This application claims the priority benefit of Taiwan Patent Application No. 100120417, filed on Jun. 10, 2011. The entirety of the above-identified patent application is hereby incorporated by reference and made a part of this specification.
1. Technical Field
The present invention relates to light bulbs and, more particularly, to a type of light emitting diode bulbs.
2. Description of Related Art
Along with the development of light emitting diodes (LEDs) the use of LEDs in light bulbs has become prevalent, and the low power consumption of LEDs meets the trend of environmental protection. LEDs generally have the light source output characteristics of point light source, high brightness and narrow light beam. The mechanical characteristics and reliability of LEDs are also different from those of traditional luminaires. Accordingly, pertinent testing standards with respect to solid-state lighting are being developed in various countries for a variety of applications, including roadside illumination, outdoor illumination, indoor illumination, etc.
In a typical LED bulb, an LED lamp board and a driving circuit are electrically coupled through a connector. However, under such configuration noise tends to increase as the length of the wire increases. Besides, the height of the connector on the LED lamp board may result in light being covered. Moreover, the LED lamp board and a heat sink are typically affixed together by one or more screws. This nevertheless increases the time of assembly. Additionally, as the driving circuit and a screw thread are usually electrically coupled together via wires, the time of assembly would be further increased.
An objective of the present invention is to provide an LED bulb that can be assembled relatively more easily with shorter assembly time and lower cost of assembly.
According to one aspect, an LED bulb may comprise a heat sink, an insulator cover, a light emitting device package, a plurality of conductive terminals, a driving circuit, a holder, a screw head and an electrode. The heat sink may comprise a component receiving surface, a plurality of fastening through holes, and a plurality of positioning through holes. The fastening through holes and the positioning through holes may be disposed on the component receiving surface. The insulator cover may be disposed on the heat sink and may include an opening. The insulator cover may comprise a plurality of hooking parts and a plurality of terminal receptacles. The hooking parts and the terminal receptacles may protrude from a surface of the insulator cover. Each of at least some of the hooking parts may be configured to be engaged with a respective one of the fastening through holes and each of at least some of the terminal receptacles may be configured to pass through a respective one of the positioning through holes to be engaged with the respective positioning through hole such that the insulator cover is affixed to the heat sink. Each of at least some of the terminal receptacles respectively having a terminal receptacle through hole. The light emitting device package may be disposed on the component receiving surface of the heat sink and may include a plurality of driving electrodes. The light emitting device package may be disposed between the insulator cover and the heat sink. The light emitting device package may be affixed to the insulator cover with the opening of the insulator cover exposing a portion of the light emitting device package. The plurality of conductive terminals may be respectively disposed in the terminal receptacle through holes of the terminal receptacles. The conductive terminals may extend outwardly and in physical contact with the driving electrodes of the light emitting device package. The driving circuit may output a current signal to drive the light emitting device package. The driving circuit may comprise a plurality of upper conductive rods and a plurality of lower conductive rods. The upper conductive rods may be in physical contact with the conductive terminals. The holder may comprise a holding protrusion. The holder may be configured to be assembled to the heat sink via the holding protrusion. The screw thread may be coupled to the holder and may comprise a screw thread through hole. The screw thread may be electrically connected to a first one of the lower conductive rods. The electrode may be disposed in the screw thread through hole and electrically connected to a second one of the lower conductive rods.
In one embodiment, the LED bulb may further comprise a lens disposed on and coupled to the heat sink. The lens may at least partially or totally cover the light emitting device package and the insulator cover.
In one embodiment, the LED bulb may further comprise an insulation box disposed in the heat sink and containing the driving circuit therein. The insulation box may comprise a plurality of holes. The upper conductive rods and the lower conductive rods may traverse through the holes to be exposed outside of the insulation box.
In one embodiment, each of at least some of the conductive terminals respectively may comprise a terminal body and an extension electrode. The terminal body may comprise a terminal through hole and a plurality of hooking parts in the terminal through hole. The hooking parts may protrude in a direction away from the respective terminal through hole.
