KR20120025700A

KR20120025700A - The lamp

Info

Publication number: KR20120025700A
Application number: KR1020100087751A
Authority: KR
Inventors: 박지혜
Original assignee: (주)리치맥스글로벌
Priority date: 2010-09-08
Filing date: 2010-09-08
Publication date: 2012-03-16

Abstract

PURPOSE: An anion-generation lamp equipped with a ventilation fan is provided to purify wide indoor air by rapidly and widely discharging wind which includes an anion to outside. CONSTITUTION: A socket type connector part(11) is installed on the upper side of a main body(1) of a hemi spherical shape. A converter and a second metal substrate are respectively installed in inside and bottom side of the main body. The converter is installed in a first metal substrate. A plurality of LEDs is installed in the second metal substrate. A supporting plate is installed between the first metal substrate and the second metal substrate. A anion-generation module(6) and a ventilation fan are installed to a supporting plate. An anion electrical rod is inserted in the lower side of the anion-generation module. An anion brush(52) is combined to the end of the anion electrical rod.

Description

Negative ion generating lamp with blower fan {The Lamp}

The present invention relates to an anion generating lamp equipped with a blower fan, and more particularly, by installing a blower fan inside the main body equipped with a plurality of LEDs while the anion generator module is installed, the wind generated from the blower fan As it releases quickly and widely to the outside of the body in the state of containing negative ions, it not only cleans a large area but also the air blown from the blower fan cools the LED to prevent the LED from being damaged by heat to the maximum. It relates to an anion generating lamp equipped with a fan.

In general, LED (Light Emitting Diode) operates with low power and high efficiency, and has a longer life compared to light sources such as fluorescent lamps and incandescent lamps, and because electrical energy is directly converted into light energy, low power and efficiency increase and lighting time are very long. It is short and is widely used in real life.

In addition, the anion has a negative polarity and is used to purify various pollutants such as organic substances, volatile chemicals, etc. mixed in the air. .

However, a lamp having a negative ion generating function in the related art has a problem that the negative ion generated in the lamp cannot be spread to a wide area because the negative ion generating part is formed inside the lamp, and thus the negative ion effect can be expected only around the lamp. .

That is, a lamp having a function of generating a negative ion of the related art has a problem in that an effect due to its use is insufficient as negative ions do not spread to a wide area.

Therefore, the present invention for solving the above problems can be purified wide room air by the negative ions emitted with the wind because the wind generated in the blowing fan is released quickly and widely from the inside of the main body in the state containing the negative ions In addition, the wind generated by the blowing fan quickly discharges heat generated from the LED to the outside, thereby preventing the LED from being ruptured by heat to the maximum, and the optical sensor and the storage battery inside and outside the main body, respectively. Blowing fan that can be installed and configured to prevent the power is consumed by the LED automatically flashed by the optical sensor, as well as to install and use a lamp with an anion generating module regardless of the location by the capacitor It is an object to provide a negative ion generating lamp equipped with this.

The present invention for achieving the above object,

A socket-shaped terminal portion forms a hemispherical body installed at an upper end, and a converter and a plurality of LEDs (Light Emitting Diodes) mounted on a first metal substrate are respectively radially mounted on the inside and the bottom of the main body, and a through hole is formed at the center thereof. The second metal substrate is formed and installed, and the tapered cap is formed to be concave and the center hole is formed on the bottom of the cover formed in the hemispherical shape, and the cover is installed on the lower surface of the main body,

Between the first and the second metal substrate is installed between the converter and the negative ion generating module for generating negative ions and a support plate equipped with a blower fan, the negative electrode rod is placed on the lower side of the negative ion generating module to the end of the negative electrode It is installed so as to be located inside the taper cap, by combining an anion brush at the end of the anion electrode rod, so that the anion released through the anion brush is quickly released from the inside of the body to the outside with the wind generated from the blowing fan. It features.

According to the present invention, since the wind generated in the blowing fan is quickly and widely released from the inside of the main body to the outside in the state containing negative ions, it is possible to purify the wide indoor air by the negative ions emitted with the wind, and also the blowing fan Since the wind generated from the LED emits heat generated from the LED to the outside quickly, the LED can be prevented from being ruptured by heat to the maximum, and an optical sensor and a storage battery are installed on the inside and the outside of the main body to respectively configure It is possible to prevent the power consumption by the LED automatically flashed by the sensor, as well as the effect that can be used by installing a lamp with an anion generating module installed regardless of the location of the capacitor.

