferred embodiment of the present invention. FIG. 10 is a schematic diagram of the afterglow circuit module shown in FIG. 9 of the present invention. (A)-(D) are schematic diagrams of the current control device in the afterglow circuit module presented in the second preferred embodiment. FIG. 9 is a schematic diagram illustrating another implementation state of the afterglow circuit module presented in the second preferred embodiment; FIG. 9 is a block diagram illustrating a configuration of a light emitting diode lamp according to a third preferred embodiment presented in the present invention. FIG. 10 is a schematic diagram illustrating another implementation state of the afterglow circuit module presented in the third preferred embodiment; FIG. 9 is a configuration block diagram of a light emitting diode lamp of a fourth preferred embodiment presented in the present invention. FIG. 14 is a schematic diagram illustrating another implementation state of the afterglow circuit module presented in the fourth preferred embodiment; FIG. 13 is a block diagram illustrating a configuration of a light emitting diode lamp according to a fifth preferred embodiment presented in the present invention. 9 is a graph showing a pattern of a luminance change of an afterglow illumination load. FIG. 14 is a block diagram illustrating a configuration of a light emitting diode lamp according to a sixth preferred embodiment presented in the present invention. FIG. 15 is a block diagram illustrating a configuration of a light emitting diode lamp according to a seventh preferred embodiment of the present invention.

  Please refer to FIG. 2, which is a structural block diagram of the light emitting diode lamp presented in the present invention. The light emitting diode lamp of the present invention includes a main lighting circuit module 100 and an afterglow circuit module 200 electrically connected to the main lighting circuit module 100.

  The elements constituting the main lighting circuit module 100 include a main lighting drive device 110 and a main lighting load 120, and the main lighting load 120 is electrically connected to the main lighting drive device 110, It is driven by this main illumination driving device 110. The elements constituting the afterglow circuit module 200 include a DC constant voltage device 210, an energy storage device 220, a disconnection control device 230, a current control device 240, and an afterglow illumination load 250.

  The main lighting load 120 includes one or a plurality of light emitting diodes. When the main lighting load includes a plurality of light emitting diodes, the plurality of light emitting diodes are connected in series or in parallel. Similarly, the afterglow lighting load 250 may be comprised of one or more light emitting diodes. When the afterglow illumination load includes a plurality of light emitting diodes, the plurality of light emitting diodes are connected in series or in parallel. If the color of the afterglow lighting load does not need to be different from that of the main lighting load, some or all of the light emitting diodes of the main lighting load can be used as the afterglow lighting load, thereby reducing the cost.

  The operation mode of the light emitting diode lamp is as follows: the DC constant voltage device 210 obtains the DC partial voltage from the main lighting circuit module, converts it further, and provides the DC voltage necessary for the operation of the afterglow circuit module 200. Then, the energy storage element 220 is charged with the DC voltage. The method in which the energy storage element 220 fixes the voltage is based on the fact that the DC constant voltage devices 210 are connected in parallel. Thereby, the time of each discharge of the energy storage element 220 can be fixed, and the energy storage element 220 is protected from being damaged due to overvoltage. When the power supply P of the main lighting drive device 110 of the main lighting circuit module 100 is cut off, the main lighting load 120 is also turned off. At this time, the energy storage element 220 discharges to the afterglow lighting load 250 via the current control device 240. I do.

The connection relationship between the main lighting circuit module 100 and the element arrangement of the afterglow circuit module 200 will be described in detail as follows:
First, please refer to FIG. 3 which is a configuration block diagram of the light emitting diode lamp of the first preferred embodiment presented in the present invention, and FIG. 4 which is a schematic diagram of the afterglow circuit module shown in FIG. The main lighting driving device 110 of the main lighting circuit module 100 is a switching power supply or a linear DC power supply. The main lighting drive unit 110 is connected to a power supply P 1, and the power supply P may be AC or DC. The DC voltage can be further provided through the main lighting driving device 110 to provide a DC partial voltage.

  The current control device 240 in the afterglow circuit module 200 employs a constant current circuit. There are many types of constant current circuits, some of which use integrated circuits or components, and those which use integrated circuits and components. The following are PNP-bipolar transistor (Bipolar Junction Transistor, BJT), NPN-bipolar transistor (Bipolar Junction Transistor, BJT), P-channel field effect transistor (Field Effect Transistor, FET) or N-channel field effect The current control device 240 employing a transistor (Field Effect Transistor, FET) as a constant current circuit will be described one by one.

  The afterglow circuit module illustrated in FIG. 3 is an afterglow circuit module 200 that employs a PNP-bipolar transistor as a constant current circuit, and includes a DC constant voltage device 210, an energy The storage device 220, the disconnection control device 230, the current control device 240, and the afterglow illumination load 250 are included.

  The elements constituting the current control device 240 include a first PNP transistor 241 and a voltage setting element 242. The collector of the first PNP transistor 241 is connected to the positive electrode of the afterglow lighting load 250, the negative electrode of the afterglow lighting load 250 is grounded, and the base of the first PNP transistor 241 is connected through the first resistor 243. And a second resistor 244 is provided between the emitter of the first PNP transistor 241 and the voltage setting element 242, and the second resistor 244 can detect a current. .

  5 (A) to 5 (C) are schematic diagrams of a specific embodiment of the current control device. The voltage setting element 242 includes one first diode (as shown in FIG. 5A), a second transistor (as shown in FIG. 5B), or a first zener diode (see FIG. 5). (C)) or a combination thereof.

