JP3232164U - Smart light bulb - Google Patents

Abstract

PROBLEM TO BE SOLVED: To solve a problem that a light beam is blocked by an antenna of a smart light bulb and a shadow is formed. A smart light bulb includes a first heat dissipation member 1, a light bulb cover 2, a base assembly 3, a light source plate 4, a drive plate 5, and an antenna module 6. The bulb cover is installed at one end of the first heat dissipation member and the base assembly is installed at the other end of the first heat dissipation member. The light source plate is installed in the first heat radiating member and covers one end close to the light bulb cover of the first heat radiating member. The drive plate is installed in the first heat dissipation member and is electrically connected to the base assembly and the light source plate. The antenna module is installed in the first heat dissipation member and is electrically connected to the drive plate, and the surface of the antenna module facing the light bulb cover is not higher than the surface of the light source plate facing the light bulb cover. In the smart bulb, the surface of the antenna module facing the bulb cover is not higher than the surface of the light source plate facing the bulb cover, does not block the light emitting path of the light source plate, and guarantees the uniformity of the light spot. [Selection diagram] Fig. 2

Description

This utility model relates to lighting equipment, and more specifically to smart light bulbs.

Since LED lighting devices have advantages such as energy saving, environmental consideration and high stability, they are widely applied in various lighting fields. With the development of smart technology, LED lighting devices will gradually become smarter, thereby improving the smart experience of users.

Today's smart light bulbs need to communicate with the outside, and in order to improve the transmission effect, it is necessary to install an antenna inside the smart light bulb, but the conventional antenna structure blocks some light rays, especially If the area of the antenna is large, it causes shadows of light spots.

The purpose of this utility model is to provide a smart light bulb and to solve the technical problem that a shadow of a light spot is generated by blocking a part of light rays by an antenna in a conventional smart light bulb.

The technical means adopted by this utility model to achieve the above objectives are as follows.
First heat dissipation member,
A light bulb cover installed at one end of the first heat dissipation member,
A base assembly installed at the other end of the first heat dissipation member,
A light source plate installed in the first heat radiating member and covering one end of the first heat radiating member near the light bulb cover.
A drive plate installed in the first heat radiating member and electrically connected to the base assembly and the light source plate, and an antenna installed in the first heat radiating member and electrically connected to the drive plate. With a module,
A smart light bulb characterized in that the surface of the antenna module facing the light bulb cover is not higher than the surface of the light source plate facing the light bulb cover.

Compared with the conventional technology, the beneficial effects of this utility model smart light bulb are as follows. The surface of the antenna module facing the light bulb cover is not higher than the surface of the light source plate facing the light bulb cover, and the upper part of the antenna module is covered only by the light bulb cover, so that the influence on the communication signal is small. Moreover, since there are no obstacles, it is possible to guarantee control consistency of communication signals at different angles. Since some light rays are not blocked by blocking the light source plate, even if the area of the antenna module is increased, the light emitting path of the light source plate is not blocked, and the uniformity of the light spot is guaranteed. Moreover, the signal transmission rate of the antenna module is guaranteed. In this way, the user's experience is good.

Further, the antenna module is installed on the drive plate, and the antenna module has a flat plate-like structure in which the surface facing the light bulb cover is lower than the surface of the light source plate facing the light bulb cover.
The antenna module has a ring rod-like structure in which the surface of the light source plate facing the light bulb cover is lower than the surface of the light source plate facing the light bulb cover.

Further, a through hole is provided at a position corresponding to the antenna module of the light source plate.
Further, the antenna module includes a substrate and an antenna.
The surface of the substrate facing the light bulb cover and the surface of the light source plate facing the light bulb cover are on the same plane.
The antenna is installed on the surface of the substrate facing the light bulb cover, and the protruding height of the antenna is lower than the protruding height of the light emitting element of the light source plate.

Further, a retracting groove for mounting the substrate is provided in the light source plate, and the substrate is fitted in the retracting groove.

Further, a retract notch is opened at a position of the light source plate corresponding to the transmitting end of the antenna, and the retract notch communicates with the retract groove.

Further, a first input terminal is installed on the board, and a first output terminal electrically connected to the first input terminal is installed on the drive plate.

Further, the smart light bulb further includes a second heat radiating member, and the second heat radiating member is installed between the driving plate and the light source plate and is attached to the substrate.

