Patent Document

BACKGROUND OF THE INVENTION 
   1. Field of the Invention 
   The invention generally relates to white light emitting diodes, and more particularly to a white light emitting diode using phosphor excitation with the phosphor separated from the die. 
   2. The Prior Arts 
   One of the more common and mature white light emitting diode (LED) technologies is to coat or fill a yellow phosphor on or around a blue LED die. The yellow phosphor is excited by radiation from the blue LED and emits yellow lights. The blue lights emitted by the LED are then mixed with the complimentary yellow lights from the phosphor to generate two-wavelength white lights. However, with this technique, it is difficult to control the proportions of the participated blue and yellow lights and, as a result; the generated white lights usually have a non-uniform light color, too high a color temperature, and too low a color rendering index. 
   In another similar technology, red, green, and blue (RGB) phosphors are coated or filled around an ultra-violet (UV) LED. The phosphors are excited by the UV lights emitted from the UV LED, and the generated RGB lights are combined to form white lights. However, this technique still suffers the difficultly in controlling the proportions of RGB phosphors, although the UV lights themselves do not participate in forming the white lights. As a result, the color uniformity, color temperature, and color rendering problems are not satisfactorily resolved. 
   The foregoing techniques have another disadvantage. The phosphors coated on or filled around the LED die would be deteriorated due to the heat generated from the LED die itself, which would further compromise the performances of the LED including its color, brightness, and lifetime. 
   To solve the problem of uniformity, several solutions have already been disclosed. For example, U.S. Pat. Nos. 5,962,971 and 5,813,753 disclose that a filter was included in the LED package to improve the uniformity of the mixed white light. Taiwan Patent No. 569,479 discloses that a blue LED or an UV LED die was arranged in a fluorescent glue, and interposed between dielectric omni-directional reflectors so that the blue lights or UV lights are reflected repeatedly in all directions to excite the phosphors as much as possible, thereby consuming the energy of blue lights or UV lights and enhancing the white light conversion efficiency. However, the above-mentioned techniques could still not solve the phosphors&#39; deterioration problem from direct contact with the LED die. Furthermore, the arrangement of the filter or the reflectors would also add to the process complexity, resulting in high manufacturing cost and low yield. 
   In view of the phosphor deterioration problem, Taiwan Patent No. M246,528 provides a white LED lamp, which can prevent the phosphors from heat deterioration by separating the phosphors from the LED die. However, this technique is designed for a lamp including many blue LEDs, but not for an individual LED. 
   SUMMARY OF THE INVENTION 
   A main objective of the present invention is to provide a white LED, which separates the excitable entities (i.e. phosphors) from the light source (i.e. a blue or a UV LED die) so that the phosphors do not directly contact with the LED die to avoid the heat deterioration problem, thereby increasing the lifetime of the white LED of the present invention. 
   Another main objective of the present invention is to provide a white LED, which utilizes a simple reflective structure through which the phosphors could be excited more than once by the blue lights or UV lights emitted from the blue or UV LED die, thereby increasing their reaction. As a result, the white light uniformity, color temperature, and color rendering problems of the LED could be effectively resolved. 
   To achieve the foregoing objectives, the present invention provides a reflective mirror arranged on the light emitting path of the blue or the UV LED die at an appropriate inclined angle, which could reflect and redirect the blue lights or UV lights to be emitted out from an emitting plane of the LED. The phosphors are coated on the reflective mirror, the emitting plane of the LED, or both so as to achieve the separation of the phosphors and the LED die. In addition, if the phosphors are coated on both the reflective mirror and the emitting plane, the phosphor coated on the reflective mirror is firstly excited by the blue lights or UV lights emitted by the die to generate white lights, and the white lights together with the remaining blue lights or UV lights whose energy is not yet consumed are reflected by the reflective mirror toward the emitting plane. These remaining blue lights or UV lights get a second chance to react with the phosphors coated on the emitting plane. As a result, a uniform light color, a low color temperature, and a good color rendering index could be achieved. 