  Elements constituting the disconnection control device 230 include a second diode 231, a third resistor 232, and a first capacitor 233. The positive electrode of the second diode 231 may be connected to any of the contacts capable of sensing whether the main lighting load 120 blinks or whether the power supply P of the main lighting driver 110 is turned on, and Conduct only in the direction to avoid backflow. When the main lighting load 120 is turned on or the main lighting driving device 110 is turned on, the second capacitor 233 performs filtering to stabilize the voltage, and the third resistor 232 switches the first PNP transistor 241. When the main lighting load 120 is turned off and the main lighting load 120 is turned off, the second capacitor 233 discharges the third resistor 232 to the ground via the first resistor 243, and the first PNP transistor 241 turns on. Then, the afterglow illumination load 250 is operated.

  The energy storage device 220 is a capacitor, a supercapacitor, or a battery. The energy storage device 220 is connected to a current controller 240.

  The DC constant voltage device 210 is a series-connected constant voltage circuit, and its components include a first NPN transistor 211, a fifth resistor 212, and a third Zener diode 215. The collector of the first NPN transistor 211 is connected to the main lighting circuit module 100 for providing a DC voltage division and the fifth resistor 212, respectively, and the negative terminal of the third Zener diode 215 is connected to the first Zener diode 215. And the fifth resistor 212 is connected to the base of the NPN transistor 211, and the positive electrode of the third Zener diode 215 is grounded.

  FIG. 6 is a schematic diagram showing another embodiment of the afterglow circuit module presented in the first preferred embodiment. As seen from FIG. 6, a first switch 251 that can be freely turned on and off is provided in order to meet needs that do not require an afterglow illumination load. In the current control device 240 shown in FIG. 6, the first switch 251 is connected between the voltage setting element 242 and the second resistor 244, between the voltage setting element 242 and the first resistor 243, It can be provided between the element 242 and the first PNP transistor 241 or between the energy storage element 220 and the current controller 240. The user can cut off or establish the power supply path from the energy storage element 220 to the afterglow illumination load via the first switch 251. When disabling the function of the afterglow lighting or the emergency lighting to the light emitting diode, the function of the afterglow lighting or the emergency lighting can be turned off by cutting off the power supply path from the energy storage element to the afterglow lighting load.

  When the light is turned off by a remote controller or power line communication, a third switch (not shown) can be provided between the main lighting drive device 110 and the main lighting load 120 or in the main lighting drive device 110. The third switch is used to cut off or establish power supply to the main lighting load 120. The second switch 252 receives a light-off signal from a microcomputer or a control circuit, is turned off by the microcomputer or the control circuit, and cuts off power supply to the afterglow lighting load of the main lighting load and the energy storage element. The disconnection control device 230 activates the afterglow illumination load to emit light and consumes the energy of the energy storage element 220 due to the turning off of the main illumination load 120. The second switch 252 is provided between the DC voltage regulator 210 and the energy storage element 220 or between the main lighting circuit module 100 and the DC voltage regulator 210. The second switch 252 and the third switch are elements that can open and close a circuit in response to a designated signal. For example, a P-channel transistor, an N-channel transistor, a PNP transistor, an NPN transistor, a photocoupler, If a desired function is satisfied by a relay or the like, the element is not specified. When a DC power supply is taken out of the light emitting diode lamp train of the main lighting load and supplied to the DC constant voltage device 210, the supply of the DC power supply is stopped when the main lighting load 120 is turned off. In this case, the second switch 252 is used. Design is not required. Further, when the light is turned off by the remote controller or the power line communication or the like, other execution states are shown as follows. A third switch (not shown) can be provided between the main lighting drive 110 and the main lighting load 120 or within the main lighting drive 110. The third switch is used to cut off or establish power supply to the main lighting load 120. The microcomputer receives the off signal, turns off the third switch, and turns off the main lighting load 120. At this time, without providing the second switch 252, the microcomputer directly controls the disconnection control device 230 to cause the afterglow illumination load 250 to emit light. The afterglow lighting time can be set by the timer of the microcomputer. This control signal can be a PWM signal. The luminance of afterglow lighting can be controlled by setting the duty ratio, and the afterglow illumination load 250 can function as afterglow or nightlight depending on whether or not a microcomputer timer is set. Also, when there is a power outage, the disconnection control module 230 has a function as an emergency illuminator that forcibly activates the afterglow illumination load 250 to emit light.

  FIG. 7 is a schematic diagram showing another embodiment of the afterglow circuit module presented in the first preferred embodiment. As seen from FIG. 7, a three-terminal regulator 216 can be selected and used as an element constituting the DC constant voltage device 210. The three-terminal regulator 216 includes an input terminal 2161, an output terminal 2162, and a common terminal. It has a terminal 2163. The DC voltage provided by the main lighting circuit module 100 is connected to the input terminal 2161, the output terminal 2162 is connected to the storage element 220, and the common terminal 2163 is directly grounded.

  For how the afterglow circuit module 200 employing a PNP-bipolar transistor as a constant current circuit achieves a constant current, refer to the following description.

  When the power supply P of the main lighting drive device 110 of the main lighting circuit module 100 is cut off, the main lighting load 120 is also turned off. At this time, the energy storage element 220 discharges to the afterglow lighting load 250 and the afterglow lighting When the load 250 is turned on, the second resistor 244 is connected in series to the emitter of the first PNP transistor 241, and the voltage setting element 242, the first resistor 243, and the base of the first PNP transistor 241 are connected in parallel. Therefore, the sum of the voltage of the emitter and the base of the first PNP transistor 241 and the voltage of the second resistor 244 is fixed. Therefore, the current flowing through the second resistor 244 is fixed, and the collector current of the first PNP transistor 241 is also fixed. If the current of the afterglow illumination load 250 is fixed, the emission intensity is also fixed accordingly. The luminance at this time is the luminance of the afterglow generated by the afterglow illumination load 250, and the energy storage element 220 does not return to the constant current state because the current flowing through the second resistor 244 becomes lower than the set current. Finally, the discharge continues until the afterglow illumination load 250 is turned off. The disconnection control device 230 prevents the main lighting circuit module 100 and the afterglow circuit module 200 from operating at the same time. That is, when the main lighting load 120 of the main lighting circuit module 100 is turned on, the disconnection control device 230 limits the lighting of the afterglow lighting load 250 of the afterglow circuit module 200.

