DE20310418U1 - High power pocket torch with heat dissipation device, has several cooling fins for removing heat generated by high-power bulb - Google Patents

Abstract

A pocket torch has a lower part (23) with an insulated contact point (231) and a high power bulb (21) fixed on the lower part with an anode electrode (211) and cathode electrode (212). A housing (24) is fixed to the lower part (23) and has several cooling fins (241) for removal of heat generated by the high power bulb (21). A reflector (22) is mounted around the high power bulb (21) for reflecting the light radiated from the high power bulb. A power source has a positive terminal (2611) which is connected to the contact point (2311) and a negative terminal which is connected to the lower part (23) for power supply of the high power bulb (21). An independent claim is given for a housing fixed to a lower part.

Description

FLASHLIGHT WITH HEAT DISSIPATION DEVICE BACKGROUND OF THE INVENTION

(a) Environment of the invention

The present invention relates to a flashlight, in particular a flashlight with a heat dissipation device.

(b) Description of the conventional design
Flashlights are very useful as portable lighting devices

useful. Depending on your needs, several different flashlights

Â&iacgr;&ogr;, among which a flashlight with a high-power light source is one. A light-emitting diode (LED) is used as a light source. Compared with the conventional light sources, such as a pilot lamp, signal lamp, fluorescent lamp, incandescent lamp, etc., the light-emitting diode (LED) can be of various sizes and designed to be low-heat, energy-saving, long-life, short start-up time, environmentally friendly, thin and compact . However, LED flashlights always have to use a whole LED array. Recently, high-power light-emitting diodes have been developed and become popular. Therefore, the high-power LED flashlight can be used in a practical way. The disadvantage, however, is that these high-power light-emitting diodes generate a lot of waste heat, which affects or reduces the practical applicability and lifespan of these light-emitting diodes. This problem

needs a solution. Most flashlights are designed with a cylindrical housing into which one or more batteries are inserted. One end of this cylindrical housing is fitted with a cap with a light source inside, such as a light bulb or a light emitting diode, a reflector and a lens cap that covers the light source. The light source is electrically connected in series with the batteries so that they are turned on and off, with the light source usually being turned on and off with a switch.

&iacgr;&ogr; can be turned off. In order to achieve better performance and for a stronger light, the light source of the flashlight is generally powered by two or more batteries in series and/or with larger batteries. However, the more batteries are needed for a stronger light, the larger the housing of the flashlight must be. Fig. 1 shows a high-performance LED flashlight according to the known design. As can be seen here, this high-performance LED flashlight is made up of a high-performance LED lamp 11, a reflector 12, a base 13, a protective housing 14, a lens cover 15, a light source 16 and a switch 17. The high-performance LED lamp 11 is attached to the base 13 and is equipped with the reflector 12 on the inside. The reflector bundles and reflects the light rays emitted by the high-performance LED lamp 11. The base 13 serves to connect the power source 16. The switch 17 can be used to switch the light of the flashlight

on or off. The protective housing 14 and the power source 16 are fastened together by screws. After assembling the protective housing 14 and the power source 16, the high-performance LED lamp 14, the reflector 12 and the base 13 can be installed in the protective housing 14. In addition, the protective housing 14 has an opening for letting the light rays through. The flashlight is also provided with a lens cover 15, which completely protects the high-performance LED lamp 11.

2 is a sectional view of the high power LED flashlight of the conventional type. As can be seen, the high power LED lamp 11 is attached to the base 13 and is provided with the reflector 12 inside, the base 13 being installed in the protective case 14. The high power LED lamp 11 has a cathode electrode connected to the base 13, while an anode electrode is connected to a conductive element 131. This conductive element 131 is insulated from the base 13 by an insulating element 132. When the protective case 14 is assembled with the power source 16, the conductive element 131 comes into contact with a positive terminal 1611 of the battery 161 of the power source 16. The base 13, the protective case 14 and the power source 16 are made of an aluminum alloy. Accordingly, the high-performance LED lamp 11 can be switched on and off with a switch 17 on the bottom after the flashlight has been assembled.