This utility model also provides the following smart light bulbs.

First heat dissipation member,
A light bulb cover installed at one end of the first heat dissipation member,
A base assembly installed at the other end of the first heat dissipation member,
A light source plate installed in the first heat radiating member and covering one end of the first heat radiating member near the light bulb cover.
A drive plate installed in the first heat radiating member and electrically connected to the base assembly and the light source plate, and an antenna installed in the first heat radiating member and electrically connected to the drive plate. With a module,
A smart light bulb characterized in that the surface of the antenna module facing the light bulb cover is higher than the surface of the light source plate facing the light bulb cover, and the antenna module is installed perpendicular to the light source plate.

Compared with the conventional technology, the beneficial effects of this utility model smart light bulb are as follows. By installing the antenna module vertically on the light source plate, on the other hand, the projected area of the antenna module on the light source plate is small, and the blocking area of the antenna module with respect to the light source plate is small, so that the antenna module blocks the light source plate. This prevents some light rays from being blocked. On the other hand, the surface of the antenna module facing the light bulb cover is higher than the surface of the light source plate facing the light bulb cover, whereby part or all of the antenna module extends from the light source plate, and signal transmission of the antenna module is good.

Further, the smart light bulb further includes a grounding portion, and the grounding portion is installed on the drive plate and becomes conductive by contacting with the first heat radiating member.

Further, the smart light bulb further includes a white light emitting element and a color light emitting element.
The white light emitting element is installed on the light source plate, includes a first chip and a second chip, and the light emitted from the first chip is mixed with the light emitted from the second chip.
The color light emitting element is installed on the light source plate and includes a third chip, a fourth chip, and a fifth chip, and the light emitted from the third chip, the light emitted from the fourth chip, and the fifth chip. The light emitted from is mixed.

In order to more clearly explain the technical means in the examples of the utility model, the drawings necessary for explaining the examples and the prior art will be briefly described below. Obviously, the drawings described below are only a few examples of this utility model, and one of ordinary skill in the art can obtain other drawings based on these drawings without any creative effort. it can.

It is 3D structure schematic diagram of the smart light bulb provided by the Example of this utility model. It is a schematic disassembled structure of the smart light bulb provided by the 1st Example of this utility model. It is sectional drawing of the cross-sectional structure of the smart light bulb provided by the 1st Example of this utility model. It is a schematic disassembled structure of the smart light bulb provided by the 2nd Example of this utility model. It is sectional drawing of the cross-sectional structure of the smart light bulb provided by the 2nd Example of this utility model. It is a schematic disassembled structure of the smart light bulb provided by the 3rd Example of this utility model. It is 3D structure schematic diagram of the light source plate and the antenna module provided by the 3rd Example of this utility model. It is sectional drawing of the cross-sectional structure of the smart light bulb provided by the 3rd Example of this utility model. It is a schematic disassembled structure of the smart light bulb provided by the 4th Example of this utility model. It is sectional drawing of the cross-sectional structure of the smart light bulb provided by the 4th Example of this utility model. It is the schematic of the drive relation of the smart light bulb provided by the Example of this utility model.

In order to clarify the technical problems, technical means and beneficial effects to be solved by the utility model, the utility model will be described in more detail with reference to the drawings and examples below. It should be noted that the specific examples described here are for interpreting the utility model only, and do not limit the utility model.

When the member is referred to as "fixed" or "installed" on another member, it may be directly or indirectly arranged on the other member. When a member is described as "connected" to another member, it may be directly or indirectly connected to the other member. The terms "top", "bottom", "left", "right", "front", "rear", "vertical", "horizontal", "top", "bottom", "inside", "outside" The orientations and positional relationships shown in the drawings are based on the orientations and positional relationships shown in the drawings and are for facilitating explanation, and should not be understood as limiting the technical means. Also, the terms "first" and "second" are for illustration purposes only and expressly or implicitly indicate the relative importance or number of technical features indicated. Should not be understood. "Plural" means two or more, unless otherwise stated.

In order to explain the technical means of the utility model, the details will be described below with reference to specific drawings and examples.