  FIG. 8 is a schematic diagram showing another embodiment of the afterglow circuit module presented in the first preferred embodiment. 8, a first switch 251 that can be turned on and off arbitrarily to respond to a need for an afterglow illumination load in the same place as in FIG. This is an embodiment in which second switches 252 are added to emit light.

  FIG. 9 is a configuration block diagram of a light emitting diode lamp of the second preferred embodiment presented in the present invention, and FIG. 10 is a schematic diagram of the afterglow circuit module shown in FIG. Among them, the afterglow circuit module is an NPN-bipolar transistor type afterglow circuit module 200, and the main lighting circuit module 100 of the second preferred embodiment and the first preferred embodiment is the same; Do not repeat the statement. Elements constituting the afterglow circuit module 200 include a DC constant voltage device 210, an energy storage device 220, a disconnection control device 230, a current control device 240, and an afterglow illumination load 250.

  The elements constituting the current control device 240 include a voltage setting element 242, a first resistor 243, a second resistor 244, and a first NPN transistor 245. Among them, the first NPN transistor 245 has a collector connected to the negative electrode of the afterglow illumination load 250, an emitter connected to the second resistor 244 and grounded, and a voltage setting element 242 connected to the first NPN transistor 245. The base of the first NPN transistor 245 is connected to the energy storage element 220 via the first resistor 243, and is connected to the base and the second resistor 244, respectively.

  FIGS. 11A to 11D are schematic diagrams showing specific implementation states of the current control device. The voltage setting element 242 includes a second NPN transistor (as shown in FIG. 11A) or a first diode (as shown in FIG. 11B) or a Zener diode (as shown in FIG. 11C). As shown), or a first diode (as shown in FIG. 11D) connected in series with the Zener diode.

  The elements constituting the disconnection control device 230 include a third resistor 232, a third NPN transistor 234, a fourth resistor 235, and a second zener diode 236. The collector of the third NPN transistor 234 is connected to the base of the first NPN transistor 245, the emitter of the third NPN transistor 234 is grounded, and one end of the fourth resistor 235 is connected to the main lighting load 120. The fourth resistor 235 and the third resistor 232 are used to set the voltage division, and the first NPN transistor The switching speed of the afterglow illumination load 250 can be increased by using the second zener diode 236, which is used to switch the H.245.

  The energy storage device 220 is a capacitor, a supercapacitor, or a battery. The energy storage device 220 is connected to the positive electrode of the afterglow lighting load 250.

  The DC voltage regulator 210 is a parallel connection type constant voltage circuit, and its components include a fifth resistor 212 and a third zener diode 215. One end of the fifth resistor 212 is connected to the main lighting circuit module 100 that provides a DC partial voltage, and the other end is connected to the negative electrode of the third Zener diode 215 and connected in parallel to the energy storage element 220, The positive electrode of the third Zener diode 215 is grounded.

  For how the afterglow circuit module 200 employing the NPN-bipolar transistor as the constant current circuit achieves the constant current, refer to the following description.

  When the power supply P of the main lighting drive device 110 of the main lighting circuit module 100 is cut off, the main lighting load 120 is also turned off. At this time, the energy storage element 220 discharges to the afterglow lighting load 250 and the afterglow lighting The load 250 is turned on, the emitter of the first NPN transistor 245 is connected in series to the second resistor 244, and the base of the first NPN transistor 245 and the first resistor 243 are connected in parallel to the voltage setting element 242. Since the connection is made and the sum of the base and emitter voltages and the voltage of the second resistor 244 is fixed, the current flowing through the second resistor 244 is also fixed, and the collector current of the first NPN transistor 245 is also the same. When the current of the afterglow illumination load 250 is fixed, the emission intensity is also fixed accordingly.

  FIG. 12 is a schematic diagram showing another embodiment of the afterglow circuit module presented in the second preferred embodiment. As seen from FIG. 12, a first switch 251 that can be freely turned on and off is provided in order to meet needs that do not require an afterglow illumination load. In the current control device 240 shown in FIG. 12, the first switch 251 is connected between the voltage setting element 242 and the first resistor 243, between the voltage setting element 242 and the first NPN transistor 245, 242 and the afterglow lighting load 250, or between the energy storage element 220 and the current controller 240.

  Also, when a signal to turn off the light from a microcomputer or a control circuit is input to the second switch so that the afterglow illumination load emits light when the light is turned off by a remote controller or power line communication or the like, the second switch is turned on by the microcomputer or the control circuit. When the main lighting circuit module 252 is turned off and the afterglow lighting load of the main lighting circuit module 100 and the power supply to the energy storage element are shut off, the disconnection control device 230 activates the afterglow lighting load by turning off the main lighting load 120 to emit light. And the energy of the energy storage element 220 is consumed. The second switch 252 is provided between the DC voltage regulator 210 and the energy storage element 220. The second switch 252 is provided between the DC voltage regulator 210 and the energy storage element 220. The second switch 252 is an element that can open and close a circuit in response to a designated signal, and has a function of a P-channel transistor, an N-channel transistor, a PNP transistor, an NPN transistor, a photocoupler (PHOTO COUPLER), a relay, or the like. If they are satisfied, they do not specify the element. When a DC power supply is taken out of the light emitting diode lamp train of the main lighting load and supplied to the DC constant voltage device 210, the supply of the DC power supply is stopped when the main lighting load 120 is turned off. In this case, the second switch 252 is used. Design is not required.

