The present invention relates to a lighting device and a manufacturing method of lighting devices, and more particularly to a LED (Light emitting diode) lighting device and a manufacturing method of LED lighting devices.
Lighting is an important part of human life. Since Thomas Edison has invented electric lighting, the life of human being was widely changed. With the improvement in LED (Light emitting diode) technology and the decrease in cost, LED technology rapidly extends to various light fixtures and applications.
Compared with traditional incandescent light bulbs, LED usually has better luminous efficacy. However, LED components have limitations in heat resistance. If the problems of heat dissipation can be solved effectively, the life span of LED and the stability of light fixtures would be greatly improved.
Light bulbs are an important part of a light fixture. Because light bulbs are used for a long period, people have given impressions and preferences of the shape of light bulbs. Currently there are LED light bulbs designed to resemble traditional incandescent light bulbs in the market. However, the production process of LED light bulbs similar to incandescent light bulbs in appearance often faces the problems of weak structures and complicate assembly.
The present invention focuses on the technical problems of these kind of light bulbs. The present invention shows improvements in cost, reliability of products, and production cost.
The present invention provides an improved lighting device according to the first embodiment of the present invention. The lighting device includes at least one filament module, a base, at least one pillar, and a base.
The filament module includes more than two filaments. Each filament includes a substrate, multiple LED chips, a phosphor film, a top extended electrode, and a bottom extended electrode. Multiple LED chips are mounted on the substrate. The phosphor film covers the substrate and multiple LED chips. The top extended electrode and bottom extended electrode are connected to two ends of the substrate respectively. At least part of top extended electrode and bottom extended electrode are not covered by the phosphor film, and each top extended electrode of the filaments is fixed together.
The bottom of the pillar is connected to the base. Multiple top extended electrodes of the filaments of the filament module hang on the top of the pillar. A driver circuit electrically connects to multiple bottom extended electrodes of the filaments of the filament module. The base contains the driver circuit. The base is used to connect to the power.
In some embodiments, multiple top extended electrodes of the filaments of the filament module may connect to each other, then the combination of multiple top extended electrodes connects to the top of the pillar. In other words, the highest parts of the filaments may be assembled first, then the highest parts of the filaments are fixed to the top of the pillar.
In some embodiments, multiple top extended electrodes of the filaments of the filament module are integrally formed. In this kind of manufacturing method, the stability and conductivity of the filament are further improved, and the unnecessary problem of temperature increase gets better.
In some embodiments, the connection part of the top extended electrodes of multiple filaments may have a ring. The ring is put into the top of the pillar.
In some embodiments, the top extended electrode of the filament is made with a ring, and the top of the pillar is inserted into the ring. In other words, compared with traditional method of fixing the stick electrodes by welding, this method further improves the stability of the filaments.
In some embodiments, the number of the pillar is more than two, and multiple fila
In some embodiments, the pillar is a thin piece of metal. For example, the pillar may be made of iron-nickel alloys with certain hardness.
In some embodiments, the top of the pillar includes an insulation part. The insulation part has a support structure used to hold multiple top extended electrodes of the filaments of the filament module. In other words, the insulation part avoids a short circuit, causing by assembly or vibration, when certain filaments are electrically connected.
In some embodiments, the above-mentioned insulation part may be made of glass.
In some embodiments, the pillar in the area of insulation part may be all made of glass.
In some embodiments, the insulation part is made of plastic. Plastic may further reduce the overall cost. Plastic are easier to produce a relatively complicated stand, and the stand is used to support and fix the connection parts of the filaments.
In some embodiments, the support structure is a slot at the top of the insulation part. In other words, the mounting of the filaments becomes more stable with gloves, holes, and so on.
In some embodiments, the support part of the pillar is an extended component set in the insulation part. For example, the support part may be made out of metal sticks, and the pillar may be made of plastic or metal. The support part, like metal sticks and so on, is set in the pillar in the production process of the pillar. In this way, the stability is improved, and the complexity of assembly is reduced.
In some embodiments, the extended component is a metal stick. The extended component includes an inner part and an extended part. The inner part of the extended component is set in the insulation part. The extended part of the extended component is stretched away from the insulation part. The top extended electrodes of multiple filaments of the filament module hang on the extended part of the extended component.