As shown in FIGS. 1 to 3, the smart light bulb according to the embodiment of the utility model includes a first heat dissipation member 1, a light bulb cover 2, a base assembly 3, a light source plate 4, a drive plate 5, and an antenna module 6. Here, both ends of the first heat radiating member 1 have openings, the light bulb cover 2 covers one end having a large opening of the first heat radiating member 1, and the base assembly 3 is installed at one end having a small opening of the first heat radiating member 1. Will be done. The light source plate 4 is installed in the first heat radiating member 1, and the light source plate 4 covers one end of the first heat radiating member 1 near the light bulb cover 2. The drive plate 5 is installed in the first heat radiating member 1 and is located between the base assembly 3 and the light source plate 4, and one end of the drive plate 5 is electrically connected to the base assembly 3 to other than the drive plate 5. The ends are electrically connected to the light source plate 4.

Further, as shown in FIGS. 5 and 8, the antenna module 6 is installed in the first heat radiation member 1, the antenna module 6 is electrically connected to the drive plate 5, and the surface of the antenna module 6 faces the light bulb cover 2. Is not higher than the surface of the light source plate 4 facing the bulb cover 2, that is, the surface of the antenna module 6 facing the bulb cover 2 is lower than the surface of the light source plate 4 facing the bulb cover 2, or facing the bulb cover 2 of the antenna module 6. The surface and the surface of the light source plate 4 facing the bulb cover 2 are on the same plane.

In the smart light bulb of the embodiment of this practical proposal, the surface of the antenna module 6 facing the light bulb cover 2 is not higher than the surface of the light source plate 4 facing the light bulb cover 2, and the upper part of the antenna module 6 covers only the light bulb cover 2. Therefore, the influence on the communication signal is small. Moreover, since there are no obstacles, it is possible to guarantee control consistency of communication signals at different angles. Since the light source plate 4 is not blocked to block a part of the light rays, even if the area of the antenna module 6 is increased, the light emitting path of the light source plate 4 is not blocked, and the uniformity of the light spot is improved. Guarantee and guarantee the signal transmission rate of the antenna module 6. In this way, the user's experience is good.

The following examples are provided below based on the different antenna modules 6.

Example 1
Specifically, as shown in FIGS. 2 and 3, the antenna module 6 is installed on the drive plate 5, and the antenna module 6 has a flat plate-like structure, and the surface of the flat plate-like structure facing the light bulb cover 2 is It is lower than the surface of the light source plate 4 facing the bulb cover 2, thereby preventing the antenna 62 from extending from the light source plate 4 and blocking the light emitting path of the light source plate 4 to affect the optical effect. Compared with the antenna module 6 having another structure, the antenna module 6 adopting the flat plate structure is stable after being attached. Specifically, the flat plate-like structure is installed on the side surface of the drive plate 5, and the flat plate-like structure is inserted at right angles to the drive plate 5.

Example 2
As shown in FIGS. 4 and 5, the antenna module 6 is installed on the drive plate 5, and the antenna module 6 has a ring rod-shaped structure, and the surface of the ring rod-shaped structure facing the light bulb cover 2 is a light bulb of the light source plate 4. Lower than the surface facing cover 2. Here, the circumference area of the ring rod-shaped structure is made as large as possible so as to increase the output amount of the signal. Compared with the antenna module 6 having another structure, the antenna module 6 having a ring rod-like structure can be wound up according to needs and has a simple structure. It can be selected according to specific needs.

In one embodiment of the utility model, specifically, as shown in FIGS. 2 and 4, the smart light bulb further includes a smart integrated chip 63, and the smart integrated chip 63 is installed on the side surface of the drive plate 5. .. Specifically, the smart integrated chip 63 is inserted at right angles to the side surface of the drive plate 5. The smart integrated chip 63 and the antenna module 6 are electrically connected by a feeder line of the drive plate 5, and the smart integrated chip 63 processes the induction signal collected from the antenna module 6 and the drive plate is based on the control signal. 5 is controlled, and the light emission of the light source plate 4 is controlled. This embodiment is applied to the antenna module 6 in any of the first and second embodiments.

