KR20150116621A - Self-generation using thermography LED Flashlight - Google Patents

Abstract

A self-powered LED flashlight is provided. The self-powered LED flashlight comprises: a body (110) having an insertion hole (111) formed in the longitudinal direction therein; multiple thermoelectric power generation devices (120) arranged around the inner surface of the insertion hole; a cooling body (130) inserted into the center of the thermoelectric power generation devices and having a cooling hole (131) therein to circulate air in the longitudinal direction; a rechargeable battery (140) mounted in the cooling hole (131) and connected to the thermoelectric power generation devices (120); a top body (150) installed on the upper portion of the body (110); an LED lamp (160) mounted in the top body (150) and connected to the thermoelectric power generation devices (120) to receive power by the operation of a switch (112) formed on one side of the body (110); a lens (170) installed on the upper portion of the top body (150); and a lid (180) installed on the bottom of the body (110). The thermoelectric power generation devices can be operated by a temperature difference between air temperature and the hand of a user gripping the flashlight. The flashlight according to the present invention does not necessarily require any recharging processes or batteries, thereby improving efficiency and convenience.

Description

{Self-generation using thermography LED flashlight}

The present invention relates to a self-generated LED flashlight using body heat, and more particularly, to a self-generated LED flasher using a thermally-driven self-generated LED which emits an LED lamp by self-generating a thermoelectric power generator by a difference between a body temperature and an ambient temperature of a user holding a flashlight It is about a flashlight.

In general, LED flashlights use LED lamps that generate less power than filament lamps and generate high brightness.

However, a conventional LED flashlight uses a battery to supply power, but it has a problem that the capacity and life of the battery are limited.

In particular, the conventional LED flashlight has a problem that it is difficult to store the battery for a long period of time when the battery is used and the efficiency of the battery deteriorates with time.

In addition, although the conventional LED flashlight uses a rechargeable battery, the process of recharging the rechargeable battery each time has a troublesome and complicated problem.

In addition, the conventional LED flashlight can not easily be charged when the charging environment is poor, such as outdoor activities, and therefore, it has a limitation in use.

Korean Registered Utility Model No. 20-0425781 (2006.09.07) Korean Patent Laid-Open No. 10-2012-0039208 (Apr. 25, 2012) Korean Registered Utility Model No. 20-0465842 (March 3, 2013)

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art,

It is an object of the present invention to provide a self-powered LED flashlight using a thermostat which can emit an LED lamp by self-heating a thermoelectric power generator with a difference between a body temperature and an ambient temperature of a user who holds the flashlight.

To achieve the above object, a self-generated LED flashlight (100)

A body 110 forming an insertion hole 111 in the longitudinal direction; A plurality of thermoelectric generators 120 arranged on the inside of the insertion holes 111; A cooling body 130 inserted into the center of the array of the thermoelectric generators 120 to form a cooling hole 131 for circulating air in the longitudinal direction; A rechargeable battery 140 installed inside the cooling hole 131 and connected to the thermoelectric generator 120; An upper body 150 installed on the upper portion of the body 110; An LED lamp 160 mounted inside the upper body 150 and connected to the thermoelectric generator 120 to receive power by operation of a switch 112 formed on one side of the body 110; A lens 170 installed on the upper portion of the upper body 150; And a lid 180 installed at a lower portion of the body 110.

Here, a plurality of circulation holes 151 are formed on the outer surface of the upper body 150.

Further, a plurality of exhaust holes 181 are formed on the surface of the lid 180 so as to surround the ice.

And a heat pipe 190 for forming a through hole 182 at the center of the lid 180 and inserting the through hole 182 into the cooling hole 131.

The present invention has the effect that the thermoelectric power generator can be self-powered by the difference between the body temperature and the atmospheric temperature of the user who holds the flashlight.

In addition, since the present invention does not require any additional charging as in the prior art, it has an effect of improving the use efficiency.

In particular, since the present invention does not need to be replaced without using a battery, it has an effect of increasing the convenience of use.

1 is an exploded perspective view showing a structure of a self-generated LED flashlight using the present invention body heat.
2 is a perspective view showing a structure of a self-generated LED flashlight using the present invention body.

Technical features of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is an exploded perspective view illustrating a structure of a self-generated LED flashlight using the present invention body, and FIG. 2 is a combined perspective view illustrating a structure of a self-generated LED flashlight using the present invention body heat.