In some embodiments, a bottom electrical connection structure extends from the base. The bottom electrical connection structure electrically connects to the driver circuit. The bottom extended electrodes of multiple filaments of the filament module electrically connect to the bottom electrical connection structure, and multiple filaments are electrically connected in series or parallel.
In some embodiments, the bottom electrical connection structure has an annular metallic strip. By cutting off the annular metallic strip, multiple filaments are electrically connected in series or parallel.
In some embodiments, the bottom extended electrodes of multiple filaments are fixed to the bottom electrical connection structure and thus to allow the angle between each filament and the pillar to be more than fifteen degrees.
In some embodiments, an insulator is put over a pair of connection parts of the top extended electrodes of the filaments, and another a pair of connection parts of the top extended electrodes of the filaments are fixed to the pillar over the insulator.
The present invention provides a manufacturing method of a lighting device according to another view of the present invention. The manufacturing method includes steps as follows.
A filament module is provided. The filament module includes at least two filaments. The filament includes a substrate, multiple LED chips, a phosphor film, a top extended electrode, and a bottom extended electrode. Multiple LED chips are mounted on the substrate. The phosphor film covers the substrate and multiple LED chips. The top extended electrode and bottom extended electrode are connected to two ends of the substrate respectively. At least part of top extended electrode and bottom extended electrode are not covered by the phosphor film. Each top extended electrode of the filaments is fixed together.
One or multiple filament modules are fixed to the pillar of the lighting device. The pillar is mounted on the base of the lighting device.
In some embodiments, this manufacturing method further includes a producing way of cutting a metal plate to produce the substrate, the top extended electrode, and the bottom extended electrode of the filament modules.
According to different embodiments as above, the present invention makes it possible to decrease the cost with varying degrees, improve the stability of filaments, and simplify the production process.
Firstly, please refer to
In the lighting device of
Please refer to
In
In this embodiment, two of filaments 201, 202, 203, 204 are electrically connected in series, while others are electrically connected in parallel. The annular metallic support strip extended from the base may be cut off according to different connection types. In other words, the annular metallic support strip as in the drawings may be cut off according to different connection types of filaments in the production process, thus to form different connection types of filaments.
Please refer to
Four filaments 301, 302, 303, 304 of
In other words, in these embodiments, the annular metallic support strips are basically the same, and the base with the same annular metallic support strip may be produced in large numbers. In the subsequent production process, a series connection or a parallel connection are formed by changing the break point of the annular metallic support strip or changing the connection type between the filaments and the annular metallic support strip. This method significantly reduces the production cost.
In
In other words, with this filament structure, people just make the top extended electrodes of the filaments hang on or weld to the top of the pillar, then make the bottom extended electrodes 422, 412 connect to the base, such as the annular metallic support strip as above.
In
The present invention provides an improved lighting device according to the first embodiment of the present invention. The lighting device includes at least one filament module, a base, at least one pillar, and a base.
The filament module includes more than two filaments. Each filament includes a substrate, multiple LED chips, a phosphor film, a top extended electrode, and a bottom extended electrode. Multiple LED chips are mounted on the substrate. The phosphor film covers the substrate and multiple LED chips. The top extended electrode and bottom extended electrode are connected to two ends of the substrate respectively. At least part of top extended electrode and bottom extended electrode are not covered by the phosphor film, and each top extended electrode of the filaments is fixed together.
The bottom of the pillar is connected to the base. Multiple top extended electrodes of the filaments of the filament module hang on the top of the pillar. A driver circuit electrically connects to multiple bottom extended electrodes of the filaments of the filament module. The base contains the driver circuit. The base is used to connect to the power.
In some embodiments, multiple top extended electrodes of the filaments of the filament module may connect to each other, then the combination of multiple top extended electrodes connects to the top of the pillar. In other words, the highest parts of the filaments may be assembled first, then the highest parts of the filaments are fixed to the top of the pillar.