1 is a perspective view of a negative ion generating lamp equipped with a blowing fan of the present invention.
Figure 2 is a cross-sectional view of the negative ion generating lamp equipped with a blowing fan of the present invention.
Figure 3 is a bottom view of the negative ion generating lamp equipped with a blowing fan of the present invention.
Figure 4 is a sectional view showing a state in which the blowing fan and the negative ion generating module of the present invention is installed.
5 is a cross-sectional view showing a state in which the converter and the LED of the present invention is installed.
Figure 6 is a front view showing a state in which the storage battery of the present invention is installed.
Figure 7 is an installation state of the negative ion generating lamp equipped with a blowing fan of the present invention.
Figure 8 is a view showing a state in which the guide protrusion projected on the tapered cap of the present invention.

Hereinafter, with reference to the accompanying Figures 1 to 8 will be described a preferred embodiment of the present invention.

According to the present invention, an anion generator is installed inside the lamp 8, and an anion generated by the anion generator is operated in a blower fan 53 installed inside the lamp 8 to be quickly and widely divided to the outside. It is intended to be released.

The lamp 8 is coupled to the hemispherical body (1) formed with a coupling cap 12, as shown in Figure 1, a plurality of LED (Light Emitting Diode: 3) is coupled to the body 1, the body (1) It consists of a cover 6 formed in a hemispherical shape at the bottom.

At this time, by installing the storage battery 13 on the outer circumferential surface of the main body 1 as shown in Figure 6, by using the electricity charged in the storage battery 13 can be installed and used regardless of the location of the lamp (8) will be.

The socket-type terminal part 11 is installed on the upper end of the main body 1 of the lamp 8 formed as described above, and the first metal substrate 22 is connected to the converter 2 having the heater sink 21 coupled to the upper surface thereof as shown in FIG. 2. The first metal substrate 22 on which the converter 2 is mounted is mounted on the upper surface of the main body 1.

The light sensor 4 is mounted on the upper surface of the first metal substrate 22 on which the converter 2 is mounted, thereby adjusting the illuminance of the LED 3 according to the light intensity detected by the light sensor 4. In addition to being adjustable, the LED 3 lights up automatically.

In this case, the light sensor 4 detects the light flowing through the detection hole 41 by penetrating the detection hole 41 on the outer circumferential surface of the main body 1 to correspond to the light sensor 4. .

Further, a plurality of LEDs 3 are radially mounted on one side of the second metal substrate 31 connected to the converter 2 by an electric wire as shown in FIG. 5B, and the LEDs 3 are mounted. The second metal substrate 31 is installed on the lower surface of the main body 1, and the cover 6 formed in a hemispherical shape is installed on the lower surface of the main body 1 on which the LED 3 is mounted. The overall shape of 8) is formed in a spherical shape, the cover 6 installed on the lower end of the main body 1 can prevent the LED 3 from being easily damaged by external shocks, as well as the LED Allow the lights in (3) to spread out in all directions.

The negative ion generating module 8 and the blowing fan 53 which generate negative ions as shown in FIGS. 5A and 5B are installed inside the main body 1 of the lamp 8 in which the LEDs 3 are installed as described above. Since the negative ions generated in the negative ion generating module 8 are discharged to the outside through the central hole 62 of the tapered cap 61 together with the wind generated in the blower fan 53, the large area is purified. Of course, the heat generated by the LED 3 can also be quickly released to the outside to prevent the LED 3 from being damaged by heat to the maximum.

A plurality of second flow holes between the first and second metal substrates 22 and 31 to install the negative ion generating module 8 and the blowing fan 53 inside the main body 1 as shown in FIG. 2. While the 55 is penetrated, a disk-shaped support plate 54 connected to the converter 2 is installed and configured in the main body 1, and a blowing fan 53 is provided at the lower center, which is one side of the support plate 54. The negative ion generating module 8 is mounted on the support plate 54 so as to be spaced apart from the blowing fan 53.

