The present invention relates to the field of illumination technology, and more particularly relates to a LED (Light Emitting Diode) lamp having high brightness, uniform light-emitting surface and good heat dissipation.
LED lamps are more and more widely used in the illumination field due to their low-carbon, environment-friendly, long operating life characteristics etc. In the current market, a LED lamp is configured to fix a plurality of LEDs on a lamp panel above which a heat-dissipating cover and a light-transmitting cover are provided. The plurality of LEDs will lead to heat-dissipating problems which are difficult to deal with, and a lot of heat build-up may result in hidden danger of heat dissipation. In addition, the arrangement of the plurality of LEDs may cause a non-uniform light-emitting surface, which will result in the fact that shadows of the LEDs can be seen.
In the existing side LED backlight module, the light guide plate is optically designed such that light emitted from LEDs can bring about images of more uniform brightness at the light-exiting surface of the light guide plate. That is, the backlight surface of the light guide plate is designed with regular light guide grid-dots for regulating the light. However, the volume of the LED lamp implemented by using the light guide plate is small, which results in the fact that it is difficult to optically distribute the grid-dots. That is, it is difficult to obtain a uniform brightness distribution on the entire light-exiting surface of the light guide plate.
In order to solve the above problems, the present invention makes a beneficial improvement.
An object of the present invention is to provide a LED lamp which can effectively improve the light efficiency and has a uniform brightness distribution on the entire light-emitting surface.
The present invention is achieved in the following technical solution: a LED lamp, including a LED strip and a cylindrical light guide body connected to the LED strip, wherein light emitted from the LED strip irradiates toward the light guide body and exits via the surface of the light guide body.
The LED lamp further includes a light guide connection plate arranged at a side of the light guide body and provided with a recess, and the LED strip is embedded in the recess.
Further, the recess is in parallel with the light guide body, and the light-emitting surface of the LED strip faces the light guide body.
The LED strip includes a plurality of LEDs provided thereon, and the plurality of LEDs are arranged in a line and equally spaced therebetween.
Further, LEDs at both ends of the LED strip are arranged to respectively slant towards the end surfaces of the light guide body close to them.
Still further, the LED strip further includes a plurality of divider resistors provided thereon, and each LED of the LED strip and a divider resistor are connected in series.
In addition, the LED lamp further includes a L-shaped backplate, and the LED strip is adhered to the inner surface of one side plate of the L-shaped backplate, wherein the one side plate is embedded in the recess of the light guide connection plate, and the other side plate of the L-shaped backplate is arranged outside the light guide connection plate.
Material of the L-shaped hackplate includes aluminum.
Further, the LED strip is adhered to the L-shaped backplate by heat-dissipating adhesive.
Moreover, the LED lamp further includes a driving power supply provided on the outer surface of the L-shaped backplate outside the light guide connection plate.
In addition, material of the light guide body includes polymethyl methacrylate (PMMA).
Compared to the existing technologies and products, the present invention provides following advantages:
1. In the present invention, by providing the LED strip at a side of the light guide body and guiding out the light emitted from the LED strip by the light guide body, in the case that the same lighting effect is required, the number of the LEDs required is significantly reduced; By providing a cylindrical light guide body and arranging the two LEDs at both ends of the LED strip slant towards the end surfaces of the light guide body close to them, a uniform brightness can be achieved on the entire light-emitting surface of the light guide body of the LED lamp;
2. The present invention provides a better way to solve the heat-dissipating problem of the LED lamp;
3. With the structure of the light guide connection plate provided with a recess, the LED lamp provided by the present invention is better in light efficiency and the volume thereof is smaller;
4. By providing the driving power supply of the LED strip on the aluminum backplate and outside the lamp tube (i.e. the light guide body), the driving power supply operates safely and a light-emitting surface with uniform brightness is obtained.
Hereafter, embodiments of the present invention will be described in detail in conjunction with the accompanying drawings.
As shown in
Specially, the LED strip 4 is detachably or fixedly connected to the light guide body 3. The light guide body 3 is cylindrical. Light emitted from the LED strip 4 will irradiate towards the light guide body 3 and exit via the surface of the light guide body 3.
In the present embodiment, as the light guide body 3 is cylindrical, the path of the light emitted from the LED lamp can be regulated effectively and the light-exiting angle will be changed, thereby lighting effect of high brightness and good uniformity can be achieved.
The LED strip 4 can be arranged at a side of the light guide body 3 in numerous connecting ways (such as by using adhesive, by mounting bracket or support plate), and emits light towards the light guide body 3.
Preferably, the LED strip 4 is arranged at a side of the light guide body 3 in an embedded manner. As shown in
With the light guide connection plate 1 provided with a recess, the LED lamp itself will be more compact, durable and of smaller volume while light efficiency of the LED lamp will be improved.
Of course, the LED strip 4 can also be adhered to a backplate, and the backplate is then inserted into the recess of the light guide connection plate 1. The shape of the backplate can be determined in accordance with the actual requirements by a skilled person in the art. In the present embodiment, preferably, the backplate is implemented as an L-shaped backplate 2, and material with good heat dissipation (such as aluminum) is selected as material of the L-shaped backplate 2. The LED strip 4 is adhered to the inner surface of one side plate of the L-shaped backplate 2, which is embedded in the recess of the light guide connection plate and the other side plate of the L-shaped backplate 2 is provided outside the light guide connection plate 1. As surface area of the L-shaped backplate 2 is large, and the one side plate of the L-shaped backplate 2 (to which the LED strip 4 is adhered) is embedded in the recess of the light guide connection plate 1 while the other side plate of the L-shaped backplate 2 is provided outside the light guide connection plate 1, the heat dissipation of the LED strip 4 will be better. In order to ensure the heat-dissipating effect, the LED strip 4 is adhered to the L-shaped backplate 2, and it is best to use heat-dissipating adhesive (i.e. thermally conductive silicone) to adhere.
Preferably, light guide material with good light transmission for the light emitted from the LED strip is selected as material of the light guide connection plate 1. In the present embodiment, preferably, PMMA (polymethy) methacrylate) material is used. Light transmission of PMMA material for the white light is up to 92%. In addition, product of PMMA material has low birefringence, good transparency, and prominent ageing stability.
As shown in
The LED strip 4 can be driven by a constant voltage. By providing several divider resistors 42 on the LED strip 4 and ensuring that each LED 41 and a divider resistor 42 are connected in series, in the case that the rating driving voltage of each LED 41 is satisfied, the voltage can be divided. By dividing the voltage using the divider resistors, the light-emitting brightness of the LEDs 41 will be uniformly distributed. In addition, as to the LEDs 41 at both ends of the LED strip 4, each LED 41 is arranged to slant towards the end surface of the light guide body 3 close to it. Higher power LEDs can be provided at both ends of the LED strip 4 to improve the light-emitting effect at both ends of the cylindrical light guide body 3, so that there is no shadow on the entire surface of the light guide body 3 and a surface with uniform brightness can be achieved.
As shown in
Obviously, person skilled in the art can make various modifications and variations without departing from the spirit and the scope of the invention. The present invention is intended to include these modifications and variations if these modifications and variations belong to the scope of the claims and their equivalents.
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2012 1 0384633 | Oct 2012 | CN | national |
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First office action and search report issued by Chinese Patent Office for priority application 201210384633.8 dated Feb. 14, 2014. |
Second office action issued by Chinese Patent Office for priority application 201210384633.8 dated Sep. 25, 2014. |
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20140104867 A1 | Apr 2014 | US |