Embodiments of the present disclosure relate to LED lamps, and especially to simple structured LED lamps without heat sinks.
In recent years, LED lamps have been developing rapidly due to many advantages such as high energy efficiency, long service life, compact size, and environmental friendliness. An era of replacing fluorescent lamps with LED lamps has come. The LED lamp is characterized by high quality, durability, and energy saving. Its advantages, such as a wide adjustment range of projection angle, high temperature resistance, moisture proofing, water proofing and anti-creep, make it a mainstream in the lighting field, while replacing the conventional fluorescent lamps.
The conventional LED lamp mainly includes a lamp base, a lamp base fitting, a lamp housing, an LED driving power source, a circuit board assembled with LED chips, a circuit board clamp, and a heat sink, wherein the lamp base, the lamp base fitting and the lamp housing are connected to each other to form an external structure of the LED lamp. The LED driving power source, the circuit board assembled with the LED chips, the circuit board clamp, and the heat sink are connected to each other to form an internal structure of the LED lamp. The circuit board clamp is configured to clamp the circuit board and fix the LED driving power source and the heat sink. Meanwhile, the internal structure of the LED lamp matches and is fixed in the external structure of the LED lamp. The LED driving power source is configured to supply power to the LED chips, and the heat sink is configured to dissipate heat from the LED chips.
Because the heat-sinking capacity of the conventional LED chip is limited, the heat sink is an indispensable device to avoid impacts on a lifespan and stability of the LED chip which is caused by long-term use in a high-temperature environment. However, the heat sink is bulky and heavy, which will affect the overall design and luminescence of the LED lamp and greatly increase the manufacturing and transportation costs.
There is also a conventional method for solving the heat dissipation problem of the LED lamp. The method comprises filling the LED lamp with at least one of hydrogen gas, helium gas, and nitrogen gas, whereby heat generated by the LED chip is conducted and radiated to the gas in the LED lamp. Therefore, the heat generated by the light emitting module can be efficiently conducted to the housing via the gas and dissipated to the outside of the lamp. However, the LED lamp that needs to be inflated requires a complicated manufacturing process, a good impermeability and a high manufacturing cost.
Therefore, it is desirable to provide new LED lamps without heat sinks and gas therein for dissipation.
A LED lamp comprises a base, an envelope and a printed circuit board for mounting a plurality of LED chips. The envelope has a bottom end coupled with the base. The envelope defines an interior between the base and the envelope. The printed circuit board is disposed in the interior. The printed circuit board comprises a hollow structure. The LED lamp further comprises a supporting member for supporting the printed circuit board. The supporting member has one end assembled in the base and the other end coupled with the printed circuit board. One end of the printed circuit board extends into the base.
These and other features, aspects, and advantages of the present disclosure will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:
Unless defined otherwise, technical and scientific terms used herein have the same meaning as is commonly understood by one of ordinary skill in the art to which the present disclosure belongs. The terms “first”, “second”, and the like, as used herein do not denote any order, quantity, or importance, but rather are used to distinguish one element from another. Also, the terms “a” and “an” do not denote a limitation of quantity, but rather denote the presence of at least one of the referenced items. The approximate language used in this paper can be used for quantitative expressions, indicating that a certain amount of variation can be allowed without changing basic functions. Therefore, numerical values modified by languages such as “about” and “around” are not limited to the exact numerical value itself. Similarly, the terms “a” and “an” do not denote a limitation of quantity, but rather denote the presence of at least one of the referenced items. The use of “comprising” or “having” variations thereof herein means that the element or object preceding “comprising” or “having” encompasses any element or article listed after “comprising” or “having” and its equivalence, and does not exclude other elements or objects. The terms “connecting”, “connected”, “coupled” and the like are not limited to physical or mechanical connections, but may include direct or indirect electrical connections, or include thermal connections, thermally conductive connections, heat transfer connections and so on.
The base 110 is a standardized threaded part in some embodiments of the present disclosure. The base 110 defines an internal thread 111 configured to mount and fix the supporting member 160.
The envelope 120 has a hollow structure. In some embodiments of the present disclosure, the envelope 120 has a same shape as a conventional incandescent lamp, which comprises a substantially spherical top portion 121 and a bottom portion 122 under the top portion and substantially in a shape of hollow cylinder. The envelope 120 has an overall shape of sphere that expands from the bottom portion 122. The bottom portion 122 of the envelope 120 is connected to the base 110. The envelope defines an interior 170 between the base 110 and the envelope 120 and configured to receive the printed circuit board 130. The envelope 120 may be made of a transparent material, so that light emitted by the LED chip 150 can be transmitted to the outside of the LED lamp 100. In some embodiments of the present disclosure, the base 120 is made of a transparent plastic by simple manufacturing process, and the base is not easy to break. In addition, the envelope 120 may also be made of glass or transparent ceramic.
Referring to
In some embodiments of the present disclosure, the printed circuit board 130 is a flexible circuit board comprising a hollow structure. It may comprise a hollowed polyhedron, or a hollowed cylinder, or other annular structures. Referring to
When assembling, the printed circuit board 130 integrated with the driver circuit 140 and the plurality of LED chips 150 is firstly mounted on the supporting member 160. The printed circuit board 130 is retained between the supporting portion 162 and the latch portions 163 of the supporting member 160, and the latch portions 163 of the supporting member 160 is retained in the holes 131 of the printed circuit board 130. Then, the supporting member 160 assembled with the printed circuit board 130 is installed in the base 110, and the supporting member 160 is fixed in the base 110 by matching the base thread 164 with the internal thread 111 of the base 110. Finally, the envelope 120 is mounted on the base 110, and the envelope 120 and the base 110 are packaged together with glue. After the assembling, one end of the hollow printed circuit board 130 is mounted and fixed on the supporting member 160 and extends into the base 110, and the other end is suspended in the interior 170 of the envelope 120. In this way, the printed circuit board 130 of the LED lamp 100 can have a larger mounting area than a conventional printed circuit board, and the LED chips 150 can be distributed on the printed circuit board 130 in a more dispersed way. Therefore, the LED lamp 100 has a better self-heat-dissipation effect, and there is no need to additionally provide a separate heat sink. Meanwhile, the hollow printed circuit board 130 is vertically mounted and fixed on the supporting member 160 along the direction of the central axis of the base 110 and the envelope 120, so that the LED lamp 100 has a better lighting effect.
