JP3120264U - Wind power light-emitting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To directly convert wind power generated into light emitting power efficiently without waste, and from the diode charged without stopping light emission even if the wind power weakens and falls into power shortage, Provision of a device that can continue to emit light while being obtained.
SOLUTION: It is not a means of generating wind power with one power generation means and dividing the power, but as if there are two power generators, one single-axis power generator generates two systems of power generation, Each light emitting circuit can be controlled and made to emit light without depending on each other system, and can be charged at the same time, and the light emitting diode can continue to emit light even when there is no wind.
[Selection] Figure 1

Description

  The present invention apparently has a large capacity portion of a capacitor by combining a charging light emitting device comprising a power generating device having two induction coils that generate power independently in a single generator and a direct light emitting device. The present invention relates to a wind-charged light-emitting device that continues to emit light even when there is no wind generated by the difference between the small-capacity part and the small-capacity part.

  Light emitting diodes (LEDs) have become widespread in recent years and are actually applied to various devices. In particular, it is an ideal product for energy-saving measures. It is used for traffic lights, top lights, illuminators, etc., and has grown in three primary colors, so it can be used for video. Naturally, it is colorful and energy-saving, so it is indispensable for electric decoration, and is used as a variety of power generation systems such as batteries, heat, light, hydropower, and wind power.

However, there are few conventional ultra-small light emitting devices using light emitting diodes that make effective use of received power. .
Even if it is an energy-saving light-emitting device, it will not emit light when the electromotive device stops, and a dedicated power generator is required to charge it. However, there is an urgent need to provide a device that continues to emit light, and the present invention aims to solve such conventional problems.

In the first aspect of the present invention, the coil is wound in a direction facing the central axis of the permanent magnet core for power generation 3A joined to the generator rotating shaft 2 for transmitting the stress of the fan 1 in parallel. The power generator 3 including the system induction electromotive coil 4 and the second system induction electromotive coil 11 constitutes the power generation means 10.
A rectifier diode 5 is provided in the first system power generation wiring path 4A for transmitting the power generated in the first system induction electromotive coil 4 of the power generator 3, the (−) side of the rectifier diode 5 is connected to the ground G, and the other The (+) side is connected to the DC light emitting wiring path 6D, and a small-capacitance capacitor 6 is provided.
Furthermore, the light emitting diode 7, the light emitting diode 8, and the light emitting diode 9 are arranged in parallel from the (+) side, respectively, and the first system light emitting means 40 that connects each (−) side to the ground G is configured.
In the other second system induction electromotive coil 11 of the power generator 3, a rectifier diode 12 is provided in the second system power generation wiring path 11A for transmitting the generated power, and the (−) side of the rectifier diode 12 is connected to the ground G. The other (+) side is connected to the DC light emitting wiring path 13D, the large-capacitance capacitor 13, the light emitting diode 14, and the light emitting diode 15 are connected in parallel from the (+) side, and each (−) side is grounded. The second system light emitting means 110 is configured by being connected to G, and the generated power is in a state where the generated electric power can be efficiently charged and emitted without waste.

The present invention according to claim 2 is characterized in that in claim 1,
The power generator 3 of the power generation means 10 includes a first system induction electromotive coil 4 that is independently provided in at least two or more necessary numbers with a permanent magnet core 3A for power generation rotating around one axis and generating electricity. It is a wind-charging light-emitting device that is arranged to face the second system induction electromotive coil 11 and includes the electromotive coil, and constitutes the first system power generation wiring path 4A and the second system power generation wiring path 11A.

The present invention as defined in claim 3 is characterized in that, in claim 1,
The rectifying diode 5 and the DC light emitting wiring path 6D constituting the first system light emitting means 40 control the light emitting diode 7, the light emitting diode 8, and the light emitting diode 9 with a small capacity capacitor 6 for the amount of voltage and current necessary for direct light emission. The rectifying diode 12 and the DC light emitting wiring path 13D constituting the second system light emitting means 110 are provided with a capacitor 13 having a capacity much larger than that of the capacitor 6 of the first system light emitting means 40. It is a wind charging light emitting device.

  The wind-powered light-emitting device of the present invention is apparently a single generator having a plurality of power generation coils. In fact, the power generation of two or more systems is the same as when a plurality of power generators are operated simultaneously. In order to cover the entire light emission system with a power generator that can be used in the electric device, a structure in which power generation loss and power distribution failure due to the plurality of power generators that are generally performed is unlikely to occur. Therefore, the structure is simplified and the cost is reduced, and the best design as an LED light emitter is facilitated.