In one embodiment, the extension electrodes of the conductive terminals may extend outwardly and physically contact the driving electrodes of the light emitting device package.
In one embodiment, a sidewall of the terminal receptacle through hole of each of at least some of the terminal receptacles may respectively comprise a protrusion. The hooking parts of the terminal bodies and the protrusions of the terminal receptacles may be engaged together.
In one embodiment, each of at least some of the conductive terminals may comprise a terminal bending part in the respective terminal through hole that is electrically connected with at least some of the upper conductive rods.
In one embodiment, the light emitting device package may comprise a first surface and a second surface opposite to the first surface. The second surface may be connected to the component receiving surface and in physical contact with the heat sink. The driving electrodes may be disposed on the first surface.
In one embodiment, the heat sink may comprise a plurality of heat dissipation fins disposed around the heat sink.
According to another aspect, an LED bulb may comprise a heat sink, a light emitting device package, a driving circuit, a holder, a plurality of conductive terminals, a screw thread and an electrode. The heat sink may include a component receiving surface. The light emitting device package may be disposed on the component receiving surface and may comprise a plurality of driving electrodes. The driving circuit may output a current signal to drive the light emitting device package. The driving circuit may comprise a plurality of upper conductive rods and a plurality of lower conductive rods. The upper conductive rods may be electrically connected with the driving electrodes. The holder may comprise a holding protrusion and a plurality of terminal receptacles. Each of at least some of the terminal receptacles may comprise a respective terminal receptacle through hole. At least some of the lower conductive rods may be disposed in the terminal receptacle through holes. The plurality of conductive terminals may be respectively disposed in the terminal receptacle through holes of the terminal receptacles and in physical contact with the lower conductive rods. The screw thread may be coupled to the holder and may include a screw thread through hole. The electrode may be disposed in the screw thread through hole of the screw thread. The conductive terminals may extend outwardly and be in physical contact with the screw thread and the electrode such that each of the screw thread and the electrode is electrically connected with a respective one of the lower conductive rods.
In one embodiment, the LED bulb may further comprise a lens disposed on and coupled to the heat sink. The lens may at least partially or totally cover the light emitting device package.
In one embodiment, the LED bulb may further comprise an insulation box disposed in the heat sink and containing the driving circuit therein. The insulation box may comprise a plurality of holes, the upper conductive rods and the lower conductive rods traversing through the holes to be exposed outside of the insulation box.
In one embodiment, each of at least some of the conductive terminals respectively may comprise a terminal body and an extension electrode. The terminal body may comprise a terminal through hole and a plurality of hooking parts in the terminal through hole. The hooking parts may protrude in a direction away from the respective terminal through hole.
In one embodiment, the extension electrodes of the conductive terminals may extend outwardly and physically contact the screw thread and the electrode.
In one embodiment, a sidewall of the terminal receptacle through hole of each of at least some of the terminal receptacles may respectively comprise a protrusion. The hooking parts of the terminal bodies and the protrusions of the terminal receptacles may be engaged together.
In one embodiment, each of at least some of the conductive terminals may comprise a terminal bending part in the respective terminal through hole that is bent toward the respective terminal through hole and electrically connected with at least some of the lower conductive rods.
In one embodiment, the light emitting device package may comprise a first surface and a second surface opposite to the first surface. The second surface may be connected to the component receiving surface and in physical contact with the heat sink. The driving electrodes may be disposed on the first surface.
In one embodiment, the heat sink may comprise a plurality of heat dissipation fins disposed around the heat sink.