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When assembling, the driving board 241 is firstly installed via the guiding portion 268 of the supporting member 260 from bottom to top, so that the upper half of the driving board 241 is retained between the internal holding portions 2632 of the supporting member 260. Meanwhile, the driving board 241 is fixed to the supporting member 260 by matching the slots 243 of the driving board 241 with the protrusions 266 of the supporting member 260. The lower half of the driving board 241 is received in the guiding portion 268 of the supporting member 260. Then, the printed circuit board 230 is installed from top to bottom, and the printed circuit board 230 is retained between the external holding portions 2631 and the internal holding portions 2632 of the holding portions 263. Meanwhile, the upper half of the driving board 241 can support the printed circuit board 230 to prevent the printed circuit board 230 from shaking. Furthermore, the projection portions 233 of the printed circuit board 230 is received in the positioning holes 265 of the supporting member 260, and protrudes beyond the bottom of the floor portion 262. Then, the printed circuit board 230 is fixed to the supporting member 260 by bending the part of the projection portions 233 protruding beyond the bottom. Then, the supporting member 260 mounted with the printed circuit board 230 and the driving board 241 is installed in the base 210, and the base thread 264 of the supporting member 260 engages with the internal thread 211 of the base 210 to fix the supporting member 260 in the base 210. Finally, the envelope 220 is retained in the receiving portion 267 of the supporting member 260, and the envelope 220 is fixed to the supporting member 260 by sealing with glue. In a second embodiment, the printed circuit board 230 may firstly be mounted on the supporting member 260, and then the driver circuit board 240 may be installed and fixed on the supporting member 260 from bottom to top. The order of mounting the printed circuit board 230 and the driver circuit 240 to the supporting member 260 is not limited.
In an embodiment of the present disclosure, the printed circuit board 330 is substantially in a shape of a hollow hexahedron comprising six rectangular flat mounting sides 332. The plurality of LED chips 350 are evenly distributed on the upper half of the mounting sides 332, and the driver circuit 340 is integrated on the lower half of one mounting side 332. The LED chips 350 and the driver circuit 340 are integrated on the printed circuit board 330, which can simplify the structure of the LED lamp 300 and reduce a number of parts of the LED lamp 300, thereby reducing assembling steps of the LED lamp.
Referring to
When assembling, the printed circuit board 330 integrated with the plurality of LED chips 350 and the driver circuit 340 can be firstly accommodated and fixed in the mounting slot 362 of the supporting member 360. Then, the supporting member 360 installed with the circuit printed board 330 is installed and fixed in the base 310. Then, the bottom portion 322 of the envelope 320 is installed in the base 310 and finally fixed and sealed with glue.
In the embodiment of the present disclosure, the hollow polyhedral printed circuit board 130, 230, 330 is supported and fixed by the supporting member 160, 260, 360. One end of the printed circuit board 130, 230, 330 is fixed on the supporting member 160, 260, 360 and extends into the base 110, 210, 310, and the other end of the printed circuit board 130, 230, 330 is suspended in the envelope 120, 220, 320. Thus, the area of mounting sides of the printed circuit board 130, 230, 330 is increased compared to a conventional printed circuit board. The plurality of LED chips 150, 250, 350 can be dispersedly provided on the printed circuit board 130, 230, 330, which enhances the self-cooling effect of the LED lamp 100, 200, 300. Meanwhile, the structure of the LED lamp 100, 200, 300 is also simplified. No additional heat sink is needed and no gas is required to be supplied to the LED lamp for heat dissipation. In particular, the supporting member 160, 260, 360 made of the thermally conductive material engages with the base 110, 210, 310, and the heat generated by the printed circuit board 130, 230, 330 can be conducted out of the LED lamp via the base 110, 210, 310, which further enhances the self-cooling effect of the LED lamp. Meanwhile, the number of LED lamp parts is reduced, and the production process of the LED lamp is simplified, thereby reducing the production cost of the LED lamp. Moreover, in the present disclosure, the driver circuit 140, 340 may be integrally disposed on the printed circuit board 130, 230, or the driver circuit 240 is fixed and retained by the supporting member 260, which also simplifies the structure of the LED lamp, thus reducing the manufacturing cost of the LED lamp. Meanwhile, the hollow polyhedral printed circuit board can increase the mounting area of the printed circuit board, and enable the LED chips to be installed more discretely, which is beneficial to the heat dissipation of the LED lamp. Meanwhile, the luminous effect of the LED lamp is optimized. In addition, the supporting member 160, 260, 360 is integrally formed of a heat-conducting material, which also simplifies the manufacture and assembly process of the LED lamp.
The specification uses detailed embodiments to describe the present disclosure, including the best mode, and can help any person skilled in the art of the disclosure to perform experimental operations. These operations include using any device and system and using any specific method. The scope of the disclosure is defined by the claims, and may include other examples that occur in the technical field. Such other examples are intended to be within the scope of the claims of the disclosure if they are not structurally different from the literal language of the claims or they have equivalent structures as described in the claims.
Number | Date | Country | Kind |
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201710447399.1 | Jun 2017 | CN | national |