TWI403671B - Reinforced insulated bulbs - Google Patents

Abstract

An insulation-reinforced bulb includes a light transmissive cover and a electricity connecting base, a heat dissipation body and an assembly base installed between the light transmissive cover and the electricity connecting base, at least one light source substrate disposed inside the light transmissive cover, and a power conversion board electrically connected to the light source substrate and the electricity connecting base, in which the heat dissipation body has an installation space for accommodating the power conversion board. The present invention is characterized in that the bulb further includes an isolating body installed in the installation space. The isolating body comprises an isolating wall arranged between the power conversion board and the heat dissipation body in order to form a circuit accommodation space for accommodating the power conversion board, and an outlet hole located on the isolating wall for allowing the power conversion board wired-connecting to the light source substrate.

Description

Reinforced insulated bulb

A bulb for reinforced insulation, in particular, a bulb structure for driving at least one light-emitting diode using a power conversion panel, and further comprising a spacer to enhance the insulation capability of the power conversion panel.

Because the light-emitting diode (LED) has many advantages such as long service life, low power consumption, high brightness, and environmentally friendly materials, with the progress of the light-emitting diode process and the cost reduction, in addition to the use of traffic lights or electrical appliances. In addition to the indicator light, it is further used in environmental decoration and lighting fixtures. In order to make the light-emitting diode suitable for use in a general light bulb, the prior art has combined the light-emitting diode with the outer casing of a conventional light bulb, such as the Republic of China Patent Certificate No. I293807 "Light-emitting diode with constant current circuit" "Light bulb", the prior patent discloses that a light-emitting diode bulb includes a lamp cap, a lamp housing, a plurality of series-connected light-emitting diodes, and a step-down constant current circuit. Wherein the lamp cap has an electrode connected to the power source, and the plurality of light emitting diodes and the step-down constant current circuit are connected to provide a constant current to cause the light emitting diode to emit light, and the light emitting diode bulb is mounted on the conventional lamp holder It can be used directly. However, since the driving LED needs a stable DC current, the driving circuit that converts the AC mains into a DC current will continuously generate and accumulate waste heat during the conversion process. Moreover, the DC current also generates a lot of waste heat through the impedance of the light-emitting diode, and the excessive temperature is used for a long time. The degree will damage the light-emitting diode or the drive circuit, or the service life will be reduced. Therefore, the industry has developed a variety of light-emitting diode bulbs with a heat-dissipating structure, as shown in the Republic of China Patent Certificate No. M358247, "LED Lamps for Various Lamp Holders", which discloses that an LED heat-dissipating module has a combined end formation. An opening, the outer periphery of the opening is formed by a ring-shaped snap groove and a corresponding lamp cap. The other end of the opening is combined with an LED light-emitting component, so that the LED light-emitting component is electrically connected to the lamp cap, and the LED heat-dissipating module is located The LED light-emitting element and the periphery of the lamp head exert the function of heat conduction. A light-emitting diode bulb similar to the use of a metal heat sink can also be found in the Republic of China Patent Certificate Nos. M345944, M381743, and Publication No. 201020457.

Many of the aforementioned predecessors use metal heat sinks (usually aluminum heat sinks) to enhance heat dissipation, further allowing the bulb to withstand higher power without burning. However, conventional light-emitting diode bulbs are equipped with a passive power supply (hereinafter referred to as "passive power supply"), which is almost a RC capacitor, and is supplied with a rectifier circuit. Passive power supplies have the problem of poor efficiency at high power output, and the circuit volume increases with increasing power. Conventional LED light bulbs use passive power supplies because they are easier to pass the safety test.

In order to further improve the power of the light-emitting diode bulb, the switching power supply is selected as a better choice for power efficiency. However, the use of switched-mode power supplies requires a rigorous safety test, which includes at least a high-voltage power-on test in which a voltage of approximately four thousand volts is applied around the bulb and that the switched-mode power supply within the bulb is insulated from the applied voltage. In the conventional technique of using a passive power source, the passive power source is covered with a shrink film, and the glue mainly used for positioning is poured, and the glue can also enhance the insulation effect. However, the results of the test confirmed that the switched power supply and the periphery plus the adhesive were covered with a shrink film. The glue method cannot pass the high voltage power test.

Based on the need to increase power, operators must consider switching power supplies, but must further overcome safety testing. Due to the heat dissipation requirements of the high-power light-emitting diode bulb, the metal diode is required to be used for the light-emitting diode, which makes it difficult to overcome the safety test. The two factors are contradictory, causing difficulties in the design of the industry.