According to still another aspect, an LED bulb may comprise a heat sink, an insulator cover, a light emitting device package, a plurality of conductive terminals, a driving circuit, a holder, a plurality of second conductive terminals, a screw thread and an electrode. The heat sink may comprise a component receiving surface, a plurality of fastening through holes, and a plurality of positioning through holes. The fastening through holes and the positioning through holes may be disposed on the component receiving surface. The insulator cover may be disposed on the heat sink and may include an opening. The insulator cover may comprise a plurality of first hooking parts and a plurality of first terminal receptacles. The first hooking parts and the first terminal receptacles may protrude from a surface of the insulator cover. Each of at least some of the first hooking parts may be configured to be engaged with a respective one of the fastening through holes and each of at least some of the first terminal receptacles may be configured to pass through a respective one of the positioning through holes to be engaged with the respective positioning through hole such that the insulator cover is affixed to the heat sink. Each of at least some of the first terminal receptacles respectively may include a first terminal receptacle through hole. The light emitting device package may be disposed on the component receiving surface of the heat sink and may include a plurality of driving electrodes. The light emitting device package may be disposed between the insulator cover and the heat sink. The light emitting device package may be affixed to the insulator cover with the opening of the insulator cover exposing a portion of the light emitting device package. The plurality of first conductive terminals may be respectively disposed in the first terminal receptacle through holes of the first terminal receptacles. The first conductive terminals may extend outwardly and may be in physical contact with the driving electrodes of the light emitting device package. The driving circuit may comprise a plurality of upper conductive rods and a plurality of lower conductive rods. The upper conductive rods may be in physical contact with the first conductive terminals. The holder may comprise a holding protrusion and a plurality of second terminal receptacles. The holder may be configured to be assembled to the heat sink via the holding protrusion. Each of at least some of the second terminal receptacles may respectively comprise a second terminal receptacle through hole. The lower conductive rods may be disposed in the second terminal receptacle through holes. The plurality of second conductive terminals may be disposed in the second terminal receptacle through holes of the second terminal receptacles and in physical contact with the lower conductive rods. The screw thread may be coupled to the holder and may comprise a screw thread through hole. The screw thread may be electrically connected to a first one of the lower conductive rods. The electrode may be disposed in the screw thread through hole and electrically connected to a second one of the lower conductive rods. The second conductive terminals may extend outwardly and physically contact the screw thread and the electrode such that the screw thread and the electrode are electrically connected with the first one of the lower conductive rods and the second one of the lower conductive rods, respectively.
In one embodiment, the LED bulb may further comprise a lens disposed on and coupled to the heat sink. The lens may at least partially or totally cover the light emitting device package and the insulator cover.
In view of the above, in an LED bulb according to the present disclosure, the insulator cover and the heat sink are affixed together using a hooking method. Accordingly, the light emitting device package, which is disposed between the insulator cover and the heat sink, can be affixed thereto at the same time. That is, hooks may be directly used for assembling to the heat sink to reduce the cost and time associated with using screws to do the same. This advantageously enhances electrical insulation. Moreover, the first conductive terminals and the second conductive terminals may be respectively affixed to the insulator cover and the holder using the hooking method. This design reduces not only the noise associated with traditional connection by wires but also the time it takes to render electrical connection (e.g., wiring) as well as the light being covered by connection terminals. Furthermore, as the LED bulb may be assembled together using hooks, engagement or other fastening methods without the use of screws, potential hazards to a user when disassembling the LED bulb may be avoided.
Detailed description of various embodiments are provided below, with reference to the attached figures, to promote better understanding of the characteristics and benefits of the various embodiments of the present disclosure.
The following description pertains to the structure and benefits of an embodiment of the LED bulb 1000.