In some embodiments, multiple top extended electrodes of the filaments of the filament module are integrally formed. In this kind of manufacturing method, the stability and conductivity of the filament are further improved, and the unnecessary problem of temperature increase gets better.
In some embodiments, the connection part of the top extended electrodes of multiple filaments may have a ring. The ring is put into the top of the pillar.
In some embodiments, the top extended electrode of the filament is made with a ring, and the top of the pillar is inserted into the ring. In other words, compared with traditional method of fixing the stick electrodes by welding, this method further improves the stability of the filaments.
In some embodiments, the number of the pillar is more than two, and multiple filaments hang on the tops of the pillars.
In some embodiments, the pillar is a thin piece of metal. For example, the pillar may be made of iron-nickel alloys with certain hardness.
In some embodiments, the top of the pillar includes an insulation part. The insulation part has a support structure used to hold multiple top extended electrodes of the filaments of the filament module. In other words, the insulation part avoids a short circuit, causing by assembly or vibration, when certain filaments are electrically connected.
In some embodiments, the above-mentioned insulation part may be made of glass.
In some embodiments, the pillar in the area of insulation part may be all made of glass.
In some embodiments, the insulation part is made of plastic. Plastic may further reduce the overall cost. Plastic are easier to produce a relatively complicated stand, and the stand is used to support and fix the connection parts of the filaments.
In some embodiments, the support structure is a slot on the top of the insulation part. In other words, the mounting of the filaments becomes more stable with gloves, holes, and so on.
In some embodiments, the support part of the pillar is an extended component set in the insulation part. For example, the support part may be made out of metal sticks, and the pillar may be made of plastic or metal. The support part, like metal sticks and so on, is set in the pillar in the production process of the pillar. In this way, the stability is improved, and the complexity of assembly is reduced.
In some embodiments, the extended component is a metal stick. The extended component includes an inner part and an extended part. The inner part of the extended component is set in the insulation part. The extended part of the extended component is stretched away from the insulation part. The top extended electrodes of multiple filaments of the filament module hang on the extended part of the extended component.
In some embodiments, a bottom electrical connection structure extends from the base. The bottom electrical connection structure electrically connects to the driver circuit. The bottom extended electrodes of multiple filaments of the filament module electrically connect to the bottom electrical connection structure, and multiple filaments are electrically connected in series or parallel.
In some embodiments, the bottom electrical connection structure has an annular metallic strip. By cutting off the annular metallic strip, multiple filaments are electrically connected in series or parallel.
In some embodiments, the bottom extended electrodes of multiple filaments are fixed to the bottom electrical connection structure and thus to allow the angle between each filament and the pillar to be more than fifteen degrees.
In some embodiments, an insulator is put over a pair of connection parts of the top extended electrodes of the filaments, and another a pair of connection parts of the top extended electrodes of the filaments are fixed to the pillar over the insulator.
Please refer to
Cut a metal plate to produce the substrate, the top extended electrode, and the bottom extended electrode of the filament modules (step 61).
A filament module is provided (step 62). The filament module includes at least two filaments. The filament includes a substrate, multiple LED chips, a phosphor film, a top extended electrode, and a bottom extended electrode. Multiple LED chips are mounted on the substrate. The phosphor film covers the substrate and multiple LED chips. The top extended electrode and bottom extended electrode are connected to two ends of the substrate respectively. At least part of top extended electrode and bottom extended electrode are not covered by the phosphor film. Each top extended electrode of the filaments is fixed together.
One or multiple filament modules are fixed to the pillar of the lighting device (step 63). The pillar is mounted on the base of the lighting device.
In some embodiments, this manufacturing method further includes a producing way of cutting a metal plate to produce the substrate, the top extended electrode, and the bottom extended electrode of the filament modules.
According to different embodiments as above, the present invention makes it possible to decrease the cost with varying degrees, improve the stability of filaments, and simplify the production process.
In addition to embodiments as above, the present invention may have other applications or designs, and as long as they are within the spirit of the present invention, the various designs still belong to the scope of the present invention.
The present application is a continued application of U.S. application Ser. No. 15/944,757.
Number | Date | Country | |
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Parent | 15944757 | Apr 2018 | US |
Child | 16725156 | US |