In one embodiment of the utility model, a through hole 43 is provided at a position corresponding to the antenna module 6 of the light source plate 4, specifically referring to FIGS. 2 and 4. With respect to the antenna module 6 in the first embodiment, the cross-sectional area of the through hole 43 is larger than the cross-sectional area of the antenna module 6. With respect to the antenna module 6 in the second embodiment, the cross-sectional area of the through hole 43 is larger than the vertical cross-sectional area of the antenna module 6. That is, a through hole 43 that is much larger than the area of the antenna module 6 is provided in the light source plate 4 to prevent the signal from the antenna module 6 from being blocked by the light source plate 4, thereby reducing the signal transmission rate of the antenna 62. Guarantee.

Example 3
Specifically, as shown in FIGS. 6 to 8, the surface of the antenna module 6 facing the light bulb cover 2 and the surface of the light source plate 4 facing the light bulb cover 2 are on the same plane. The antenna module 6 includes a substrate 61 and an antenna 62. Here, the surface of the substrate 61 facing the light bulb cover 2 and the surface of the light source plate 4 facing the light bulb cover 2 are on the same plane. The antenna 62 is installed on the surface of the substrate 61 facing the light bulb cover 2, and the protruding height of the antenna 62 is lower than the protruding height of the light emitting element of the light source plate 4. Compared to the antenna module 6 at other positions, the antenna module 6 is installed on the same plane as the light source plate 4, because the substrate 61 is just attached to the light source plate 4 when assembling, and the structure is compact and easy to assemble. .. It is not necessary to newly install a jig or a connection terminal on the substrate 61 and connect it to the light source plate 4, which saves process development cost.

In this embodiment, the antenna 62 may be installed on the substrate 61 in a striped shape, a bent shape, or an annular shape. Of course, the shape of the antenna 62 may be another shape as long as the surface of the antenna 62 facing the light bulb cover 2 and the surface of the light source plate 4 facing the light bulb cover 2 are on the same plane.

In one embodiment of the utility model, specifically, as shown in FIG. 7, the smart light bulb further includes a smart integrated chip 63, and the difference from the first and second embodiments is that the smart integrated chip 63 is used. It is to be installed on the substrate 61. The smart integrated chip 63 and the antenna module 6 are electrically connected by a feeder line of the substrate 61, and the smart integrated chip 63 processes the induction signal collected from the antenna module 6 and the drive plate 5 is based on the control signal. To control the light emission of the light source plate 4. This embodiment is applied to the antenna module 6 of the third embodiment.

In this embodiment, further referring to FIG. 7, a retracting groove 41 for attaching the substrate 61 to the light source plate 4 is opened, and the substrate 61 is fitted in the retracting groove 41. By fitting the substrate 61 into the evacuation groove 41, the mounting space is saved on the one hand, and the antenna 62 blocks the light emitting element of the light source plate 4 on the other hand, thereby avoiding affecting the uniformity of the light spot. To do. This example can be combined with Example 3.

Here, in this embodiment, the light source plate 4 does not completely enclose the substrate 61. The light source plate 4 is further provided with a retracted notch 42 corresponding to the transmitting end of the antenna 62, and the retracted notch 42 communicates with the retracted groove 41. The signal transmitted from the transmitting end of the antenna 62 is prevented from being blocked by the light source plate 4, the reception and transmission of the signal are not interfered with, and the signal transmission rate of the antenna 62 is guaranteed.

In this embodiment, with reference to 6 and FIG. 7, the substrate 61 and the drive plate 5 are electrically connected by terminals. The first input terminal 611 is installed on the board 61, and the first output terminal 51 electrically connected to the first input terminal 611 is installed on the drive plate 5. Specifically, the first input terminal 611 is a female terminal, the first output terminal 51 is a male terminal, and the male terminal is inserted into the female terminal and electrically connected to the female terminal, whereby the substrate 61 Is electrically connected to the drive plate 5. Of course, the first input terminal 611 may be a male terminal and the first output terminal 51 may be a female terminal as long as it can be guaranteed that both are electrically connected.

In this embodiment, specifically, as shown in FIG. 6, the smart light bulb further includes a second heat radiating member 7, and the second heat radiating member 7 is installed between the drive plate 5 and the light source plate 4. The second heat radiating member 7 is attached to the substrate 61. Since the antenna 62 has a temperature condition, the temperature must be lower than 85 ° C. or lower than 105 ° C., and the substrate 61 is fitted in the light source plate 4, and the heat generated by the light source plate 4 is transmitted to the substrate 61. The temperature of the antenna 62 rises to generate heat, which affects the effect of using the antenna 62. The second heat radiating member 7 is a press-molded aluminum part, which covers the first heat radiating member 1, and the second heat radiating member 7 is attached to the substrate 61 and can transfer a part of heat, and is an antenna. The temperature rise and heat generation of 62 is avoided.