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The high-performance LED flashlight of the well-known design is easy to use and assemble. The disadvantage of this design, however, is the heat dissipation. The lifespan of the LED depends on the ambient temperature around the LED chip. Therefore, the temperature for the LED must be controlled. Usually, 10% of the current is converted into light by the LED and 90% into heat. In the conventional design, however, this waste heat generated by the lamp cannot be dissipated, which reduces the lifespan of the

&iacgr;&ogr; flashlight. Therefore, this type of construction requires a heat dissipation device that can prevent damage to the lamp due to overheating, and this type of construction must be easy and efficient to assemble and can eliminate the disadvantages of the conventional construction.
SUMMARY OF THE INVENTION

An object of the present invention is to provide a flashlight with a heat dissipation device to prevent heat buildup and thus reduce the failure rate of this flashlight on the one hand and to extend the operating life of this high performance flashlight on the other hand.

According to one aspect of the present invention, the flashlight comprises a base with a contact point isolated therefrom; a high-performance

The flashlight according to the invention is constructed from a high-performance lamp body which is equipped with an anode electrode connected to the contact point and a cathode electrode connected to the base. The flashlight according to the invention also consists of a housing with the base and several cooling plates, with which the waste heat generated by the lamp body is dissipated; a reflector mounted around the high-performance lamp body, with which the light rays emitted by the high-performance lamp body are bundled and reflected; and a power source with a positive terminal, which is connected to

β the contact point and with a negative terminal, the latter connected to the base to supply power to the high-power lamp.

The high-performance lamp can also be designed in the form of a light-emitting diode (LED).

The base, the housing and the power source can be constructed of heat-conducting and electrically conductive material.

This heat-conducting and electrically conductive material can be an aluminum alloy.
The structure of the flashlight according to the invention is preferably provided with a switch which is connected to the power source for controlling the power supply.

The power source preferably has a retaining sleeve mounted around the power source to facilitate holding.
This retaining bush can be made of a heat-insulating material.

This heat insulating material can be made of rubber.

The base and the housing can be made as a single piece.

This base and the housing can be manufactured using the metal injection molding (MIM) process.

According to a further aspect of the present invention, the flashlight is constructed from a base provided with a contact point, said contact point being insulated from the base. A high-power lamp is mounted on the base, said lamp being provided with an anode electrode connected to the contact point and a cathode electrode connected to the base. A power source has a positive terminal connected to the contact point and the negative terminal to supply electrical energy to the lamp. In addition, the base is provided with a housing and with a plurality of heat sinks for dissipating the waste heat generated by the high-power lamp, in order to prevent damage to the high-power lamp and the flashlight on the one hand and to extend their operating life on the other.

The base and the housing are preferably made of heat-conducting and electrically conductive material.

The material can be an aluminum alloy.

The base and the housing are made as one piece.

This base and the housing can be manufactured using the metal injection molding (MIM) process.

The flashlight is preferably provided with a cover which is mounted to the housing and serves to cover the high-power lamp for its protection.

According to another aspect of the present invention, the housing of the flashlight with the high-performance lamp is equipped with several heat sinks that serve to dissipate heat in order to protect the high-performance lamp of the flashlight from damage and to extend its service life.

Accordingly, the housing structure is constructed from a heat-conducting and electrically conductive material, which material consists of an aluminum alloy.

The above-described objects and advantages of the present invention will become more apparent to those skilled in the art after reading the following detailed description when taken in conjunction with the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 shows a high-power LED flashlight according to the known design;

Fig. 2 shows a sectional view of the high-power LED flashlight according to the known embodiment;

Fig. 3 shows a sectional view of the high-power LED flashlight according to the present embodiment; and

Fig. 4 shows a high-performance LED flashlight according to the present embodiment.
DETAILED DESCRIPTION OF THE PREFERRED

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TYPE OF EXECUTION

The present invention describes a high power flashlight with a heat dissipation device, the objects and advantages of the present invention being more apparent to those skilled in the art after reading this detailed description. The present invention need not be limited to the following embodiment. It may be applied to a high power LED lamp or other high power lamps, etc.