   A more complete appreciation of the invention and many of the attendant advantages thereof will be readily attained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings. However, it is understood that these embodiments with the accompanying drawings are intended only as illustrative examples and the invention is not to be limited thereto. The invention is intended to be limited only by the scope of the appended claims. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIGS. 1   a  and  1   b  show a cross sectional side view, and a front view of the white LED according to the first embodiment of the present invention, respectively; 
       FIG. 1   c  shows a cross sectional side view of the white LED according to the second embodiment of the present invention; 
       FIG. 1   d  shows a cross sectional side view of the white LED according to the third embodiment of the present invention; and 
       FIG. 2  shows a cross sectional side view of the white LED according to the fourth embodiment of the present invention. 
   

   DETAILED DESCRIPTION OF THE INVENTION 
     FIGS. 1   a  and  1   b  show a cross sectional side view, and a front view of the white LED according to the first embodiment of the present invention, respectively. As shown in  FIG. 1   a  and  FIG. 1   b , a conventional blue or UV LED die  10  is arranged on a circuit board  20  having a positive electrode  21  and a negative electrode  22 . The LED die  10  is driven to emit blue lights or UV lights when an external voltage is applied onto the positive electrode  21  and the negative electrode  22 . 
   A conventional LED is usually encapsulated in a transparent, cylindrical bell cladding made of epoxy to protect the LED die  10  and the circuit board  20  therein. Meanwhile, the bell cladding also provides light convergence similar to a convex lens. Instead of using a bell cladding, a cylindrical cladding  30  having an inclined plane  31  on the top, as if it is obtained from cutting a right cylinder in half at an inclined angle, is used in this embodiment. The included angle φ between the inclined plane  31  and the circuit board  20  is set between 15° and 75°, preferably between 30° and 60°. It is noted that the bottom edge of the inclined plane  31  is intersecting the upper surface of the circuit board  20 , as shown in  FIG. 1   a . However, the bottom edge of the inclined plane  31  could be arranged at an appropriate distance from the upper surface of the circuit board  20  in another embodiment. 
   A metal film made from gold (Au), aluminum (Al), nickel (Ni), titanium (Ti), or chromium (Cr) is formed on the inner surface of the inclined plane  31  by electroplating or other processes such as sputtering, chemical vapor deposition, etc., which functions as a reflective mirror  40 . In another embodiment, the reflective mirror  40  could also be a Bragg reflector made from dielectric materials. The metal film reflective mirror or the Bragg reflector is well known technique to those skilled in the related art. 
   It is particularly pointed out that the inclined plane  31  of the epoxy cladding  30  provides the place for the configuration of the reflective mirror  40  in the present invention. The advantage of doing so is that the structure is simple. However, in another embodiment of the present invention, the reflective mirror  40  could be configured at different places inside the epoxy cladding  30 , and the shape of the epoxy cladding  30  is not limited to the one used by the present embodiment. 
   The phosphors  50  are coated on the reflective mirror  40 , and the phosphors  50  are selected such that they could be excited to produce complementary lights to those emitted from the LED die  10  to form white light. For example, if the LED die  10  is a blue LED die, the phosphors  50  are YAG (yttrium aluminum garnet)-based yellow phosphors. If the LED die  10  is an UV LED die, the phosphors  50  are RGB tricolor phosphors made from europium-doped barium aluminum oxide. As to the coating of the phosphors  50 , any suitable conventional process can be used, such as spin coating, sputtering, and printing. 
   After an appropriate voltage is applied onto the electrodes  21  and  22 , the LED die  10  emits blue lights or UV lights proceeding toward the reflective mirror  40 . It is noted that the sum of the incident angle for the blue lights or UV lights to the reflective mirror  40  and the included angle φ is 90°. The reflective mirror  40  is arranged so that the incident angle of the blue lights or UV lights is set between 15° and 75°, preferably between 30° and 60°. The phosphors  50  coated on the surface of the reflective mirror  40  are excited by the blue lights or UV lights and the produced lights are mixed with the blue lights or UV lights to form white lights. Subsequently, the generated white lights are reflected by the reflective mirror  40  and proceed toward the emitting plane  32 . 
   In this embodiment, the emitting plane  32  is a convex plane which provides a convergence effect similar to a convex lens because the epoxy cladding  30  has a cylindrical shape. In another embodiment, the epoxy cladding  30  could be a cylinder having semicircle cross section, and the emitting plane  32  would be a planar plane. In other words, the geometry of the emitting plane  32  of the present invention is not limited to a specific shape. 
