DE202011052030U1 - Underwater LED lighting device - Google Patents

Abstract

LED underwater lighting device (100), comprising a light-transmissive lamp tube (10), which has a front end opening (11) and an opposite rear end opening (12) and two longitudinal grooves (13), the bilateral on the inside wall of the Tubes are arranged between the front end opening and the rear end opening, an LED substrate (20) which is an aluminum-clad circuit board which is fixed to the longitudinally arranged grooves (13) inside the light-transmissive lamp, the LED substrate (20) carries a plurality of LED devices on its upper surface for emitting light, a heat conducting rod (30) which is fixed in the light-transmissive lamp tube and between the lower surface of the LED substrate and the inner wall of the light-transmissive lamp tube (10) for emitting Waste heat from the LED substrate ends, a front-end cap (40) covering the front end opening of the light-transmissive lamp tube and a back end cap (50) which closes the back end opening of the light transmissive lamp tube in a waterproof manner.

Description

Background of the invention

1. Field of the invention:

The present invention relates to LED lighting devices, and more particularly to an underwater LED lighting device for underwater use, for example, for use in an aquarium provided with a thermal conductor for rapid dissipation of waste heat.

2. Description of the Related Art:

Because of the great advantage of energy saving and carbon reduction requirements, the LED lighting industry represents a new generation of the mainstream market. In an aquarium or decorative water-eco system, an underwater light can be used to create lighting and create decorative features. Lighting device to be installed. Since lighting devices for the underwater purpose are turned on for a long period of time, LED components are mainly used for light emission because they cause savings in power consumption. However, the use of an LED lighting device requires rapid heat dissipation to avoid attenuation of LED brightness. Conventional LED underwater lighting devices can not provide a heat dissipation device. Even if an LED underwater lighting device is provided with a heat dissipation device, the effect of heat dissipation is still not optimal. After a long period of use of a conventional LED underwater lighting device, the problem of attenuation of the LED brightness occurs. An improvement in this regard is required.

Summary of the invention

The present invention has been accomplished by taking into account the above-described conditions. It is therefore an object of the present invention to provide a LED underwater lighting device provided with a thermal conduction bar which quickly dissipates the waste heat from the LED components during operation of the LED underwater lighting device.

To accomplish these and other objects of the present invention, an underwater LED lighting device includes:
A light transmissive lamp tube having a front end opening and an opposite rear end opening and two longitudinal grooves bilaterally disposed on the inside wall of the tube between the front end opening and the rear end opening, an LED substrate being an aluminum-clad circuit board which is fixed to the longitudinal grooves within the light transmissive lamp and carries a plurality of LED devices on its upper surface for emitting light, a thermal conduction bar fixed in the light transmissive lamp tube and between the lower surface of the LED substrate and the inner wall of the light transmissive lamp tube for discharging waste heat from the LED substrate terminates, a front end cap which terminates the front end opening of the light transmissive lamp tube in a watertight manner, and a rear end cap which the rear end opening of the light transmissive lamp tube in wasserdic closes way.

By disposing the thermal conduction bar, the invention considerably increases the heat distributing ability of the LED substrate while maintaining the brightness and operational continuity of the LED devices for a long period of time, thereby avoiding the serious problem of brightness attenuation. With respect to one and the same size of aquarium, it is no longer necessary to increase the outside diameter or the length of the lighting device to increase the brightness, with the present invention exhibiting a high degree of competitiveness.

The Wärmeleitstab can be designed in cross section with a variety of different shapes.

In one example of the present invention, the thermal conduction bar has an upper chamfered end which abuts against the lower surface of the LED substrate, and has a circularly curved outer periphery which is held in contact with the light transmissive lamp tube.

Other advantages and features of the present invention will become apparent upon reference to the following description, taken in conjunction with the accompanying drawings, in which like reference characters designate the same components of the structure.

Brief description of the drawings

1 shows an exploded view of a LED underwater lighting device according to the present invention.