Since the LED light bulb technology is limited by a number of interrelated technical problems such as power boosting, conversion efficiency, safety testing, and the existing LED light bulb structure, it is still difficult to overcome the aforementioned problems at the same time. Therefore, the object of the present invention is to provide an improved light-emitting diode bulb, which provides an insulation structure with an insulating structure to isolate the power conversion substrate that drives the light-emitting diode to achieve an ideal insulation effect. This allows for efficient power conversion, output, and rigorous safety testing.

The present invention is a reinforced insulating bulb, comprising a translucent cover and a charging base, a heat dissipating body and an assembly seat mounted between the translucent cover and the charging base, at least one disposed in the translucent cover a light source substrate, and a power conversion board electrically connected to the light source substrate and the power receiving base, wherein the heat dissipating body has a mounting space for housing the power conversion board, wherein the light bulb further comprises a device disposed on the device Providing a spacer in the space, the spacer includes a partition wall between the power conversion board and the heat sink to form a circuit receiving space for accommodating the power conversion board, and a power conversion on the partition wall The board can be connected to the outlet hole of the light source substrate.

Through the combination of the spacer and the assembly base, the power conversion panel can be completely separated from the heat dissipation body, and the insulation capability is greatly enhanced. Through enhanced insulation capabilities, One step of using a power conversion board provides higher power and conversion efficiency. The plurality of light-emitting diodes and the plurality of conductive paths are disposed through the light source substrate, so that the high-power light-emitting diodes can conduct heat to the heat sink through the light source substrate. In summary, through the above structural features, a light-emitting diode bulb that can use a power conversion board, a high-power light-emitting diode, and has sufficient insulation capability to pass the safety test is provided.

1‧‧‧Isolation

10‧‧‧ partition wall

11‧‧‧ joints

12‧‧‧Outlet hole

13‧‧‧Protruding

14‧‧‧Circuit housing space

2‧‧‧Assembly

21‧‧‧Insulated wall

211‧‧‧First Positioning Department

212‧‧‧Reducing the inner edge

22‧‧‧Combination Department

23‧‧‧Drainage Department

3‧‧‧Power Conversion Board

30, 31‧‧‧.. power wire

4‧‧‧ Heat sink

40‧‧‧Light source substrate

401‧‧‧Lighting diode

402‧‧‧Line hole

41‧‧‧Installation space

410‧‧‧Mate

411‧‧‧Second Positioning Department

42‧‧‧Heat fins

43‧‧‧through holes

44‧‧‧ positioning slot

5‧‧‧Transparent cover

50‧‧‧ neck

6‧‧‧Electrical stand (6)

61‧‧‧Binding end

Figure 1 is an exploded view of the light-emitting diode bulb of the present invention.

2 is a schematic view showing the assembly of the light-emitting diode bulb.

Fig. 3 is a cross-sectional view of the light emitting diode.

Figure 4 is a cross-sectional view showing another embodiment of the spacer and the assembly.

This case is a light bulb with enhanced insulation. The technical content of this case will be explained below with reference to the drawings. Referring to FIG. 1 , FIG. 2 and FIG. 3 , FIG. 1 to FIG. 3 show a first embodiment of the present invention. The light bulb disclosed in the first embodiment includes a transparent cover 5 and a receiving base 6 . a heat dissipating body 4 and an assembly base 2 disposed between the light transmissive cover 5 and the power receiving base 6 , at least one light source substrate 40 disposed in the light transmissive cover 5 , and an electrical connection between the light source substrate 40 and The power conversion board 3 of the battery holder 6 is connected. Preferably, the power conversion board 3 is a switched power supply circuit. The heat dissipating body 4 has a mounting space 41 for housing the power conversion panel 3. The light bulb further includes a spacer 1 including a partition wall 10 between the power conversion panel 3 and the heat sink 4 to form a circuit housing space 14 for accommodating the power conversion panel 3, and A wire opening 12 is provided on the partition wall 10 for the power conversion panel 3 to be connected to the light source substrate 40. And in order to pass the safety test, the separator 1 is A protrusion 13 is formed on the periphery of the outlet hole 12 to avoid high voltage power breakdown. In the embodiment shown in FIGS. 1 to 3, the partition wall 10 continuously covers the upper side and the side of the power conversion panel 3. The partition wall 10 is provided with a joint portion 11 . The assembly base 2 is provided with a continuous insulating wall 21 and a joint portion 22 respectively on the two sides. The outer edge of the insulating wall 21 is provided with at least one first positioning portion 211 . The joint portion 11 of the partition wall 10 is then tightly joined to the inner edge of the insulating wall 21 (as shown in Fig. 4). Alternatively, in order to facilitate the engagement of the insulating wall 21 with the joint portion 11, the joint portion 11 may have a reduced outer edge, and the inner edge of the partition wall 21 correspondingly has a reduced inner edge 212 complementary to the reduced outer edge ( As shown in FIG. 1 to FIG. 3 , the present embodiment is only an implementable embodiment, and the joint portion 11 and the partition wall 21 must be provided with a reduced outer edge and a reduced inner edge 212. The technical field has a general The manner in which the knowledgeable person can easily change should be included in the scope of the case. Through the engagement of the joint portion 11 with the inner edge of the insulating wall 21, it is ensured that the power conversion panel 3 is insulated from the circuit housing space 14.