Further, if an appropriate capacitor is provided for direct current light emission, the LED emits light without an extra resistor, and there is no fear of breakdown withstand voltage due to overpower feeding.
On the one hand, light is emitted directly by wind power as described above, and in the other circuit, charging is performed during light emission simply by increasing the capacitance of the capacitor, and power continues to be supplied even if wind power is lost. It becomes possible to continue to emit light.

Next, the best mode for carrying out the present invention will be described with reference to the drawings.
FIG. 1 is a wiring system diagram of a wind-powered light emitting device according to the present invention. FIG. 2 is a block diagram illustrating the wiring system of FIG. In the present embodiment, power receiving / feeding is described as an example of a wind-powered light-emitting device, but the present invention can be similarly applied to light-emitting devices other than wind power.
Since FIG. 1 and FIG. 2 are the same wiring diagrams, FIG. 1 and FIG.

  The power generation means 10 has a power generation device in which a generator rotating shaft 2 that rotates directly on the same axis under the stress of the fan 1 rotates a power generation permanent magnet core 3 </ b> A at the center of the power generator 3 to generate electricity. The pair of first system induction electromotive coils 4 and the second system induction electromotive coils 11 opposed to each other in parallel with the power generation permanent magnet core 3A of the power generator 3 are independently induced to generate two systems. Apparently, one generator 3 can be used to generate power simultaneously.

The electric power generated from the first system induction electromotive coil 4 is supplied to the rectifier diode 5 provided in the middle through the first system power generation wiring path 4A, converted into a direct current, and distributed to the DC light emitting wiring path 6D, and the rectification diode. 5, the capacitor 6, the light-emitting diode 7, the light-emitting diode 8, and the light-emitting diode 9 are connected in parallel from the (+) side, respectively, from the (+) side, and the other is grounded to the ground G to connect the first system light emitting means 40. It is composed.
At this time, the capacitor 6 is a capacitor having a capacity sufficient for the light-emitting diode 7, the light-emitting diode 8, and the light-emitting diode 9 to directly generate power from the power generator 3.

  Further, the power generated by the second system induction electromotive coil 11 of the power generator 3 on the second system light emitting means 110 side is received by the second system power generation wiring path 11A and rectified to the terminal of the second system power generation wiring path 11A. A diode 12 is provided to convert it into a direct current, and the power supplied from the (+) side is distributed to the DC light emitting wiring path 13D, and a capacitor 13 is provided in the DC light emitting wiring path 13D. The path 13D is characterized in that a capacitor capable of charging a larger capacity than the capacitor 6 of the first system light emitting means 40 is provided, and the light emitting diode 14 and the light emitting diode 15 are arranged from the (+) side behind the configuration. The (−) side is grounded to the ground G.

FIG. 3 is an explanatory diagram of the generator 3 that performs electromotive force and dielectric of FIGS. 1 and 2, and is a diagram in which two generators are incorporated into one.
The fan 1 is joined to the generator rotating shaft 2 and transmits the stress to the power generating permanent magnet core 3A. The rotating permanent magnet core 3A for power generation includes a first system induction electromotive coil 4 and a second system induction electromotive coil 11 facing each other in parallel with the rotation shaft, and each coil is wound independently. Since it is non-contact, it is configured so that two systems of power generation can be performed simultaneously in one generator.

FIG. 4 is a flowchart showing a procedure of a method of performing wind power generation light emission by the wind charging light emitting device of FIG. 1, FIG. 2, and FIG. 3, and a light emitting diode of the wind charging light emitting device with reference to FIG. A method of emitting light will be described.
First, step S1 obtains stress from the fan 1 of the power generation means 10, and when the generator rotating shaft 2 rotates the power generating permanent magnet core 3A, the first system induction coil 4 opposed to the rotating shaft in parallel. And the second system induction electromotive coil 11 constitute a single-axis two-pair winding generator that constitutes the power generation means 10 and supplies power to the wiring path for two-system light emission.