Example 4
In one embodiment of the utility model, as shown in FIGS. 9 and 10, the installation positions of the antenna modules 6 in this embodiment are the same as the installation positions of the antenna modules 6 of Examples 1, 2 and 3. different. The surface of the antenna module 6 facing the light bulb cover 2 is higher than the surface of the light source plate 4 facing the light bulb cover 2, that is, a part of the structure of the antenna module 6 or the entire structure of the antenna module 6 extends from the light source plate 4 and The antenna module 6 is installed vertically on the light source plate 4.

Since the conventional antenna module 6 extends from the light source plate 4 and the antenna module 6 is installed in parallel with the light source plate 4, the projected area of the antenna module 6 on the light source plate 4 is large, and as a result, a part of the antenna module 6 is projected. Block the light source. In this embodiment, the antenna module 6 is installed vertically on the light source plate 4, and on the other hand, the projected area of the antenna module 6 on the light source plate 4 is small, so that the blocking area of the antenna module 6 with respect to the light source plate 4 is small. , The antenna module 6 blocks the light source plate 4 to prevent some light rays from being blocked. On the other hand, since the surface of the antenna module 6 facing the light bulb cover 2 is higher than the surface of the light source plate 4 facing the light bulb cover 2, a part or all of the antenna module 6 extends from the light source plate 4 and thereby. The transmission signal of the antenna module 6 is good.

Specifically, in this embodiment, the antenna module 6 is coated with a light reflecting layer, and the light rays emitted to the antenna module 6 can be reflected, so that the utilization rate of the light rays can be improved.

In one embodiment of the utility model, the antenna module 6 has a flat plate-like structure, the smart light bulb further includes a smart integrated chip 63, and the smart integrated chip 63 is installed on the side surface of the drive plate 5. Specifically, the smart integrated chip 63 is inserted at right angles to the side surface of the drive plate 5, and the smart integrated chip 63 and the antenna module 6 have an integrally molded structure, whereby the smart integrated chip 63 is an antenna module. Electrically connected to 6, the smart integrated chip 63 processes the induction signal collected from the antenna module 6 and controls the drive plate 5 based on the control signal to control the light emission of the light source plate 4.

In one embodiment of the utility model, an extension hole 45 for extending the antenna module 6 is provided at a position corresponding to the antenna module 6 of the light source plate 4. With respect to the antenna module 6 in the fourth embodiment, the cross-sectional area of the extension hole 45 is equal to or larger than the cross-sectional area of the antenna module 6, and the antenna module 6 can extend from the light source plate 4.

In one embodiment of the utility model, as further shown in FIGS. 2, 4, 6 and 9, the smart light bulb further includes a grounding portion 52, and the grounding portion 52 is installed on the drive plate 5. The grounding portion 52 conducts by contacting with the first heat radiating member 1, that is, the ground of the drive plate 5 is connected to the first heat radiating member 1 via the grounding portion 52, and helps to remove some interference signals. As a result, the signal of the antenna 62 becomes stronger and complements a part of the signal blocked by the light source plate 4. This example applies to any of Example 1, Example 2, Example 3 or Example 4.

The antenna module 6 in the first, second and fourth embodiments is installed on the drive plate 5. Compared with the conventional design, on the other hand, the grounding portion 52 unifies the ground of the antenna module 6 and the first heat radiating member 1, combines with the metal structure of the first heat radiating member 1, and combines the first heat radiating member 1 with the antenna module 6. It can be a part, the transmission and reception capabilities of the antenna module 6 can be enhanced, and the communication performance of the antenna module 6 is greatly improved. On the other hand, by connecting the ground of the antenna module 6 to the first heat radiation member 1, the electrostatic circuit of the entire light bulb is improved, and the static electricity enters the grounding portion 52 via the antenna module 6 and further from the grounding portion 52. It leads to the first heat radiation member 1. In general, this helps to eliminate some interference signals, which strengthens the signal of the antenna 62 and complements some of the signals blocked by the light source plate 4.