That is, in the state in which the blower fan 53 and the negative ion generating module 8 are installed in the center of the support plate 54 formed in a disk shape as shown in FIG. 4, the support plate 54 is formed on the first and second metal substrates 22. By installing between the 31 and by the wind generated in the blowing fan 53, as shown in Figure 2 the negative ion can be quickly released from the inside of the lamp (8) to the outside and at the same time widely spread LED ( It is to dissipate heat generated in 3) quickly.

And to install an anion electrode rod 51 on the lower side of the anion generating module 8, the anion electrode rod 51 is the inside of the tapered cap 61 is coupled to the lower center of the cover 6 as shown in FIG. The negative electrode brush 52 for radiating negative ions to the outside of the negative electrode electrode 51 is disposed at the inner side of the tapered cap 61.

At this time, the tapered cap 61 is formed to be inclined upward so as to become narrower toward the upper end as shown in FIG. 2, and by forming a central hole 62 at the upper end of the tapered cap 61, the negative ion brush 52 is formed. The negative ions generated to the outside through the central hole 62 to be emitted to the outside in the state contained in the wind coming out of the inside of the main body 1, thereby the negative ions are distributed only around the lamp (8) Purification can be prevented.

That is, the negative ions generated in the negative ion generating module 5 are emitted to the outside of the lamp 8 through the negative ion brush 52, in which the amount of negative ions generated through the negative ion brush 52 is the lamp 8 About 3 to 4 million are measured at a distance within 30 cm, whereas less than about 120,000 to 180,000 are measured at a distance of more than 1M, so that the negative ions generated in the negative ion generating module 5 are indoor air. It is not only possible to prevent the purification of the surroundings of the lamp 8 in a state intensively distributed only around the lamp 8 without purifying, and as a result, the burning of the lamp 8 causes the blower fan 53 This can be prevented by the wind generated from).

In addition, the light of the LED 3, such as white, red, yellow, green, etc., so that various wavelengths and colors appear, the lamp 8 can be used for home use by the LED 3 and the negative ion generating module 5. Of course, it can be used for agriculture, animal husbandry, or fisheries, etc. Therefore, it is installed in a farm for raising special crops or livestock to help the agricultural and livestock industries.

Meanwhile, as shown in FIG. 1, the induction part 630 is spirally formed to rotate the wind of the blowing fan 53 on the inner circumferential surface of the tapered cap 61 to be discharged to the outside.

By forming the induction part 63 in a spiral shape on the inner circumferential surface of the taper cap 61, the wind passing through the taper cap 61 by the induction part 63 rotates in a spiral together with the anion emitted from the negative ion brush 52. While it is released to the outside while the negative ions can be released far, wide, by the negative ions released in this way it is possible to improve the purification power of the internal air of the room.

In addition, the guide blade 64 is formed to be bent upward at the end of the guide portion 63 as shown in FIG. 8, and the outside is caused by the wind of the blowing fan 53 inside the main body 1 by the guide blade 64. Not only can the strength of the wind falling into the furnace more strong, but also by the strongly discharged wind negative ions are widely distributed around the lamp 8 can greatly improve the room purification power.

Referring to the preferred operating state and effects of the present invention configured as described above are as follows.

First, as shown in FIG. 2, the lamp 6 is formed by coupling the cover 6 to the bottom of the main body 1 including the LED 3, the negative ion generating module 5, and the blowing fan 53. By using the terminal portion 11 of the lamp 8, it is installed in a place such as the room as shown in FIG. 7, so that the power supply supplies electricity to the converter 2 installed inside the main body 1. As shown in FIG.

The converter 2 connected to the power source operates the negative ion generating module 5 and the blower fan 53 installed inside the main body 1, respectively, so that negative ions generated through the negative ion generating module 5 are enlarged in FIG. Since it is emitted to the outside of the main body 1 with the wind generated in the blower fan 53 as well as to improve the purification ability of the indoor air.

And when the wind generated in the blowing fan 53 is discharged to the outside of the lamp 8 by the induction portion 63 protruding spirally inside the tapered cap 61 as shown in FIG. Because of this, the negative ions discharged from the inside of the main body 1 to the outside together with the wind are also released while rotating, thereby being widely released inside the room, thereby improving the indoor purification ability.