  Further, when the light is turned off by the remote controller or the power line communication or the like, other execution states are shown as follows. A third switch (not shown) can be provided between the main lighting drive 110 and the main lighting load 120 or within the main lighting drive 110. The third switch is used to cut off or establish power supply to the main lighting load 120. The microcomputer receives the off signal, turns off the third switch, and turns off the main lighting load 120. At this time, without providing the second switch 252, the microcomputer directly controls the disconnection control device 230 to activate the afterglow illumination load 250 to emit light. The afterglow lighting time can be set by the timer of the microcomputer. This control signal may be a PWM signal. The luminance of afterglow lighting can be controlled by setting the duty ratio, and the afterglow illumination load 250 can function as afterglow or nightlight depending on whether or not a microcomputer timer is set. Also, when there is a power outage, the disconnection control module 230 has a function as an emergency illuminator that forcibly activates the afterglow illumination load 250 to emit light. The above-mentioned NPN-bipolar transistor type and PNP-bipolar transistor type afterglow circuit module 200 has its disconnection control device 230, current control device 240, and afterglow lighting load 250 interchangeable. The current control device 240, the afterglow illumination load 250, and the disconnect control device 230 in FIGS. 9 and 9 are interchangeable.

  Although not shown, a metal oxide semiconductor field effect transistor (MOSFET) may be employed in place of the NPN transistor 234 in the afterglow circuit module 200.

  Since the operating voltage of the afterglow lighting load 250 and the operating voltage of the main lighting load 120 employed in the present invention are both independent, the operating voltage can be designed based on the energy storage element 220 which is easily available. As a result, the selectivity of the energy storage element 220 is increased. When the afterglow lighting load 250 is adopted as the afterglow light source, the rated output of the afterglow lighting load 250 is smaller than that of the main lighting load 120, and the main lighting load 120 and the afterglow lighting load 250 have current feedback resistors respectively. Provided, the complexity of the afterglow circuit can be simplified with a simple circuit.

  When a capacitor or a supercapacitor is adopted as the energy storage element 220, the DC constant voltage circuit device 210 may be a series connection constant voltage circuit, a parallel connection constant voltage circuit, a switching regulator, or a three-terminal regulator 216. it can. However, when a battery is adopted as the energy storage element 220, the DC constant voltage circuit device 210 is preferably a battery charging circuit.

  Please refer to FIG. 13 which is a configuration block diagram of the light emitting diode lamp of the third preferred embodiment presented in the present invention. The afterglow circuit module shown in FIG. 13 is a P-channel field-effect transistor type afterglow circuit module 200, and the elements constituting this afterglow circuit module 200 are similarly a DC constant voltage device 210, an energy storage element 220, It includes a disconnect control device 230, a current control device 240, and an afterglow lighting load 250, but differs from the PNP-bipolar transistor type afterglow circuit module in the following way: the current control of the third preferred embodiment The device 240 employs a first P-channel transistor 246, does not employ the first PNP transistor 241 of the first preferred embodiment, and the source of the first P-channel transistor 246 is the first PNP transistor 246. The drain of the first P-channel transistor 246 corresponds to the emitter of the transistor 241, , The gate of the first P-channel transistor 246 corresponds to the base of the first PNP transistor 241, and the positive terminal of the afterglow illumination load 250 is connected to the drain of the first P-channel transistor 246. Connect. The other circuit connections and operation modes are the same as those of the first preferred embodiment, and needless detailed description will not be repeated here.

  FIG. 14 is a schematic diagram showing another embodiment of the afterglow circuit module presented in the third preferred embodiment. As can be seen from FIG. 14, a first switch 251 that can be turned on and off arbitrarily to respond to needs that do not require an afterglow lighting load, and a second switch 251 that emits light when the afterglow lighting load is turned off by a remote controller or the like. In this embodiment, a switch 252 is added.

  Please refer to FIG. 15 which is a structural block diagram of the light emitting diode lamp of the fourth preferred embodiment presented in the present invention. The afterglow circuit module shown in FIG. 15 is an N-channel field-effect transistor type afterglow circuit module 200, and the elements constituting this afterglow circuit module 200 are similarly a DC constant voltage device 210, an energy storage element 220. , The disconnection control device 230, the current control device 240, and the afterglow lighting load 250, which are different from the NPN-bipolar transistor type afterglow circuit module as follows: the current of the fourth preferred embodiment The control device 240 employs the first N-channel transistor 247, does not employ the first NPN transistor 245 of the second preferred embodiment, and the source of the first N-channel transistor 247 is the first N-channel transistor 247. The drain of the first N-channel transistor 247 corresponds to the emitter of the NPN transistor 245, 1 corresponds to the collector of the NPN transistor 245, the gate of the first N-channel transistor 247 corresponds to the base of the first NPN transistor 245, and the negative electrode of the afterglow illumination load 250 is the drain of the first N-channel transistor 247. Connected to. Other circuit connections and operation modes are the same as those of the second preferred embodiment, and needless detailed description will not be repeated here.

  FIG. 16 is a schematic diagram showing another embodiment of the afterglow circuit module presented in the fourth preferred embodiment. As can be seen from FIG. 16, a first switch 251 that can be turned on and off arbitrarily in order to respond to a need that does not require an afterglow illumination load, and a second switch 251 so that the afterglow illumination load emits light when turned off by a remote controller or the like. In this embodiment, a switch 252 is added.

  FIG. 17 is a schematic view schematically showing a light emitting diode lamp according to a fifth preferred embodiment of the present invention.