  Then, AC power is converted into DC via the rectifier diode 5 in step S3-b through the first system power generation wiring path 4A in step S2-b. In step S4-b, the DC current is controlled stably by the small-capacity charging capacitor in step S5-b via the DC light-emitting wiring path 6D, and in step S6-b, the light-emitting diode 7, the light-emitting diode 8, Since power is also distributed to the diode 9, in step S6-b, the diode 7, the light emitting diode 8, and the light emitting diode 9 directly emit the power distributed in step S1.

On the other hand, the current distributed from step S1 to step S2-a is rectified in step S3-a through the second system power generation wiring path 11A from the second system induction coil 11 as an alternating current in step S2-a. The power is distributed to the diode 12 and converted to a direct current. In step S4-a, a (+) current is distributed to the direct current light emission wiring line 13D, and the large capacity capacitor 13 is charged in step S5-a. In step S6-a, the electric power is supplied from the (+) side to the light emitting diode 14 and the light emitting diode 15 arranged in parallel behind the DC light emitting wiring path 13D to emit light.
When the generator 3 in step S1 cannot obtain wind power, the light emitting diodes in the step Sb system are turned off, but the light emitting diodes in the step Sa system are fed from the large-capacitance capacitor 13 and continuously emit light. Make.

  The wiring system figure of the wind-charging light-emitting device of this invention.   The block diagram which divided the wiring system of FIG. 1 into two systems.   Explanatory drawing of the generator 3 of the wind-charging light-emitting device of this invention.   The flowchart which shows the procedure of the method of performing wind power generation light emission by the wind charging light-emitting device of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Fan 2 Generator rotating shaft 3 Generator 3A Permanent magnet core for power generation 4 1st system induction electromotive coil 4A 1st system power generation wiring 5 Rectifier diode 6 Capacitor 6D DC light emission wiring 7 Light emitting diode 8 Light emitting diode 9 Light emitting diode

DESCRIPTION OF SYMBOLS 10 Power generation means 11 2nd system induction coil 11A 2nd system power generation wiring path 12 Rectifier diode 13 Capacitor 13D DC light emission wiring path 14 Light emitting diode 15 Light emitting diode 40 1st system light emission means 110 2nd system light emission means G Ground

Claims (3)

A first system induction electromotive coil 4 and a second system wound in a direction opposite to the central axis of the power generation permanent magnet core 3A joined to the generator rotating shaft 2 for transmitting the stress of the fan 1 A power generator 3 having an induction electromotive coil 11 constitutes a power generation means 10,
A rectifier diode 5 is provided in the first system power generation wiring path 4A for transmitting the power generated in the first system induction electromotive coil 4 of the power generator 3, the (−) side of the rectifier diode 5 is connected to the ground G, and the other The (+) side is connected to the DC light emitting wiring path 6D, and a small-capacitance capacitor 6 is provided.
Furthermore, the light emitting diode 7, the light emitting diode 8, and the light emitting diode 9 are arranged in parallel from the (+) side, respectively, and the first system light emitting means 40 that connects each (−) side to the ground G is configured.
In the other second system induction electromotive coil 11 of the power generator 3, a rectifier diode 12 is provided in the second system power generation wiring path 11A for transmitting the generated power, and the (−) side of the rectifier diode 12 is connected to the ground G. The other (+) side is connected to the DC light emitting wiring path 13D, the large-capacitance capacitor 13, the light emitting diode 14, and the light emitting diode 15 are connected in parallel from the (+) side, and each (−) side is grounded. A wind-charging light-emitting device characterized in that the second system light-emitting means 110 is configured by being connected to G so that the generated power can be efficiently activated and emitted without waste. In claim 1,
The power generator 3 of the power generation means 10 includes a first system induction electromotive coil 4 that is independently provided in at least two or more necessary numbers with a permanent magnet core 3A for power generation rotating around one axis and generating electricity. Wind power charging and light-emitting device that is provided to face the second system induction electromotive coil 11 and includes the electromotive coil, and constitutes the first system power generation wiring path 4A and the second system power generation wiring path 11A. In claim 1,
The rectifying diode 5 and the DC light emitting wiring path 6D constituting the first system light emitting means 40 control the light emitting diode 7, the light emitting diode 8, and the light emitting diode 9 with a small capacity capacitor 6 for the amount of voltage and current necessary for direct light emission. The rectifying diode 12 and the DC light emitting wiring path 13D constituting the second system light emitting means 110 are provided with a capacitor 13 having a capacity much larger than that of the capacitor 6 of the first system light emitting means 40. Wind-charging light emitting device.

Images