3, there is shown a sectional view of a high power LED flashlight according to the present invention. As can be seen, this flashlight is constructed of a base 23 having a contact point 231 insulated from this base 23 by an insulating member 232; a high power lamp 21 secured to the base 23 and having an anode electrode 211 connected to the contact point 231 and a cathode electrode 212 connected to the base 23; a power source 26 having a positive terminal 2611 connected to the contact point 231 and a negative terminal (not shown) connected to the base 23 for supplying power to the lamp 21; and a housing 24 secured to the base 23. This housing has several cooling plates 241 for dissipating the waste heat generated by the high-performance lamp 21 in order to avoid damage to the flashlight on the one hand and to extend its service life on the other.

The present invention can be equipped with a light emitting diode (LED) 21. The housing 24 and the power source 26 can be made of a heat-conducting and electrically conductive material, for example an aluminum alloy. For use, the flashlight has a switch 27 connected to the power source 26 for switching this flashlight on and off, with a holding sleeve 28 also being provided around the power source 26 to make it easier to hold. This holding sleeve 28 is made of a heat-insulating material, such as

&iacgr;&ogr; for example, rubber. In addition, the base 23 and the housing 24 can be made in one piece using the metal injection molding process (MIM).

In Fig. 4, a high-performance LED flashlight according to the present invention is shown. This flashlight according to the invention consists of a base 23 with a contact point 231, which is insulated from the base 23 by an insulating element 232; a high-performance lamp 21 attached to the base 23 with an anode electrode 211, which is connected to the contact point 231 and to a cathode electrode 212, which is connected to the base 23; a housing 24 attached to the base 23 with several cooling plates 241 for dissipating the waste heat generated by the high-performance lamp 21; a reflector 22 mounted around the high-performance lamp 21, with which the light rays emitted by this high-performance lamp 21 are bundled and reflected; and a power source 26 with a

positive terminal 2611 connected to the contact point 231 and a negative terminal 2612 connected to the base 23 for supplying power to the high power lamp 21.
The present invention can be equipped with a light emitting diode (LED) 21. The housing 24 and the power source 26 can be made of a heat-conducting and electrically conductive material, for example an aluminum alloy. For use, the flashlight has a switch 27 connected to the power source 26 for switching this

&iacgr;&ogr; flashlight, wherein a holding bushing 28 is also provided around the power source 26 to make it easier to hold. This holding bushing 28 is made of a heat-insulating material, such as rubber. In addition, the base 23 and the housing 24 can be made in one piece using the metal injection molding process (MIM).

According to one aspect of the present invention, the invention comprises a housing 24 of a flashlight with a high-performance lamp 21. In addition, the housing 24 is equipped with a plurality of heat sinks 241 for dissipating the waste heat generated by the high-performance lamp 21 in order to avoid damage due to overheating and to maintain the operating life longer.

The housing 24 is made of a heat-conducting and electrically conductive material, which material consists of an aluminum alloy.

40

According to the above description, the present invention provides a flashlight with a heat dissipation device which can prevent damage to the lamp body due to overheating, which type of construction must be easy and efficient to assemble and which can eliminate the disadvantages of the conventional type. Accordingly, the present invention has many excellent features which can eliminate the disadvantages of the conventional type and provide practical, reliable and novel products,

&iacgr;&ogr; whose economic efficiency is improved. Therefore, the present invention represents a great industrial value.

While the present invention represents an embodiment which is presently considered practical and preferable, it is to be understood that the scope of the present invention is not to be limited in any way to the embodiments described herein, but is intended to include various modifications and similar arrangements within the spirit and scope of the following claims, which are to be interpreted in the broadest sense so as to encompass all such modifications and similar arrangements.