The heat sink 4 is provided with a light source substrate 40 having a plurality of light emitting diodes 401. The light source substrate 40 can be an aluminum substrate including a plurality of conductive paths. In the prior art, the copper foil, the heat conductive insulating material, and the aluminum plate can be stacked, and the copper foil is etched into a circuit and then coated on the heat conductive insulating material and the aluminum plate. The light source substrate 40 including the conductive path is formed. Since the aluminum substrate is a currently known technology, although the technology of the aluminum substrate is cited in the present case, the manufacturing technology and the detailed structure of the aluminum substrate are not technical points of the present invention, and therefore will not be described again. The heat dissipating body 4 is fixed to the fitting portion 410 by means of a pressing portion, and the light source substrate 40 is firmly pressed into the fitting portion 410 to firmly bond the light source substrate 40 to the heat dissipating body 4. Therefore, the heat dissipating body 4 and the inner edge of the light source substrate 40 surround an installation space 41 having an opening to accommodate the spacer 1 and the insulating wall 21, The light source substrate 40 has a wire hole 402 communicating with the installation space 41. The inner edge of the heat dissipating body 4 has at least one second positioning portion 411 corresponding to the first positioning portion 211 of the insulating wall 21, and the first positioning portion 211 and the second positioning portion 411 can be correspondingly buckled and notched. The bumps thereby enclose the insulating wall 21 and the separator 1 in the installation space 41. At least one power wire 30 connected to the power conversion board 3 can pass through the outlet hole 13 of the partition wall 10 and the wire hole 402 on the light source substrate 40 to make the power conversion board 3 and the light emitting diodes The body 401 is electrically connected. Moreover, the protruding portion 13 can be embedded in the routing hole 402.

Through the above-described technique, the power conversion panel 3 can be mounted in the light-emitting diode bulb, and the power conversion panel 3 can be isolated and protected in the circuit housing space 14 through the spacer 1 and the assembly base 2. Further, an air gap is formed between the partition wall 10 of the separator 1 and the inner edge of the heat sink 4 to ensure that the high-voltage power in the safety test cannot damage the power conversion panel 3.

As shown in FIG. 1 to FIG. 3 , the joint portion 22 of the assembly base 2 is located outside the installation space 41 , and the joint portion 22 and a joint end 61 of a power socket 6 are coupled to each other. For connecting an external power source, and electrically connecting the power conversion board 3 and the power receiving base 6 through the at least one power wire 31, the power guided from the external power source is sent to the power conversion board 3. Depending on the type of bulb or the application environment, a variety of different types of sockets can be used. The type quoted in Figures 1 to 3 is a general household bulb type, but the socket 6 is not limited to Figure 1. To the type shown in Figure 3.

In addition, the heat dissipating body 4 has a positioning groove 44 in the fitting portion 410. The positioning groove 44 is used for fixing the transparent cover 5, and the transparent cover 5 has a neck portion 50. Equipped in the positioning groove 44, or at the same time with the adhesive, the neck 50 is adhered to the fixed In the bit slot 44.

4 is a cross-sectional view showing another embodiment of the light bulb, and the embodiment of FIG. 4 differs from the first embodiment in that the joint portion 11 and the insulating wall 21 are dimensioned to make the joint. The inner portion 11 and the inner edge of the insulating wall 21 can be directly tightly coupled, and the outer edge of the reduced and the outer edge of the reduced outer edge are not required to be additionally provided. Since the direct tight bonding method does not need to thin the thickness of the joint portion 11 and the insulating wall 21, it can have a larger insulating ability.

