The present disclosure relates to a LED illumination technical field, and more particularly to a LED filament and a LED bulb with the LED filament.
A light emitting diode (LED) is a solid-state semiconductor device that can transform electrical energy into visible light. A LED is an ideal light source that can take the place of a conventional light source since it contains benefits such as less energy consumption, longer service life and little environmental contamination, applied in various realms.
A conventional LED bulb can include a LED filament, a stem, a transparent lampshade such as a spherical lampshade, and a lamp holder such as a thread lamp holder; the transparent lampshade, the stem and the lamp holder are connected firmly, the stem is disposed in the transparent lampshade and equipped with electrodes that can be connected to the LED filament in order to supply power to the LED filament.
A LED filament includes a copper frame and multiple LED chips disposed on the copper frame. The multiple LED chips can be series connected, parallel connected or series-parallel connected. However, during process of manufacturing a conventional LED bulb, a LED filament mounted on a column can be commonly manual, and an external force is needed in aligning welding, which can easily fail a component caused by the copper frame bend. Moreover, high costs cannot be avoided if power of a single conventional LED filament is increased.
Therefore, aiming at disadvantages in a conventional technique, the disclosure provides a LED filament and a LED bulb with the LED filament.
Specifically, an embodiment of the disclosure provides a LED filament, including: a carrier, LED chips disposed on the carrier, the carrier includes a first lateral section and a second lateral section opposite to the first lateral section, the LED chips are formed on the first lateral section, hardness of the first lateral section is less than that of the second lateral section.
In an embodiment of the disclosure, the carrier includes a substrate, a first adhesive and a second adhesive, the substrate contains a first surface and a second surface opposite to the first surface, the LED chips are disposed on the first surface of the substrate, the first lateral section is formed by the first adhesive covering the first surface and the LED chips, the second lateral section is formed by the second adhesive covering the second surface.
In an embodiment of the disclosure, Shore hardness type A of the first adhesive is less than or equal to 55, Shore hardness type A of the second adhesive is more than or equal to 70, and a difference of the Shore hardness type A of the first adhesive and the Shore hardness type A of the second adhesive is more than or equal to 15.
In an embodiment of the disclosure, a material of the first adhesive is transparent resin, such as epoxy resin, silica gel, methyl silicone resin, phenyl silicone resin, methyl phenyl silicone resin or modified silicone resin.
In an embodiment of the disclosure, a material of the second adhesive is transparent resin, such as epoxy resin, silica gel, methyl silicone resin, phenyl silicone resin, methyl phenyl silicone resin or modified silicone resin.
In an embodiment of the disclosure, fluorescent powders are dispersed in the first adhesive and the second adhesive.
In an embodiment of the disclosure, the substrate is formed by a metal material, transparent ceramic, sapphire or glass.
In an embodiment of the disclosure, through-holes are defined on the substrate.
In an embodiment of the disclosure, the substrate includes a substrate, a first adhesive and a second adhesive, the substrate includes a first bracket and a second bracket connected with the first bracket, the first bracket contains an upper surface away from the second bracket, the second bracket contains a bottom surface away from the first bracket, the LED chips are disposed on the upper surface of the first bracket, the first adhesive covers the upper surface of the first bracket and the LED chips, the first adhesive and the first bracket form the first lateral section, the second adhesive covers the bottom surface of the second bracket, the second adhesive and the second bracket form the second lateral section.
In an embodiment of the disclosure, a thermal conductivity of the first bracket is higher than that of the second bracket.
In an embodiment of the disclosure, brittleness of the first bracket is more than that of the second bracket.
In an embodiment of the disclosure, a thickness of the first bracket is less than that of the second bracket.
In an embodiment of the disclosure, the first bracket and the second bracket are formed by metal materials.
In an embodiment of the disclosure, hardness of a metal material of the first bracket is less than that of the second bracket.
In an embodiment of the disclosure, the first bracket is formed by copper, the second bracket is formed by iron.
In an embodiment of the disclosure, the first bracket and the second bracket are connected by pasting with an adhesive.
In an embodiment of the disclosure, the first bracket and the second bracket are connected by electroplating.
In an embodiment of the disclosure, through-holes penetrating the first bracket and the second bracket are defined on the substrate.
In an embodiment of the disclosure, the first bracket is formed by transparent ceramic or sapphire, the second bracket is formed by glass.
In an embodiment of the disclosure, the first bracket and the second bracket are connected by pasting with an adhesive.
In an embodiment of the disclosure, the first bracket and the second bracket are connected by pasting with an adhesive, sintering, sputtering or electroplating.
The disclosure further provides a LED bulb, including: a lamp holder, a transparent lampshade, a stem and a LED filament, the transparent lampshade and the stem are connected with the lamp holder firmly, the LED filament can be any one of the LED filaments in embodiments above.
In conclusion, according to a LED filament and a LED bulb with the LED filament of the embodiments above, as the hardness of the first lateral section is less than that of the second lateral section, the LED filament above can be designed according to various requirements of structural strength, which can reduce costs without sacrificing structural strength.
In order to clearly illustrate the disclosure, the following figures will be described in detail, the drawings are merely for explanation instead of limitation. Furthermore, the figures are not sketched in scale, the purpose of the drawings is to illustrate structures and processes of corresponding description literally.
Embodiments of the present disclosure are described in detail with reference to the accompanying drawings as follows.
Embodiments of the present disclosure are described in detail with reference to the accompanying drawings as follows to better understand the purpose, property and merits of the disclosure.