With respect to the antenna module 6 of the third embodiment, the antenna module 6 is electrically connected to the drive plate 5 by the first input terminal 611, whereby the ground of the antenna module 6 is first connected to the ground portion 52 of the drive plate 5. It is unified with the heat radiation member 1, and in combination with the metal structure of the first heat radiation member 1, the first heat radiation member 1 can be a part of the antenna module 6, and the transmission and reception capabilities of the antenna module 6 can be improved. , The communication performance of the antenna module 6 is greatly improved. On the other hand, by connecting the ground of the antenna module 6 to the first heat radiation member 1, the electrostatic circuit of the entire light bulb is improved, and the static electricity enters the drive plate 5 via the antenna module 6 and further to the grounding portion 52. It enters, and finally reaches the first heat radiation member 1 from the grounding portion 52.

Specifically, in this embodiment, the ground contact portion 52 is an elastic piece. One end of the elastic piece is connected to the drive plate 5, and the other end of the elastic piece is tightly fitted to the first heat radiating member 1. The shape of the elastic piece is straight, arc or bent. It can be selected according to specific needs.

In one embodiment of the utility model, a two-in-one white light source and a three-in-one color light source are distributed on the light source plate 4, with reference to FIGS. 2, 4, 6, 7, and 9. Here, the smart light bulb further includes a white light emitting element 81 and a color light emitting element 82. Both the white light emitting element 81 and the color light emitting element 82 are provided on the light source plate 4. The white light emitting element 81 includes a first chip 811 and a second chip 812, and the light emitted by the first chip 811 is mixed with the light emitted by the second chip 812, whereby white light can be emitted. The color light emitting element 82 includes a third chip 821, a fourth chip 822, and a fifth chip 823, and includes light emitted by the third chip 821, light emitted by the fourth chip 822, and light emitted by the fifth chip 823. The three are mixed.

Specifically, in this embodiment, the second input terminal 44 is installed on the light source plate 4, and the second output terminal 53 electrically connected to the second input terminal 44 is installed on the drive plate 5. Here, the second input terminal 44 is a female terminal, the second output terminal 53 is a male terminal, and the second output terminal 53 is inserted into the second input terminal 44 and electrically connected to the second input terminal 44. Be connected. Of course, in other embodiments, the second input terminal 44 may be a male terminal and the second output terminal 53 may be a female terminal. Here, the second input terminal 44 and the second output terminal 53 both employ 8PIN terminals to supply power to the light source plate 4 and control the PMW signal of the drive plate 5, whereby the white light emitting element 81 is different. White light having a color temperature can be output, and the color light emitting element 82 can output color light of a different color.

In one embodiment of the utility model, specifically, as shown in FIGS. 2, 4 and 6, the first heat radiating member 1 has a structure in which plastic is fitted into aluminum, and the first heat radiating member 1 is The insulating layer 11 and the heat radiating layer 12 installed in order from the outside to the inside are included, and here, the side closer to the light source plate 4 is the inside. Preferably, the heat dissipation layer 12 is made of an aluminum material, whereby the heat dissipation layer 12 has high heat dissipation performance. Since the conductive performance of the heat radiating layer 12 made of an aluminum material is also relatively high, an insulating layer 11 made of plastic is further fitted outside the heat radiating layer 12 in order to prevent an electric shock due to the touch of a human hand. Will be set up.

Since the upper part of the antenna module 6 is covered only by the light bulb cover 2, the metal material tends to block the signal transmitted from the antenna module 6. Therefore, the light bulb cover 2 is a non-metal, and the light bulb cover 2 is made of a transparent material (for example, PVC (Polyvinyl chloride)) so that the white light emitting element 81 and the color light emitting element 82 can easily emit light. Alternatively, it is manufactured from a non-metal material such as PET (Polyethylene terephthalate, polyethylene terephthalate). The signal transmission rate of the antenna 62 is guaranteed by adopting the light bulb cover 2 made of a non-metal material.

The light bulb cover 2 is locked to the insulating layer 11 of the first heat radiating member 1, thereby protecting the drive plate 5, the light source plate 4, and the antenna module 6. Specifically, as further shown in FIGS. 3, 5 and 8, the light bulb cover 2 includes a shell portion 21 and a locking portion 22 extending from the shell portion 21 toward the first heat radiating member 1, and the insulating layer 11 Is provided with an engaging portion 13 that engages with the locking portion 22 along its circumferential direction.