In the first embodiment of FIG. 1 to FIG. 3 and the second embodiment shown in FIG. 4 , the outer edges of the heat sink 4 are stacked with a plurality of heat dissipation fins 42 , and the heat dissipation fins 42 have The gap is for air circulation. The heat dissipation fins 42 have a plurality of through holes 43. The plurality of through holes 43 of the plurality of heat dissipation fins 42 are arranged through the heat dissipation body 4 to form at least one air flow passage for the longitudinal direction of the air, and the assembly base 2 further includes At least one flow guiding portion 23, the flow guiding portion 23 reserves a space for guiding the airflow to facilitate the airflow through the through holes 43. The gaps between the fins 42 and the airflow passages allow for lateral and longitudinal airflow, and provide a large air contact area for excellent heat dissipation.

The foregoing embodiment defines that the partition wall 10 continuously covers the upper side and the side of the power conversion board 3, but the partition wall 10 may extend between the power conversion board 3 and the power receiving base 6, and has The outlet wall 10 is disposed such that the power conversion panel 3 can be electrically connected to another outlet hole (not shown) of the power receiving base 6. Although the present invention has been disclosed above in the preferred embodiment, it is not intended to limit the present invention. Anyone who is familiar with this skill and does not deviate from the spirit and scope of this case, and some of the changes and refinements should be covered in this case. Therefore, the scope of protection of this case is subject to the definition of the patent application scope attached.

In summary, this case enhances the above-mentioned effects compared with the well-known creations. It should fully comply with the statutory innovation patent requirements of novelty and progressiveness. If you apply in accordance with the law, you are requested to approve the application for this invention patent to encourage creation. Debian.

1‧‧‧Isolation

10‧‧‧ partition wall

11‧‧‧ joints

12‧‧‧Outlet hole

13‧‧‧Protruding

14‧‧‧Circuit housing space

2‧‧‧Assembly

21‧‧‧Insulated wall

211‧‧‧First Positioning Department

22‧‧‧Combination Department

23‧‧‧Drainage Department

3‧‧‧Power Conversion Board

30, 31‧‧‧Power wires

4‧‧‧ Heat sink

40‧‧‧Light source substrate

401‧‧‧Lighting diode

402‧‧‧Line hole

411‧‧‧Second Positioning Department

42‧‧‧Heat fins

43‧‧‧through holes

5‧‧‧Transparent cover

50‧‧‧ neck

6‧‧‧Electrical stand

Claims (13)

A reinforced insulating bulb includes a transparent cover and a power receiving base, a heat dissipating body and an assembly seat mounted between the transparent cover and the power receiving base, and at least one light source substrate disposed in the transparent cover And a power conversion board electrically connected to the light source substrate and the power receiving base, wherein the heat dissipating body has a mounting space for accommodating the power conversion board, wherein the light bulb further comprises: a device disposed at the device a spacer in the space, the spacer includes a partition wall between the power conversion board and the heat sink to form a circuit accommodating space for accommodating the power conversion board, and a power conversion board disposed on the partition wall The outlet hole of the light source substrate is connected to the outlet, and the assembly has an insulating wall, and the inner edge of the insulating wall is tightly engaged with the partition wall. The reinforced insulated bulb of claim 1, wherein the partition wall and the insulating wall have a reduced and tight outer edge and a reduced inner edge. The reinforced insulated light bulb of claim 1, wherein the assembly base and the heat sink have at least one corresponding first positioning portion and a second positioning portion. The reinforced insulating light bulb of claim 3, wherein the first positioning portion and the second positioning portion are correspondingly buckled notches and bumps. The reinforced insulated bulb of claim 1, wherein the assembly has a joint located outside the installation space and coupled to a battery mount. The reinforced insulated bulb of claim 1, wherein the spacer is provided with a protrusion at a periphery of the outlet hole. The reinforced insulating bulb according to claim 6, wherein the light source substrate A wire hole communicating with the installation space is provided for the at least one power wire to pass through and electrically connected to the light source substrate. The reinforced insulating bulb according to claim 7, wherein the protruding portion is embedded in a wire hole of the light source substrate. The reinforced insulated light bulb of claim 1, wherein the light source substrate has a wire hole communicating with the installation space for at least one power wire to pass through and electrically connected to the light source substrate. The reinforced insulating bulb according to claim 1, wherein the light source substrate is an aluminum substrate including a plurality of conductive paths. The reinforced insulating light bulb of claim 1, wherein the heat dissipating body has a plurality of heat dissipating fins arranged in a stack, and the heat dissipating fins have a plurality of through holes penetrating through at least one air flow passage. The reinforced insulated light bulb of claim 1, wherein the partition wall extends between the power conversion board and the power receiving base, and has a power distribution board on the partition wall for connecting the power conversion board to the power socket. Another outlet hole. The reinforced insulated bulb of claim 1, wherein the power conversion panel is a switched power supply circuit.