Referring to
As the hardness of the first lateral section 122 is less than that of the second lateral section 124, the LED filament 10 above can be designed according to various requirements of structural strength, which can reduce costs without sacrificing structural strength of the LED filament 10.
In the embodiment, the carrier 12 includes a substrate 121, a first adhesive 123 and a second adhesive 125. The substrate 121 contains a first surface 1212 and a second surface 1214 opposite to the first surface 1212. The LED chips 14 are disposed on the first surface 1212 of the substrate 121. The first adhesive 123 covers the first surface 1212 and the LED chips 14, the second adhesive 125 covers the second surface 1214. The first adhesive 123 forms the first lateral section 122, the second adhesive 125 forms the second lateral section 124; in other words, the first lateral section 122 is formed by the first adhesive 123, the second lateral section is formed by the second adhesive 125.
Specifically, in the embodiment, hardness of the first adhesive 123 and that of the second adhesive 125 are measured by a Shore durometer type A, which means measured hardness is Shore hardness type A. Shore hardness type A of the first adhesive 123 can be less than or equal to 55, Shore hardness type A of the second adhesive 125 can be more than or equal to 70. Preferably, a difference of the Shore hardness type A of the first adhesive and the Shore hardness type A of the second adhesive can be more than or equal to 15. In other embodiments of the disclosure, based on the premise that hardness of the first adhesive 123 is less than that of the second adhesive 125, hardness of the first adhesive 123 and that of the second adhesive 125 can be measured in another type of hardness, such as shown in
The substrate 121 can be formed by a metal material, and through-holes 1216 are defined on the substrate 121. An effect of the through-holes is to guide lights, which leads to lights from the LED chips 14 can be radiated from the second lateral section 124.
The LED chips 14 can be multiple, the LED chips 14 can be series connected, parallel connected or series-parallel connected, each of the LED chips 14 can be connected electrically by metal wires printed on the carrier 12.
The carrier 12 of the LED filament 10 above includes the first lateral section 122 and the second lateral section 124 opposite to the first lateral section 122, the hardness of the first lateral section 122 is less than that of the second lateral section 124, and the first lateral section 122 is formed by the first adhesive 123, the second lateral section 124 is formed by the second adhesive 125; therefore, the LED filament 10 can obtain high structural strength with low costs. Moreover, as the first lateral section 122 and the second lateral section 124 are formed by the first adhesive 123 and second adhesive 125 separately, the first adhesive 123 can select an adhesive with better heat resistance and heat dissipation, and the second adhesive 125 can select an adhesive with regular heat resistance and heat dissipation; consequently, the LED filament 10 can be guaranteed to dissipate heat rapidly and evenly without increasing costs, which can improve operational power of the LED filament 10.
In the embodiment, the carrier 32 includes a substrate 321, a first adhesive 323 and a second adhesive 325. The substrate 321 contains a first bracket 3211 and a second bracket 3213 connected with the first bracket 3211. The first bracket 3211 contains an upper surface 3212 away from the second bracket 3213, the second bracket 3213 contains a bottom surface 3214 away from the first bracket 3211. The LED chips 34 are disposed on the upper surface 3212 of the first bracket 3211, the first adhesive 323 covers the upper surface 3212 of the first bracket 3211 and the LED chips 34, the second adhesive 325 covers the bottom surface 3214 of the second bracket 3213. The first adhesive 323 and the first bracket 3211 form the first lateral section 322, the second adhesive 325 and the second bracket 3213 form the second lateral section 324.
Specifically, a thermal conductivity of the first bracket 3211 can be higher than that of the second bracket 3213. Brittleness of the first bracket 3211 can be more than that of the second bracket 3213. A thickness W1 of the first bracket 3211 can be less than that W2 of the second bracket 3213.
In the embodiment, the first bracket 3211 and the second bracket 3213 are formed by metal materials, with a requirement of hardness of a metal material of the first bracket 3211 is less than that of the second bracket 3213. For instance, when the first bracket 3211 is formed by copper and the second bracket 3213 is formed by iron, copper can dissipate heat from the LED chips 34 easier because the thermal conductivity is higher, preventing temperature around the LED chips 34 from being excessive; yet iron of the second bracket 3213 can improve the entire structural strength of the LED filament 30 as the property of high strength, and iron materials have high thermal capacity, which can store more heat; hence the LED filament 30 can have higher optional power.
In the embodiment, the first bracket 3211 and the second bracket 3213 are formed by opaque metal materials, for which through-holes 3216 applied to guide lights can be defined on the substrate 321.
Furthermore, in the embodiment, the first bracket 3211 and the second bracket 3213 are connected by pasting with an adhesive 3217. The adhesive 3217 is preferably a thermal conductive adhesive.
Overall, according to the LED filaments and the LED bulb with the LED filament of the embodiments of the disclosure, as hardness of the first lateral section is less than that of the second lateral section, the LED filaments above can be designed based on various requirements of structural strength, which can reduce costs without sacrificing structural strength.
Till now, several embodiments are employed in the disclosure to illustrate principles and executions of the LED filaments and LED bulb of the disclosure, embodiments above are merely for explaining methods and spirits of the disclosure; meanwhile, it is understandable in practical to a person skilled in the art that all or portion of the processes in the method according to the aforesaid embodiment can be accomplished with modifications, equivalent replacements or improvements, in conclusion, the embodiments described above should not be regarded as a limitation, the scope should be covered by the claims.
Number | Date | Country | Kind |
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201510423074.0 | Jul 2015 | CN | national |