In addition, the air in the upper end of the main body 1 due to the wind generated in the blowing fan 53 is the first and second flow holes 23 formed in the first metal substrate 22 and the support plate 54, respectively ( Since it is discharged to the outside of the main body 1 through 55, the internal temperature of the lamp 8 is prevented from rising to the maximum, and the heat generated by the LED 3 is also tapered by the wind of the blower fan 53. Since it is emitted to the outside through the central hole 62 of the cap 61, it is possible to prevent the LED 3 from being damaged by heat to the maximum.

On the other hand, since the LED 3 is automatically flashed by the light line 4 installed in the main body 1 as shown in FIG. 5A, power consumption can be prevented, and the main body 1 6, an optical sensor 4, an anion generating module 5, and a blowing fan 53 installed inside the main body 1 by using the power of the battery 13 coupled to the outer surface of the main body 1. Since it can be operated, there is an advantage that the lamp 8 can be installed and used anywhere.

1: body, 2, converter,
3: LED, 4: light sensor,
5; Negative ion generating module, 6: cover,
8: lamp, 11: terminal,
12: connecting cap, 13: battery,
21: heater sink, 22: heater sink,
23: first metal substrate, 31: second metal substrate,
32: through hole, 41: detection hole,
51: anion electrode, 52: anion brush,
53: blower fan, 54: support plate,
55: second flow hole, 61: taper cap,
62: central hall, 63: induction part,
64; Wings,

Claims

The socket-shaped terminal portion 11 forms a hemispherical body 1, which is installed at the upper end,
The through-hole 32 is formed in the center while the converter 2 and the plurality of LEDs (Light Emitting Diodes) 3 installed on the first metal substrate 22 and the plurality of LEDs are radially mounted on the inside and the bottom of the main body 1, respectively. Install and configure the second metal substrate 31,
The tapered cap 61 is formed to be concave to be tapered, and the tapered cap 61 having the central hole 62 is coupled to the lower end of the cover 6 formed in a hemispherical shape, and the cover 6 is installed on the lower surface of the main body 1. ,
Between the first and second metal substrates 22 and 31, a negative ion generating module 5 and a support plate 54 mounted with a blower fan 53 are installed, which are connected to the converter 2 and generate negative ions. ,
The negative electrode rod 51 is placed in the lower side of the negative ion generating module 5 so that the end of the negative electrode rod 51 is positioned inside the tapered cap 61.
The anion brush 52 is coupled to the end of the anion electrode rod 51 so that the anion released through the anion brush 52 is moved from the inside of the body 1 to the outside together with the wind generated from the blowing fan 53. Anion generating lamp equipped with a blowing fan, characterized in that to be quickly released.

According to claim 1, The outer periphery of the main body 1 is formed through the plurality of inlet holes 14 as the blowing fan 53 rotates the outside air of the main body 1 through the inlet hole 14 Anion generating lamp equipped with a blower fan, which is introduced into the inside, and the introduced air is discharged to the outside through the central hole 62 of the tapered cap 61.

2. The sensing hole 41 of claim 1, wherein an optical sensor 4 for detecting light is installed inside the main body 1, and a sensing hole 41 is provided on an outer circumferential surface of the main body 1 so that light is introduced into the optical sensor 4. The negative ion generating lamp equipped with a blowing fan, characterized in that the through-forming, the illumination intensity is configured to be automatically adjusted according to the amount of light detected by the optical sensor (4).

The negative ion generating lamp with a blower fan according to claim 1, characterized in that a storage battery (13) is installed and configured to supply AC power to the outer circumferential surface of the main body (1) to be charged and supplied as an LED (3) driving power. .

The induction part of claim 1, wherein the wind of the blower fan 53 is spirally rotated on the inner circumferential surface of the tapered cap 61 to discharge to the outside to allow the negative ions to be mixed and discharged away from the wind. 63) Anion generating lamp equipped with a blowing fan, characterized in that the spirally projected.

The method of claim 5, wherein the guide blade 64 is further formed at the end of the guide portion 63 to be bent upward, so that the strength of the wind to the loop by the guide blade 64 is stronger to further anion Anion generating lamp equipped with a blowing fan, characterized in that configured to emit.