2 Fig. 13 is a schematic composition of the underwater LED lighting device according to the present invention.

3 Fig. 12 is a schematic side view of the underwater LED lighting device according to the present invention.

4 is a sectional view on an enlarged scale, taken along the line AA 3 ,

Detailed Description of the Preferred Embodiment

Regarding 1 is an LED underwater lighting in it 100 shown in accordance with the present invention. The LED underwater lighting 100 has a light transmissive lamp tube 10 on, an LED substrate 20 , a thermal conductor 30 , a front end cap 40 and a back end cap 50 ,

The light transmissive lamp tube 10 may be a plastic tube, having a front end opening 11 and a rear end opening opposite thereto 12 , as well as two longitudinal grooves 13 which are arranged symmetrically on the inner side wall of the tube on two opposite sides. The LED substrate 20 is an aluminum-clad circuit board attached to the longitudinal grooves 13 in the light transmissive lamp tube 10 is arranged. Moreover, the LED substrate has 20 a plurality of LED devices 21 which are installed on the upper surface of the substrate.

The main feature of the present invention relates to the arrangement of the Wärmeleitstabes 30 in the light transmissive lamp tube 10 , Like that in 4 is shown, is the heat conductor 30 in the light transmissive lamp tube 10 between the lower surface of the LED substrate 20 and the inside wall of the light transmissive lamp tube 10 attached. The thermal conductor 30 has a top cut surface 31 , which he uses against the bottom surface of the LED substrate 20 adjacent, and a circular curved outer circumference 32 , with the inside wall of the light transmissive lamp tube 10 in contact. By holding the Wärmeleitstabes 30 in close contact with the LED substrate 20 can waste heat from the LED substrate 20 be quickly dissipated, resulting in a reduction in the brightness of the LED device 21 avoids. It is clear that the thermal conductor 30 not on the in 4 shown configuration is limited. The thermal conductor 30 can also be made in a variety of other forms. In 4 The heat pipe has a massive structure. Alternatively, the Wärmeleitstab 30 have a hollow structure.

Moreover, the front end cap is 40 and the back end cap 50 each at the front end opening 11 and at the rear end opening 12 the light transmissive lamp tube 10 set for sealing against water. The back end cap 50 further allows the passage of a power line 60 that is electrically connected to the LED substrate 20 connected.

The invention provides due to the arrangement of the Wärmeleitstabes 30 an increased ability to dissipate heat from the LED substrate 20 , wherein the brightness and the operating function of the LED devices 21 maintained for a long period of time and the serious problem of brightness attenuation is avoided. In one and the same aquarium size, it is no longer necessary, on the basis of the present invention, to increase the outside diameter or the length of the lighting device to increase the brightness. Therefore, the invention provides a high degree of competitiveness.

Although a particular embodiment of the invention has been described in detail for purposes of illustration, various modifications and enhancements may be made without departing from the spirit and scope of the invention. Accordingly, the invention is limited by the appended claims, but not by the above description.

Claims (5)

LED underwater lighting device ( 100 ), comprising a light transmissive lamp tube ( 10 ), which has a front end opening ( 11 ) and an opposite rear end opening ( 12 ) and two longitudinal grooves ( 13 ) disposed bilaterally on the inside wall of the tube between the front end opening and the rear end opening, an LED substrate ( 20 ), which is an aluminum-clad circuit board attached to the longitudinal grooves ( 13 ) is fixed within the light transmissive lamp, the LED substrate ( 20 ) carries a plurality of LED devices on its upper surface for emitting light, a heat conducting rod ( 30 ), which is mounted in the light-transmissive lamp tube and between the lower surface of the LED substrate and the inner wall of the light-transmissive lamp tube ( 10 ) for dissipating waste heat from the LED substrate, a front-end cap ( 40 ) terminating the front end opening of the light transmissive lamp tube in a watertight manner, and a back end cap (FIG. 50 ) terminating the back end opening of the light transmissive lamp tube in a watertight manner. An underwater LED lighting device according to claim 1, wherein the thermal conduction bar ( 30 ) has an upper chamfered end which abuts against the lower surface of the LED substrate ( 20 ) adjoins. LED underwater lighting device according to claim 2, wherein the heat conductor ( 30 ) has a circular periphery which is held in contact with the inner side wall of the light transmissive lamp tube. An underwater LED lighting device according to claim 1, wherein the thermal conduction bar ( 30 ) has a massive structure. An underwater LED lighting device according to claim 1, wherein the thermal conduction bar ( 30 ) has a hollow structure.

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