  The feature of this embodiment lies in control for changing the beam and luminance of the afterglow illumination load. It is characterized in that the afterglow lighting load is activated when the main lighting load is turned off due to a power failure or power cut. Since the interior of the room is not completely dark due to the lighting of the afterglow lighting load, the above-described embodiment, in which the user can recognize the surrounding situation and secure his / her own safety, is further provided in the afterglow circuit module 200 with the afterglow lighting load control unit 270. Was added. An afterglow lighting load control unit 270 is connected to the afterglow lighting load power supply 260 and the afterglow lighting load 250. Although not shown, the afterglow illumination load power supply 260 may include the DC low-voltage device of each of the above embodiments, an energy element, a disconnection control device, and the like. The afterglow lighting load 250 can match the current control device of each of the above embodiments. The afterglow illumination load control unit 270 controls the beam and brightness of the afterglow illumination load 250. That is, for example, within a short period after the main lighting load 120 is turned off, the afterglow lighting load 250 is caused to emit light with a higher luminance than in the afterglow normal lighting, and gradually becomes the brightness in the afterglow normal lighting. Can be FIG. 18 shows a luminance change pattern of the afterglow illumination load 250. The luminance of the LED lamp is kept constant during the operation period of the main lighting load, and is gradually reduced during the operation time of the afterglow lighting load.

  After switching from the lighting of the main lighting load 120 to the lighting of the afterglow lighting load, there is a period of time in which the eyes already suitable for the brightness of the main lighting load 120 are suitable for the brightness of the afterglow lighting load 250 which is somewhat dark. In order to extremely reduce the time required for the adaptation, the luminance control of the afterglow illumination load 250 is performed. It shines in a bright state immediately after the afterglow illumination load 250 is turned on. Then, the luminance is continuously changed until the luminance at the time of the afterglow normal lighting. This may allow the user to adapt to the brightness of the afterglow illumination load. The afterglow illumination load control unit 270 may have a configuration including a timer circuit, a current measurement circuit, and the like. For example, the current measurement circuit measures the feedback current of the constant current circuit (that is, the current control device) and controls the luminance of the afterglow illumination load, thereby maintaining a bright state within a certain period of time. Thereafter, the brightness of the afterglow illumination load is reduced in a linear or other manner.

  The pattern of the control of the luminance and the change of the luminance are not limited to those shown in FIG. In some cases, the state may be changed from a bright state to a dark state, or from a bright state to a dark state, and further to a bright state.

  In addition, a blinking operation or the like may be performed in order to notify the user of the end of the afterglow lighting load soon or the elapsed time of light emission of the afterglow lighting load.

  In addition to controlling according to the predetermined luminance change pattern described above, the embodiment shown in FIG. 17 can also be used for controlling the current flowing through the afterglow illumination load to an arbitrary value. Alternatively, the luminance of the afterglow illumination load can be selected by selecting the PWM duty ratio. Naturally, as the flowing current increases, the luminance of the afterglow illumination load increases, but the light emission time of the afterglow illumination load decreases. Conversely, when the flowing current is reduced, the luminance of the afterglow lighting load decreases, but the light emission time of the afterglow lighting load can be extended. That is, a circuit configuration is formed in which the user can select the luminance of the afterglow lighting load and the light emission period of the afterglow lighting load.

  FIG. 19 is a schematic diagram schematically showing the light emitting diode lamp of the sixth preferred embodiment presented in the present invention. The differences from the embodiment shown in FIG. 17 are as follows: the afterglow lighting load of the embodiment shown in FIG. 19 is a first sub-afterglow lighting load 250A and a second sub-afterglow lighting load 250B. The afterglow illumination load power supply 260 is connected to the first sub-persistence illumination load 250A and the second sub-persistence illumination load 250B via the load switching circuit 280. The light illumination load 250A and the second sub-persistence illumination load 250B are operated alternately. The afterglow illumination load control unit 270 including a timer circuit and a current measurement circuit is connected to the afterglow illumination load power supply 260, the load switching circuit 280, and the first sub-afterglow illumination load 250A. The first sub-persistence illumination load 250A and the second sub-persistence illumination load 250B can be configured to be illumination loads that emit different colored lights. For example, the first sub-persistence lighting load 250A is configured to be a lighting load that emits green light, and the second sub-persistent lighting load 250B is configured to be a lighting load that emits blue light. However, the present invention is not limited to this. The first sub-persistence illumination load 250A and the second sub-persistence illumination load 250B may be configured to be illumination loads that emit the same color light.

  The feature of the present embodiment lies in the control of the color change of the afterglow illumination load. From the viewpoint of visibility, immediately after the main illumination load is turned off and switched to the afterglow illumination load, green light having a wavelength of about 500 nm is emitted. Further, it is possible to change the light emission color so as to notify the user that the light emission time of the afterglow illumination load will soon end, or to set a color that the user likes. For example, the current measuring circuit measures the feedback current of the constant current circuit, emits green light for a fixed time, and then performs control to change the emission color of the afterglow illumination load to blue light or the like.

  Although the embodiment shown in FIG. 19 is an example of two outputs, three outputs of RGB or three or more outputs may be used. The control may be such that the color temperature is gradually changed by an LED which is an element having RGB.

  Regarding the emission color change pattern, a configuration may be adopted in which colors such as green-blue-green-blue are sequentially changed in a short time.

  Further, a circuit configuration for allowing the user to arbitrarily set the color temperature may be provided.

  FIG. 20 is a schematic view showing the light emitting diode lamp of the seventh preferred embodiment presented in the present invention.

  The difference from the embodiment shown in FIG. 17 is as follows: In the embodiment shown in FIG. 20, the afterglow illumination load control unit 270 includes a current measurement circuit, a timer circuit, a PWM control circuit 271 and the like. In the case of the embodiment shown in FIG. 17, by turning on / off the afterglow lighting load, the afterglow lighting load blinks. In the case of the embodiment shown in FIG. 19, the afterglow lighting load 1 and the afterglow lighting load 2 can be operated alternately via the switching circuit, so that the afterglow lighting load blinks.

  The embodiment shown in FIG. 20 is characterized in that the afterglow lighting load is made to blink at an arbitrary frequency or an arbitrary duty ratio via the PWM control circuit 271, thereby extending the total light emission time of the afterglow lighting load. I have. Blinking the afterglow lighting load at a frequency of about 100 Hz (or more or less than 100 Hz) at which development is not found by the human eye flickers, the brightness and the luminance of the afterglow lighting load are lower than the conventional DC lighting. Light emission time can be improved.

