1. Field of the Invention
The present invention is related to an LED bulb, and more particularly to a bending LED bulb that can provide uniform luminance and dissipate out heat generated by LEDs.
2. Description of the Related Art
Ball-type bulbs and incandescent tubes for lighting purpose in early stage are all quite common.
In view of the awakening energy-saving consciousness, energy-saving bulbs, such as U-shaped bulb, 2C type bulb and helical bulb, have started their entry in the light market. In spite of being more energy-saving, LED bulbs with more energy-saving capability overwhelm the glamour of the earlier energy-saving bulbs to become the new favorite in the market after high power white light LED technique become mature.
With reference to
The base 31 has a free end, a base electrode 311 and a bottom electrode 312. The base electrode 311 takes a form of threads formed around the base 31 for screwing into a screw lamp socket. The bottom electrode 312 is formed on a bottom of the base 31.
The LED substrate 32 is securely mounted on an end of the base 31 opposite to the free end, and has a rigid circuit board 321, a plurality of light-emitting diodes (LED) 322 and a heat sink 323. The rigid circuit board 321 is electrically connected to the base electrode 311 and the bottom electrode 312. The LEDs 322 are mounted on a top of the rigid circuit board 321 in a form of a matrix pattern. The heat sink is mounted on a bottom of the rigid circuit board 321. The glass cover 33 is securely mounted on the base 31 to cover the LED substrate 32 therein.
As the candle (cd) of a bulb for lighting must reach a standard value, the LED bulb 30 needs to employ a plurality of LEDs, for example, as shown in
Furthermore, there are plenty of ball-type LED bulbs and LEDs tubes currently available in the marketplace, while energy-saving bending LED tubes haven't been absent in the market so far. If the heat dissipation issue of the LEDs can be solved, LED bulbs can be further promoted as the new-generation energy-saving lighting source.
An objective of the present invention is to provide a bending LED bulb providing uniform luminance and dissipating waste heat generated by LEDs.
To achieve the foregoing objective, the bending LED bulb has a transparent bending tube and at least one flexible LED strip. The transparent bending tube has two ends and at least one sealing end. The at least one sealing end is formed on at least one of the ends of the transparent bending tube. Each one of the at least one sealing end has a power electrode mounted thereon.
The at least one flexible LED strip is mounted in the transparent bending tube and each one of the at least one flexible LED strip has a flexible PCB and a plurality of LEDs. The flexible PCB is electrically connected with the at least one power electrode. The plurality of LEDs is separately mounted on the flexible PCB.
The flexible LED strip has the LEDs mounted thereon passes through the transparent bending tube with various shapes to form the bending LED tube. As the LEDs are separately mounted on the transparent bending tube, the LEDs can be uniformly allocated in the transparent bending tube. Moreover, because the LEDs are adjacent to the wall of the transparent bending tube 10, not only can luminance of the bending LED bulb be enhanced, but also waste heat generated by the LEDs 22 can be dissipated out through the wall of the transparent bending tube 10, so as to avoid high temperature resulting from accumulation of the waste heat.
With reference to
The transparent bending tube 10 has two sealing ends 11 and two power electrodes 12, 13. The two sealing ends 11 are respectively formed on two ends of the transparent bending tube 10. The two power electrodes 12, 13 are respectively mounted on the two sealing ends 11. In the present embodiment, the transparent bending tube 10 is alternatively and repeatedly bent up and down to have the two sealing ends facing a same direction.
The at least one flexible LED strip 20 is received in the transparent bending tube 10, and has a flexible printed circuit board (PCB) 21 and a plurality of LEDs 22. The LEDs 22 are separately mounted on the flexible PCB 21. Both ends of the flexible PCB 21 are electrically and respectively connected with the two power electrodes 12, 13 on the two ends of the transparent bending tube 10. In an embodiment, the LEDs 22 are spaced on the flexible PCB 21 at equal intervals. Alternatively, the LEDs 22 may be spaced on the flexible PCB 21 at different intervals.
With reference to
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As illustrated by the foregoing embodiments, the transparent bending tube 10˜10e has at least one sealing end 11. As shown in
With reference to
Besides, a total voltage consumed by the flexible LED strip 20 or all LEDs 22 of each sub light group 201 is equal to an input voltage of an external power source. For example, in an embodiment, if a driving voltage Vf required by an individual LED is 3.3 V and an external input voltage is 120 V, a total voltage of all the LEDs 22 serially connected in each sub light group 201 is a multiple of 3.3 V and the total voltage shall be substantially equal to the external input voltage. A plurality of sub light groups 201 can be further parallelly connected to the external input voltage or power.
To further enhance a cooling efficiency of the transparent bending tube 10˜10f, the transparent bending tube 10˜10f can be vacuumed and then filled in with a gas having a heat transfer coefficient higher than that of air or inert gas to prevent high temperature from oxidizing metal wires 211, 212 or metal contacts. The vacuuming and the filling of the gas or inert gas with higher heat transfer coefficient can be carried out through the sealing end 11 of the transparent bending tube 10˜10f and with a duct of an external gas vacuum and a filling device. The sealing end 11 of the transparent bending tube 10˜10f can be formed by directly melting at least one opening of the transparent bending tube 10˜10f, thereby saving additional material. The sealing end 11 that receives the power electrodes 12, 13 therein further has a non-conductive portion, such as a rubber plug or a ceramic plug, to seal at least one end of the transparent bending tube 10˜10f by tight fitting, press fitting or adhesive bonding. Moreover, the transparent bending tube 10˜10f of the present invention is preferably made of a glass material. Any other material or compound material (for example, silicon and the like) similar to glass also falls within the scope of the present invention.
With further reference to
With reference to
As known from the foregoing description, the flexible LED strip 20 having the LEDs 22 mounted thereon is mounted in and extends throughout the transparent bending tube 10 with various shapes to form the bending LED tube of the present invention. If the LEDs 22 are sequentially mounted on the transparent bending tube 10 at an equal interval, the LEDs 22 can be uniformly allocated in the transparent bending tube 10. Moreover, because the LEDs 22 are adjacent to the wall of the transparent bending tube 10, lumen value can be raised and the heats generated by the LEDs 22 can be dissipated out through the wall of the transparent bending tube 10 to avoid high temperature resulting from accumulation of the heat.
Even though numerous characteristics and advantages of the present invention have been set forth in the foregoing description, together with details of the structure and function of the invention, the disclosure is illustrative only. Changes may be made in detail, especially in matters of shape, size, and arrangement of parts within the principles of the invention to the full extent indicated by the broad general meaning of the terms in which the appended claims are expressed.
Number | Date | Country | Kind |
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98216183 U | Sep 2009 | TW | national |
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Number | Date | Country | |
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20110050073 A1 | Mar 2011 | US |