The drive plate 5 is locked to the first heat radiating member 1, the drive plate 5 is electrically connected to the base assembly 3 by the elastic piece 54, and one end of the elastic piece 54 is fixedly connected to the drive plate 5 to be fixedly connected to the elastic piece 54. The other end of the base is fixedly connected to the base assembly 3.

In one embodiment of the utility model, the base assembly 3 includes a base 31 and a pin 32. Here, the base 31 is screwed to the first heat dissipation member 1, the pin 32 is inserted into the base 31, and the pin 32 is used to electrically connect to an external power source.

The specific assembly process of the smart light bulb in Example 1, Example 2, and Example 4 is as follows.

First, the heat radiating layer 12 is put into the insulating layer 11, then the drive plate 5 is locked in the engaging portion 13 of the first heat radiating member 1, the light source plate 4 is attached, and then the light source is light-sourced by a fixing member such as a screw 9. The plate 4 is fixed in the first heat radiating member 1. The light bulb cover 2 is locked to the engaging portion 13 of the first heat radiating member 1, and the light bulb cover 2 and the first heat radiating member 1 are fixedly connected by an adhesive. The base 31 and the first heat radiating member 1 are riveted together with a jig, and the pin 32 is riveted.

Based on the above description, specifically, as shown in FIG. 11, the path for supplying electric power to the white light emitting element 81 and the color light emitting element 82 is as follows. The AC power of the external power source reaches the drive plate 5 via the pin 32, and is then provided to the light source plate 4 by the second output terminal 53 and the second input terminal 44.

The path for supplying power to the antenna 62 is as follows. The AC power of the external power source is transmitted to the drive plate 5 by the pin 32 of the base 31, and is transmitted to the antenna module 6 and the smart integrated chip 63 by the feeding line of the drive plate 5, respectively.

The smart integrated chip 63 has the following control paths for the white light emitting element 81 and the color light emitting element 82. The antenna module 6 receives the control signal and transmits the control signal to the smart integrated chip 63, the smart integrated chip 63 controls the drive plate 5 based on the control signal, and causes the white light emitting element 81 and the color light emitting element 82. Drive to emit light.

The specific mounting process of the smart light bulb in Example 3 is as follows.

The difference from the first, second and fourth embodiments is that the antenna module 6 of the third embodiment is fitted in the light source plate 4, and the second heat radiation member 7 is further between the light source plate 4 and the drive plate 5. Is to be provided.

First, the heat radiating layer 12 is put into the insulating layer 11, then the drive plate 5 is locked in the engaging portion 13 of the first heat radiating member 1, the second heat radiating member 7 is charged, and the substrate 61 is further fitted. The light source plate 4 is arranged on the second heat radiating member 7, and the light source plate 4 and the second heat radiating member 7 are fixed in the first heat radiating member 1 by a fixing member such as a screw 9. After that, the light bulb cover 2 is locked to the engaging portion 13 of the first heat radiating member 1, and the light bulb cover 2 and the first heat radiating member 1 are fixedly connected by an adhesive. Finally, the base assembly 3 and the first heat radiating member 1 are riveted together with a jig, and then the pin 32 is riveted.

Based on the above description, specifically, as shown in FIG. 11, the path for supplying electric power to the white light emitting element 81 and the color light emitting element 82 is as follows. The AC power of the external power source reaches the drive plate 5 via the pin 32, and is then provided to the light source plate 4 by the second output terminal 53 and the second input terminal 44.

The path for supplying power to the antenna 62 is as follows. The AC power of the external power source is transmitted to the drive plate 5 by the pin 32 of the base 31, and is transmitted to the antenna 62 and the smart integrated chip 63 by the first output terminal 51 and the first input terminal 611, respectively.

The smart integrated chip 63 has the following control paths for the white light emitting element 81 and the color light emitting element 82. The antenna 62 receives the control signal and transmits the control signal to the smart integrated chip 63, and the smart integrated chip 63 controls the drive plate 5 based on the control signal to emit the white light emitting element 81 and the color light emitting element 82. Drive to let.