  The present invention is not limited to the above embodiments. By enlightenment of the present invention, a person having ordinary knowledge in the technical field to which the present invention pertains can create a circuit configuration using the circuits of the plurality of embodiments or a circuit configuration combining different functions, and one or more It should be understood that some or all of the features of one embodiment may be combined with some or all of the features of other embodiments.

What has been described above is merely preferred embodiments of the present invention and is not used to limit the scope of the claims filed by the present invention; at the same time, the above description should be understood by those skilled in the art. Is to be understood and enabled, and equivalent changes or modifications made without departing from the essence disclosed by the invention should be included in the following claims.
[Items of Invention]
[Item 1]
A main lighting circuit module (100) including a main lighting drive (110) and a main lighting load (120), wherein the main lighting drive (110) is used to drive the main lighting load (120) to emit light. When,
A DC constant voltage circuit device (210) that is electrically connected to the main lighting circuit module (100) and receives a DC partial voltage provided by the main lighting circuit module (100); An energy storage element (220) electrically connected, a current controller (240) electrically connected to the energy storage element (220), and an afterglow that emits light when driven by the current controller (240) An afterglow circuit module (200) including a lighting load (250);
A light-emitting diode lamp including.
[Item 2]
The current control device (240) includes a first NPN transistor (245), a negative electrode of the afterglow illumination load (250) is connected to a collector of the first NPN transistor (245), and the current control device (240) 240) The light-emitting diode lamp according to item 1, further including a voltage setting element (242) connected to the first NPN transistor (245).
[Item 3]
The current control device (240) includes a first N-channel transistor (247), the negative terminal of the afterglow illumination load (250) is connected to the drain of the first N-channel transistor (247), The light emitting diode lamp according to item 1, wherein (240) further includes a voltage setting element (242) connected to the first N-channel transistor (247).
[Item 4]
The light emitting diode lamp according to item 2, wherein the voltage setting element (242) is selected from the group consisting of a combination of a second NPN transistor, a first diode, and a first zener diode.
[Item 5]
The light emitting diode lamp according to item 3, wherein the voltage setting element (242) is selected from the group consisting of a combination of a second NPN transistor, a first diode, and a first zener diode.
[Item 6]
The current control device (240) includes a first PNP transistor (241), a positive electrode of the afterglow lighting load (250) is connected to a collector of the first PNP transistor (241), and the current control device (240) 240) The light-emitting diode lamp according to item 1, further comprising a voltage setting element (242) connected to the first PNP transistor (241).
[Item 7]
The current control device (240) includes a first P-channel transistor (246), the positive terminal of the afterglow illumination load (250) is connected to the drain of the first P-channel transistor (246), The light emitting diode lamp of claim 1, wherein the device (240) further comprises a voltage setting element (242) connected to the first P-channel transistor (246).
[Item 8]
7. The light-emitting diode lamp according to item 6, wherein the voltage setting element (242) is selected from the group consisting of a combination of a second PNP transistor, a first diode, and a first zener diode.
[Item 9]
Item 8. The light-emitting diode lamp according to item 7, wherein the voltage setting element (242) is selected from the group consisting of a combination of a second PNP transistor, a first diode, and a first zener diode.
[Item 10]
The DC constant voltage circuit device (210) is a series connection constant voltage circuit, and the series connection constant voltage circuit includes a first NPN transistor (211), a fifth resistor (212), and a Item 3. The light-emitting diode lamp according to item 1, including a third Zener diode (215), wherein a negative electrode of the third Zener diode (215) is connected to a base of the first NPN transistor (211).
[Item 11]
The DC constant voltage circuit device (210) is a parallel connection type constant voltage circuit, the DC constant voltage circuit device (210) includes a fifth resistor (212) and a third zener diode (215), The light-emitting diode lamp according to item 1, wherein a negative electrode of the third Zener diode (215) is connected to the fifth resistor (212).
[Item 12]
The light-emitting diode lamp according to item 1, wherein the DC constant voltage circuit device (210) is a three-terminal regulator (216).
[Item 13]
The light emitting diode lamp according to item 1, wherein the DC constant voltage circuit device (210) is a switching regulator.
[Item 14]
The light-emitting diode lamp according to item 1, wherein the DC constant voltage circuit device (210) is a battery charging circuit.
[Item 15]
The light-emitting diode lamp according to item 1, wherein a rated output of the afterglow lighting load (250) is lower than a rated output of the main lighting load (120).
[Item 16]
The light-emitting diode lamp according to item 1, wherein an operating voltage of the afterglow lighting load (250) is lower than an operating voltage of the main lighting load (120).
[Item 17]
2. The light emitting diode lamp according to item 1, wherein the main lighting load includes a plurality of light emitting diodes, and a part or all of the main lighting loads are used as afterglow lighting loads.
[Item 18]
The afterglow circuit module (200) is further provided in the current control device (240) and used to interrupt or establish a power supply path from the energy storage element (220) to the afterglow lighting load (250). The light-emitting diode lamp according to item 1, including a first switch (251) to be operated.
[Item 19]
The afterglow circuit module (200) is further provided between the DC constant voltage circuit device (210) and the energy storage element (220), and is provided from the DC constant voltage circuit device (210) to the energy storage element (220). 2) and a second switch (252) used to interrupt or establish a power supply path to the afterglow lighting load (250).
[Item 20]
Item 20. The light-emitting diode lamp according to item 19, wherein the second switch (252) is triggered and operated by a remote controller or a microcomputer.
[Item 21]
The main lighting circuit module (100) is further provided in the main lighting drive (110) or between the main lighting drive (110) and the main lighting load (120) and the main lighting load (120). Item 20. The light-emitting diode lamp of item 19, wherein the light-emitting diode lamp is used to shut off or establish power supply to the device, and includes a third switch that is triggered and activated by a remote control or a microcomputer.
[Item 22]
The afterglow circuit module (200) is further configured such that when the main lighting power supply is turned on, the afterglow circuit is turned off, and when the main lighting power supply is not turned on, the afterglow circuit operates to emit the afterglow lighting load. The light-emitting diode lamp according to any one of Items 1 to 21, including the disconnection control device (230) described above.
[Item 23]
Item 23. The disconnection control device (230) according to item 22, wherein the disconnection control device (230) is selected from the group consisting of a combination of a second diode (231), a third resistor (232), and a first capacitor (233). Light emitting diode lighting.
[Item 24]
The disconnection control device (230) includes a group including a third resistor (232), a third NPN transistor (234), a fourth resistor (235), and a second Zener diode. 23. A light emitting diode lamp according to item 22, which is selected from the group consisting of:
[Item 25]
The afterglow circuit module (200) is further configured to control at least one of a current flowing through the afterglow lighting load, a luminance of light emission of the afterglow lighting load, and a light emission time of the afterglow lighting load. The light-emitting diode lamp according to any one of Items 1 to 21, which includes a light illumination load control unit (270).
[Item 26]
Item 30. The light-emitting diode lamp according to item 25, wherein the afterglow illumination load control unit (270) includes a current measurement circuit and a timer circuit.
[Item 27]
The DC constant voltage circuit device, the energy storage element, and the disconnection control device form an afterglow illumination load power supply (260), and the afterglow illumination load (250) includes a plurality of sub-afterglow illumination loads (260). 250A, 250B), the afterglow circuit module (200) includes a load switching circuit (280), and the afterglow lighting load control unit (270) includes the afterglow lighting load power supply (260) and the load. A switching circuit (280) and their sub-persistence lighting loads (250A, 250B) are connected to the afterglow illumination load power supply (260) via the load switching circuit (280). Item 30. The light-emitting diode lamp according to Item 25, wherein the sub-persistence lighting load (250A, 250B) is alternately operated by being connected to the sub-afterglow lighting load (250A, 250B).
[Item 28]
28. The light-emitting diode lamp according to item 27, wherein the sub-afterglow illumination loads (250A, 250B) have different emission colors.
[Item 29]
The light emission according to item 25, wherein the afterglow illumination load control unit (270) includes a control circuit (271) that causes the afterglow illumination load to blink at a set frequency or duty ratio via a PWM lighting type. Diode lamp.