The present invention includes a body 110 forming an insertion hole 111 in the longitudinal direction thereof; A plurality of thermoelectric generators 120 arranged on the inside of the insertion holes 111; A cooling body 130 inserted into the center of the array of the thermoelectric generators 120 to form a cooling hole 131 for circulating air in the longitudinal direction; A rechargeable battery 140 installed inside the cooling hole 131 and connected to the thermoelectric generator 120; An upper body 150 installed on the upper portion of the body 110; An LED lamp 160 mounted inside the upper body 150 and connected to the thermoelectric generator 120 to receive power by operation of a switch 112 formed on one side of the body 110; A lens 170 installed on the upper portion of the upper body 150; And a lid 180 installed at a lower portion of the body 110.

Preferably, the body 110 is made of a metal material having a high thermal conductivity so that the body 110 can receive the body temperature in the state of being held by the user and can transmit the body temperature to the thermoelectric power generator 120 as well as can easily rise in temperature through sunlight.

At this time, a regulator (not shown) may be included in the body 110 to maintain a constant voltage for charging.

Particularly, the insertion hole 111 is formed to have a polygonal shape when viewed in a planar state, thereby increasing the area contacted with the outer side surface of the thermoelectric generator 120, thereby guiding the user's body temperature to be transmitted more.

In the present invention, the thermoelectric generator 120 generates a seeback effect with a temperature difference generated according to the body temperature of a user transmitted through the body 110 and the temperature of the air circulating through the cooling hole 131, To perform the power generation function.

At this time, the structure and operation principle of the thermoelectric generator 120 are commonly used in the art, and a detailed description thereof will be omitted.

In addition, the cooling body 130 serves to cool the atmospheric temperature to the thermoelectric generator 120.

In addition, a plurality of cooling fins may be formed in the cooling holes 131 to increase the heat radiation efficiency.

Meanwhile, the rechargeable battery 140 charges the current generated from the thermoelectric generator 120 when the flash lamp is not used.

In particular, a plurality of circulation holes 151 are formed on the outer surface of the upper body 150 so that external air is circulated to the inside of the cooling holes 131 to improve the cooling efficiency.

In addition, the LED lamp 160 can emit light through the minimum current generated by the thermoelectric generator 120 because the power consumption is low and the service life is semi-permanent.

The lens 170 may be formed in a convex or concave shape to adjust an irradiation range of the LED lamp 160.

Further, a large number of exhaust holes 181 are formed on the surface of the lid 180 so that external air can be circulated to the inside of the cooling holes 131 to improve the cooling efficiency.

A through hole 182 is formed in the center of the lid 180 and a heat pipe 190 is inserted through the through hole 182 to be inserted into the cooling hole 131, The cooling efficiency can be maximized.

The temperature of the cooling body 130 is lowered by the atmospheric air so that the temperature of the thermoelectric power generating element 120 is lowered. So that the thermoelectric generator 120 can generate the self-power, and the LED lamp 160 can emit light.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Of course.

100: self-generated LED flashlight using the present invention
110: body 111: insertion hole
112: switch
120: thermoelectric element
130: cooling body 131: cooling hole
140: Rechargeable battery
150: upper body 151: circulation hole
160: LED lamp
170: lens
180: lid 181: exhaust air
182: Through the hole
190: Heat pipe

Claims (4)

A body 110 forming an insertion hole 111 in the longitudinal direction; A plurality of thermoelectric generators 120 arranged on the inside of the insertion holes 111; A cooling body 130 inserted into the center of the array of the thermoelectric generators 120 to form a cooling hole 131 for circulating air in the longitudinal direction; A rechargeable battery 140 installed inside the cooling hole 131 and connected to the thermoelectric generator 120; An upper body 150 installed on the upper portion of the body 110; An LED lamp 160 mounted inside the upper body 150 and connected to the thermoelectric generator 120 to receive power by operation of a switch 112 formed on one side of the body 110; A lens 170 installed on the upper portion of the upper body 150; And a lid (180) provided at a lower portion of the body (110). The self-powered LED flashlight according to claim 1, wherein a plurality of circulation holes (151) are formed on the outer side of the upper body (150). The self-powered LED flashlight according to claim 1, wherein a plurality of air holes (181) are formed on the surface of the lid (180). The heat exchanger according to claim 1, further comprising a heat pipe (190) formed at the center of the lid (180) to form a through hole (182) and penetrate through the through hole (182) Self-powered LED flashlight using body heat.

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