   In this embodiment, a simple reflective structure in which the phosphors and the LED die are separately arranged, thereby preventing the phosphors from heat deterioration and avoiding the problem of reduced lifetime of the LED. Based on the same concept, in another embodiment, the phosphors are coated on the inner surface of the emitting plane  32 , but not on the reflective mirror  40 , as shown in  FIG. 1   c . Similarly, the phosphors  55  coated on the inner surface of the emitting plane  32  would produce complimentary lights when excited to the radiation of the LED die  10 . In the second embodiment, the blue lights or UV lights emitted by the LED die  10  proceeds toward the emitting plane  32  after being reflected by the reflective mirror  40 . The phosphor  55  is then excited by the reflected blue lights or UV lights, and the produced lights are mixed with the blue lights or UV lights to form white lights. The generated white lights then emits through the emitting plane  32 . 
   In the foregoing first and second embodiments, the generated white lights may still include blue lights or UV lights whose energy is not consumed completely. In order to further improve the uniformity of light color, a third embodiment that combines the first embodiment with the second embodiment is provided, as shown in  FIG. 1   d . In the third embodiment, the phosphors  50  and  55  are coated on the inner surfaces of the reflective mirror  40  and the emitting plane  32 , respectively. The phosphor  55  coated on the emitting plane  32  can be of the same or different material from the phosphor  50  coated on the reflective mirror  40 . The main point of the third embodiment is that the blue lights or UV lights whose energy is not consumed after reacting with the phosphor  50  could react with the phosphor  55 , which therefore improves the uniformity of the white lights and solves the problem of high color temperature. In addition, regardless of the shape of the emitting plane  32 , it is important that the emitting plane  32  is perpendicular (or is very close to perpendicular) to the lights (white lights, blue lights, or UV lights) reflected by the reflective mirror  40  so that they can fully react with the phosphor  55 . 
   In summary, a simple reflective structure is adopted in the third embodiment so that the blue light or the UV light emitted by the LED die could react with the phosphors twice. As a result, the generated white lights are more uniform, and the problems of the color temperature and the color rendering could be avoided. On the other hand, the present invention can provide two or more reflective mirrors, part of or all of which are coated with phosphors, and the phosphors can be excited twice or more times by the reflections of these reflective mirrors. 
   According to the same concepts in the above embodiments, the fourth embodiment is illustrated in  FIG. 2 . A beam splitter  60  is arranged on the light emitting path of the LED die  10  at an inclined angle which is similar to that of the reflective mirror  40  in the above embodiments. A beam splitter  60  transmits part of the blue lights or the UV lights emitted by the LED die  10 , and reflects the rest. 
   In the fourth embodiment, the epoxy cladding  70  could have a cylindrical shape or a cubic shape. The reflective mirrors  81  and  82  could be arranged on the top surface  71  and the side surface  72  of the epoxy cladding  70 , respectively. The reflective mirrors  81  and  82  work the same way as the reflective mirror  40 . In addition, the phosphors  91  and  92  are respectively coated on the reflective mirrors  81  and  82 , wherein the phosphors  91  or  92  can produce complimentary lights to the radiation of the LED die  10 . The materials or the coating method of the phosphors  91  and  92  can be identical or different. 
   The phosphor  91  coated on the top surface  71  of the reflective mirror  81  would be excited by part of the blue lights or the UV lights passing through the beam splitter  60 . Subsequently, the generated white lights are reflected by the reflective mirror  81  and the beam splitter  60 , and proceeds toward the emitting plane  73 . In the same manner, the phosphor  92  coated on the side surface  72  of the reflective mirror  82  would be excited by part of the blue lights or the UV lights reflected by the beam splitter  60 . Furthermore, the generated white lights are reflected by the reflective mirror  82 , and then pass through the beam splitter  60 , and proceeds toward the emitting plane  73 . 
   In the third embodiment, the phosphors are excited twice by the blue lights or the UV lights. However, in the fourth embodiment, the blue light or the UV light is split into two parts, each of which reacts with the phosphor once. The objectives of these two embodiments are to increase the reaction areas and reaction times between the blue lights or the UV lights and the phosphors in order to enhance the uniformity of the white lights. In the fourth embodiment, the phosphors could be excited twice as well, as illustrated in the third embodiment. In this case, the emitting plane  73  could be coated with phosphors to generate better white lights. 
   It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention. Thus, it is intended that the present invention cover the modifications and the variations of this invention provided they come within the scope of the appended claims and their equivalents.

Technology Category: 5