In addition, the light emitting device package 1300 is disposed on the component receiving surface S1 and between the insulator cover 1200 and the heat sink 1100. As shown in
Furthermore, the extension electrodes 1440 of the first conductive terminals 1400 respectively extend outwardly and physically contact the driving electrodes 1320 of the light emitting device package 1300, which is disposed on the heat sink 1100. In one embodiment, in the insulator cover 1200, a sidewall of the terminal receptacle through hole 1242 of each of at least some of the terminal receptacles 1240 respectively comprises a protrusion 1244. When the first conductive terminals 1400 are respectively disposed in the terminal receptacle through holes 1242 of the terminal receptacles 1240, the hooking parts 1424 of the terminal bodies 1420 and the protrusions 1244 of the terminal receptacles 1240 are engaged or otherwise fastened together, as shown in
In one embodiment, each of at least some of the second conductive terminals 1700 respectively comprises a terminal body 1720 and an extension electrode 1740. Each terminal body 1720 comprises a terminal through hole 1722 and a plurality of terminal hooking parts 1724 in the respective terminal through hole 1722. The terminal hooking parts 1724 protrude in a direction away from the respective terminal through hole 1722, as shown in
Similarly, each of at least some of the terminal bodies 1720 of the second conductive terminals 1700 respectively comprises a terminal bending part 1426 that is bent toward the respective terminal through hole 1722, as shown in
It can be seen from the above description that components of an LED bulb 1000 according to the present disclosure may be assembled together using hooks, engagement or other fastening methods. Accordingly, as there is no need of screws for assembly, potential hazards to a user when disassembling the LED bulb 1000 may be avoided. Additionally, by utilizing the first conductive terminals 1400 and the second conductive terminals 1700 in the design of the LED bulb 1000 according to the present disclosure, inconvenience associated with using screws for assembly can be minimized as components can be hooked or otherwise engaged or fastened to the insulator cover 1200 and the holder 1600. Moreover, noise signals traditionally associated with the usage of wiring to connect the terminals, the time it takes to connect the wiring and light blocking effect due to wiring can be reduced. Furthermore, as the insulator cover 1200 of the LED bulb 1000 in an embodiment is affixed to the heat sink 1100 using a hooking method, the light emitting device package 1300, which is disposed between the insulator cover 1200 and the heat sink 1100, can also be affixed thereto at the same time. That is, hooks may be utilized for assembly to the heat sink 1100. This design reduces the time and cost of assembly compared to the case of assembly using screws, in addition to enhancing the electrical insulation thereof.
In one embodiment, the above-described LED bulb 1000 further comprises a lens 2100. The lens 2100 is disposed on the heat sink 1100 and physically in physical contact with or coupled to the heat sink 1100. The lens 2100 may at least partially or totally cover the light emitting device package 1300 and the insulator cover 1200, as shown in
In summary, an LED bulb in accordance with the present disclosure offers at least a number of advantages. Firstly, the insulator cover and the heat sink are affixed together via hooking. Consequently, the light emitting device package, which is disposed between the insulator cover and the heat sink can be affixed thereto at the same time. That is, assembly to the heat sink using hooks not only can minimize the cost and time associated with assembling using screws but also can enhance the electrical insulation thereof. Secondly, the first conductive terminals and the second conductive terminals may be respectively affixed to the insulator cover and the holder via engagement or other fastening method such as hooking. This design minimizes inconvenience associated with using screws for assembly as components can be hooked or otherwise engaged or fastened to the insulator cover 1200 and the holder 1600. Moreover, noise signals traditionally associated with the usage of wiring to connect the terminals, the time it takes to connect the wiring and light blocking effect due to wiring can be reduced. Moreover, as components of the LED bulb can be assembled together using hooks, engagement or other fastening methods, there is no need of screws for assembly, potential hazards to a user when disassembling the LED bulb 1000 may be avoided.
A number of embodiments of the present invention are described herein. However, as those skilled in the art would appreciate, the scope of the present invention is not and cannot be limited to the disclosed embodiments. More specifically, one ordinarily skilled in the art may make various deviations and improvements based on the disclosed embodiments, and such deviations and improvements are still within the scope of the present invention. Accordingly, the scope of protection of a patent issued from the present disclosure is determined by the claims as follows.
Number | Date | Country | Kind |
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100120417 | Jun 2011 | TW | national |