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Claims (20)

1. A flashlight consisting of:
a base ( 23 ) having a contact point ( 231 ) isolated therefrom;
a high-power lamp ( 21 ) attached to the base ( 23 ) and having an anode electrode ( 211 ) connected to the contact point ( 231 ) and a cathode electrode ( 212 ) connected to the base ( 23 );
a housing ( 24 ) attached to the base ( 23 ) with a plurality of cooling plates ( 241 ) for dissipating the waste heat generated by the high-performance lamp ( 21 );
a reflector ( 22 ) mounted around the high-performance luminous element ( 21 ) for bundling and reflecting the light rays emitted by this high-performance luminous element ( 21 ); and
from a power source ( 26 ) having a positive terminal ( 2611 ) connected to the contact point ( 231 ) and a negative terminal ( 2612 ) connected to the base ( 23 ) for supplying power to the high-power lamp ( 21 ). 2. The flashlight according to claim 1, characterized in that the high-performance luminous element ( 21 ) is designed in the form of a light-emitting diode (LED). 3. The flashlight according to claim 1, characterized in that the base ( 23 ), the housing ( 24 ) and the power source ( 26 ) are made of a heat-conducting and electrically conductive material. 4. The flashlight according to claim 3, characterized in that said heat-conducting and electrically conductive material consists of an aluminum alloy. 5. The flashlight according to claim 1, characterized in that it is further provided with a switch ( 27 ) connected to the power source ( 26 ) for turning the flashlight on and off. 6. The flashlight according to claim 1, characterized in that a holding sleeve ( 28 ) is provided around the power source ( 26 ) to facilitate holding. 7. The flashlight according to claim 6, characterized in that this holding sleeve is made of a heat-insulating material. 8. The flashlight according to claim 7, characterized in that said heat insulating material is made of rubber. 9. The flashlight according to claim 1, characterized in that the base ( 23 ) and the housing ( 24 ) are made in one piece. 10. The flashlight according to claim 9, characterized in that the base ( 23 ) and the housing ( 24 ) are made in one piece using the metal injection molding process (MIM). 11. A flashlight consisting of:
a base ( 23 ) having a contact point ( 231 ) isolated therefrom;
a high-power lamp ( 21 ) attached to the base ( 23 ) and having an anode electrode ( 211 ) connected to the contact point ( 231 ) and a cathode electrode ( 212 ) connected to the base ( 23 );
from a power source ( 26 ) having a positive terminal ( 2611 ) connected to the contact point ( 231 ) and a negative terminal ( 2612 ) connected to the base ( 23 ) for supplying power to the high-power lamp ( 21 ).
a housing ( 24 ) attached to the base ( 23 ) with a plurality of cooling plates ( 241 ) for dissipating the waste heat generated by the high-performance lamp ( 21 ) in order to prevent damage to the flashlight on the one hand and to extend its operating life on the other hand; 12. The flashlight according to claim 11, characterized in that the base ( 23 ) and the housing ( 24 ) are made of a heat-conducting and electrically conductive material. 13. The flashlight according to claim 12, characterized in that said material consists of an aluminum alloy. 14. The flashlight according to claim 11, characterized in that the base ( 23 ) and the housing ( 24 ) are made in one piece. 15. The flashlight according to claim 14, characterized in that the base ( 23 ) and the housing ( 24 ) are made in one piece using the metal injection molding process (MIM). 16. The flashlight according to claim 11, characterized in that it is further provided with a cover which is mounted with the housing and serves to cover the high-power lamp ( 21 ) for its protection. 17. a housing ( 24 ) attached to the base ( 23 ) and equipped with a plurality of cooling plates ( 241 ) for dissipating the waste heat generated by the high-performance lamp ( 21 ) in order to prevent damage to the flashlight on the one hand and to extend its operating life on the other hand; 18. The housing structure according to claim 17, characterized in that this housing ( 24 ) is constructed from a heat-conducting and electrically conductive material. 19. The housing structure according to claim 18, characterized in that the material consists of an aluminum alloy. 20. The flashlight according to claim 17, characterized in that the high-performance luminous element ( 21 ) is designed in the form of a light-emitting diode (LED).