The above is only a preferable example of the Utility Model, and does not limit the Utility Model. Any modifications, equivalent replacements, improvements, etc. made within the spirit and principles of the Utility Model are the Utility Model. Should be included within the scope of protection of.

1-first heat dissipation member, 11-insulation layer, 12-heat dissipation layer, 13-engagement part, 2-bulb cover, 21-shell part, 22-locking part, 3-base assembly, 31-base, 32- Pin, 4-light source plate, 41-retract groove, 42-retract notch, 43-through hole, 44-second input terminal, 45-extension hole, 5-drive plate, 51-first output terminal, 52- Grounding part, 53-second output terminal, 54-elastic piece, 6-antenna module, 61-board, 611-first input terminal, 62-antenna, 63-smart integrated chip, 7-second heat dissipation member, 81- White light emitting element, 811-first chip, 812-second chip, 82-color light emitting element, 821-third chip, 822-fourth chip, 823-fifth chip, 9-screw.

Claims (11)

First heat dissipation member,
A light bulb cover installed at one end of the first heat dissipation member,
A base assembly installed at the other end of the first heat dissipation member,
A light source plate installed in the first heat radiating member and covering one end of the first heat radiating member near the light bulb cover.
A drive plate installed in the first heat radiating member and electrically connected to the base assembly and the light source plate, and an antenna installed in the first heat radiating member and electrically connected to the drive plate. With a module,
A smart light bulb characterized in that the surface of the antenna module facing the light bulb cover is not higher than the surface of the light source plate facing the light bulb cover. The antenna module is installed on the drive plate, and the antenna module has a flat plate-like structure in which the surface facing the light bulb cover is lower than the surface of the light source plate facing the light bulb cover.
The smart light bulb according to claim 1, wherein the antenna module has a ring rod-like structure whose surface facing the light bulb cover is lower than the surface facing the light bulb cover of the light source plate. The smart light bulb according to claim 2, wherein a through hole is provided at a position corresponding to the antenna module of the light source plate. The antenna module includes a substrate and an antenna.
The surface of the substrate facing the light bulb cover and the surface of the light source plate facing the light bulb cover are on the same plane.
The smart light bulb according to claim 1, wherein the antenna is installed on a surface of the substrate facing the light bulb cover, and the protruding height of the antenna is lower than the protruding height of the light emitting element of the light source plate. The smart light bulb according to claim 4, wherein a retracting groove for mounting the substrate is provided in the light source plate, and the substrate is fitted in the retracting groove. The smart light bulb according to claim 5, wherein a retracting notch is provided at a position corresponding to a transmitting end of the antenna on the light source plate, and the retracting notch communicates with the retracting groove. The smart light bulb according to claim 4, wherein a first input terminal is installed on the substrate, and a first output terminal electrically connected to the first input terminal is installed on the drive plate. The smart according to claim 4, wherein the smart light bulb further includes a second heat radiating member, and the second heat radiating member is installed between the driving plate and the light source plate and is attached to the substrate. light bulb. First heat dissipation member,
A light bulb cover installed at one end of the first heat dissipation member,
A base assembly installed at the other end of the first heat dissipation member,
A light source plate installed in the first heat radiating member and covering one end of the first heat radiating member near the light bulb cover.
A drive plate installed in the first heat radiating member and electrically connected to the base assembly and the light source plate, and an antenna installed in the first heat radiating member and electrically connected to the drive plate. With a module,
A smart light bulb characterized in that the surface of the antenna module facing the light bulb cover is higher than the surface of the light source plate facing the light bulb cover, and the antenna module is installed perpendicular to the light source plate. The method according to any one of claims 1 to 9, wherein the smart light bulb further includes a grounding portion, and the grounding portion is installed on the drive plate and conducts by contacting with the first heat radiating member. Smart light bulb. The smart light bulb further includes a white light emitting element and a color light emitting element.
The white light emitting element is installed on the light source plate, includes a first chip and a second chip, and the light emitted from the first chip is mixed with the light emitted from the second chip.
The color light emitting element is installed on the light source plate and includes a third chip, a fourth chip, and a fifth chip, and the light emitted from the third chip, the light emitted from the fourth chip, and the fifth chip. The smart light bulb according to claim 10, wherein the three elements of light emitted from the light source are mixed.

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