  P: power supply, 100: main lighting circuit module, 110: main lighting drive device, 120: main lighting load, 200: afterglow circuit module, 210: DC constant voltage device, 211: first NPN transistor, 212: fifth 215: Third Zener diode, 216: Terminal regulator, 2161: Input terminal, 2162: Output terminal, 2163: Common terminal, 220: Energy storage element, 230: Disconnection control device, 231: Second diode 232: third resistor, 233 ... first capacitor, 234 ... third NPN transistor, 235 ... fourth resistor, 236 ... second Zener diode, 240 ... current control device, 241 ... first PNP transistors, 242 ... voltage setting element, 243 ... first resistor, 244 ... second resistor, 245 ... first NP Transistor, 246: First P-channel transistor, 247: First N-channel transistor, 250: Afterglow illumination load, 250A: First sub-afterglow illumination load, 250B: Second sub-afterglow illumination load, 260 ... power supply for afterglow illumination load, 270 ... afterglow illumination load control unit, 271 ... PWM control circuit, 280 ... load switching circuit 280

Claims (16)

A main lighting drive (110) and a main lighting load (120) comprising one or more light emitting diodes , the main lighting drive (110) driving the main lighting load (120) to emit light. A main lighting circuit module (100) used for:
A DC constant voltage circuit device (210) that is electrically connected to the main lighting circuit module (100) and receives a DC partial voltage provided by the main lighting circuit module (100); the energy storage device comprising any one of the capacitors and supercapacitors are electrically connected (220), a current control device (240) electrically connected to said energy storage device (220), one or more An afterglow illumination load (250), which is composed of a light emitting diode and emits light when driven by the current control device (240), the DC constant voltage circuit device (210), the energy storage element (220), and the disconnection control device (230) ), The afterglow lighting load power supply (260), and the afterglow lighting load power supply (260) and the afterglow lighting load (250). Controlling the current flowing through the afterglow lighting load (250) to control the luminance of the afterglow lighting load (250) and the light emission time of the afterglow lighting load or the afterglow lighting An afterglow lighting load control unit (270) for controlling the luminance of the load (250) and the light emission time of the afterglow lighting load, and an afterglow circuit module (200) including:
The disconnection control device (230) includes a second diode (231), a third resistor (232) having one end connected to a negative electrode of the second diode (231), and the third resistor (232). A first capacitor connected to one end of the main lighting circuit module , wherein the main lighting power supply for supplying power to the main lighting circuit module is turned on when the afterglow lighting load is turned on. Is turned off and the afterglow lighting load (250) is turned on when the main lighting power supply is not turned on, and the duty ratio of the afterglow lighting load (250) is set by setting a duty ratio of a control signal as a current or a PWM signal. It is configured to be able to control the brightness and lighting time of lighting ,
The afterglow lighting load control unit (270) includes a timer circuit and a current measurement circuit, and controls the luminance of the afterglow lighting load (250) within a predetermined period after the main lighting load (120) is turned off. The main lighting load (120) is controlled to have a first brightness that is equal to or lower than the brightness immediately before turning off, and after the predetermined period, the brightness of the afterglow lighting load (250) is changed to change the brightness of the afterglow lighting load (250). A light-emitting diode lamp, wherein the second brightness is controlled to be lower than the first brightness. A main lighting drive (110) and a main lighting load (120) comprising one or more light emitting diodes , the main lighting drive (110) driving the main lighting load (120) to emit light. A main lighting circuit module (100) used for:
A DC constant voltage circuit device (210) that is electrically connected to the main lighting circuit module (100) and receives a DC partial voltage provided by the main lighting circuit module (100); the energy storage device comprising any one of the capacitors and supercapacitors are electrically connected (220), a current control device (240) electrically connected to said energy storage device (220), one or more An afterglow illumination load (250), which is composed of a light emitting diode and emits light when driven by the current control device (240), the DC constant voltage circuit device (210), the energy storage element (220), and the disconnection control device (230) ), The afterglow lighting load power supply (260), and the afterglow lighting load power supply (260) and the afterglow lighting load (250). Controlling the current flowing through the afterglow lighting load (250) to control the luminance of the afterglow lighting load (250) and the light emission time of the afterglow lighting load or the afterglow lighting An afterglow lighting load control unit (270) for controlling the luminance of the load (250) and the light emission time of the afterglow lighting load, and an afterglow circuit module (200) including:
The disconnection control device (230) includes a third resistor (232) having one end grounded, and a third NPN transistor (234) having a base connected to the other end of the third resistor (232). A fourth resistor (235) having one end connected to the other end of the third resistor (232); and a second resistor having a positive electrode connected to the other end of the fourth resistor (235). The afterglow lighting load (250) is turned off when the main lighting power supply for supplying power to the main lighting circuit module (100) is turned on, and when the main lighting power supply is not turned on. The lighting luminance and light emission time of the afterglow lighting load (250) can be controlled by turning on the afterglow lighting load (250) and setting the duty ratio of the control signal as a current or a PWM signal. Is composed of
The afterglow lighting load control unit (270) includes a timer circuit and a current measurement circuit, and controls the luminance of the afterglow lighting load (250) within a predetermined period after the main lighting load (120) is turned off. The main lighting load (120) is controlled to have a first brightness that is equal to or lower than the brightness immediately before turning off, and after the predetermined period, the brightness of the afterglow lighting load (250) is changed to change the brightness of the afterglow lighting load (250). A light-emitting diode lamp, wherein the second brightness is controlled to be lower than the first brightness. The current control device (240) includes a first NPN transistor (245), a negative electrode of the afterglow illumination load (250) is connected to a collector of the first NPN transistor (245), and the current control device (240) The light-emitting diode lamp according to claim 1 or 2 , wherein (240) further includes a voltage setting element (242) connected to the first NPN transistor (245). The current control device (240) includes a first N-channel transistor (247), the negative terminal of the afterglow illumination load (250) is connected to the drain of the first N-channel transistor (247), 3. The light-emitting diode lamp according to claim 1, wherein (240) further includes a voltage setting element (242) connected to the first N-channel transistor (247). The light emitting diode lamp according to claim 3 , wherein the voltage setting element (242) is selected from the group consisting of a combination of a second NPN transistor, a first diode, and a first zener diode. The light emitting diode lamp according to claim 4 , wherein the voltage setting element (242) is selected from the group consisting of a combination of a second NPN transistor, a first diode, and a first zener diode. The current control device (240) includes a first PNP transistor (241), a positive electrode of the afterglow illumination load (250) is connected to a collector of the first PNP transistor (241), and the current control device (240) The light-emitting diode lamp according to claim 1 or 2 , wherein (240) further includes a voltage setting element (242) connected to the first PNP transistor (241). The current control device (240) includes a first P-channel transistor (246), a positive electrode of the afterglow illumination load (250) is connected to a drain of the first P-channel transistor (246), The light-emitting diode lamp according to claim 1 or 2 , wherein the device (240) further comprises a voltage setting element (242) connected to the first P-channel transistor (246). The light emitting diode lamp according to claim 7 , wherein the voltage setting element (242) is selected from the group consisting of a combination of a second PNP transistor, a first diode, and a first zener diode. The light emitting diode lamp according to claim 8 , wherein the voltage setting element (242) is selected from the group consisting of a combination of a second PNP transistor, a first diode, and a first zener diode. The DC constant voltage circuit device (210) is a series connection constant voltage circuit, and the series connection constant voltage circuit includes a first NPN transistor (211), a fifth resistor (212), and a includes three zener diode (215), the negative electrode of the third zener diode (215) is a light emitting diode lamp according to claim 1 or 2 is connected to the base of the first NPN transistor (211). The DC constant voltage circuit device (210) is a parallel connection type constant voltage circuit, the DC constant voltage circuit device (210) includes a fifth resistor (212) and a third zener diode (215), light emitting diode lamp according to claim 1 or 2 negative of the third zener diode (215) is connected to said fifth resistor (212). The light-emitting diode lamp according to claim 1 or 2 , wherein the DC constant voltage circuit device (210) is a three-terminal regulator (216). The afterglow lighting load (250) includes a plurality of sub afterglow lighting loads (250A, 250B), the afterglow circuit module (200) includes a load switching circuit (280), and the afterglow lighting load control unit ( 270) is connected to the afterglow lighting load power supply (260), the load switching circuit (280), and the plurality of sub-afterglow lighting loads (250A, 250B), 260) is connected to the sub-persistence lighting loads (250A, 250B) via the load switching circuit (280) to alternately operate the plurality of sub-persistence lighting loads (250A, 250B). Item 3. A light emitting diode lamp according to item 1 or 2 . The light emitting diode lamp according to claim 14 , wherein the plurality of sub-persistence lighting loads (250A, 250B) have different emission colors. 2. The afterglow illumination load control unit (270) includes a control circuit (271) configured to blink the afterglow illumination load (250) at a set frequency or duty ratio via a PWM lighting system. Or a light-emitting diode lamp according to item 2.

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