CN212480871U - Energy-gathering area array LED intelligent bulb and intelligent lamp - Google Patents

Abstract

The utility model provides an it can area array LED intelligence bulb and intelligent lamp to gather belongs to the technical field of LED bulb. The energy-gathering area array LED intelligent bulb comprises a columnar lamp wick, wherein the columnar lamp wick comprises a controller, an energy accumulator, a tubular lamp body and a flexible LED lamp strip, the flexible LED lamp strip is wound on the outer side face of the tubular lamp body to form a columnar area array LED light-emitting face, the energy accumulator and the controller are arranged in the tubular lamp body, and the flexible LED lamp strip, the energy accumulator and a screw short lamp holder are connected with the controller. The energy-gathering area array LED bulb changes the single function that the traditional bulb directly converts input electric energy into light energy, gathers weak and small currents which are gathered to be lower than a directly-driven light source to the self-carried energy accumulator through the self-carried energy accumulator, and drives the area array LED light source in a pulse mode to obtain strong light output by using output currents which are several times higher than input currents under the control of the controller.

Description

Energy-gathering area array LED intelligent bulb and intelligent lamp

Technical Field

The utility model relates to a technical field of LED bulb, in particular to gather and to install intelligent lamp of this intelligent bulb with area array LED intelligent bulb.

Background

Conventional incandescent light bulbs have been replaced by LED light bulbs, but the concept of light bulbs is also limited to the ability to directly convert input electrical energy into light energy. Along with the continuous improvement of LED light efficiency, life also doubles and prolongs, especially the current has entered the network era, and traditional circular telegram is opened the lamp, the control mode that cuts off the lamp of cutting off the power supply has been carried out intelligence management and control by the network completely. Outside the switch function through intelligent management and control illumination lamp, realize the beautiful developments light through digital intelligent control light formation of image, intelligent control will bring unlimited extension space for the working method of bulb.

Because the actual time that people need illumination every day is limited, only accounts for about 10% -20% of 24 hours of a whole day, and illumination power consumption is in the peak period of power consumption at night, the electricity price is high, and the power consumption load of the peak period of a power grid is increased. If we can charge the energy-gathering area array LED bulb for 24 hours by only consuming 2W of electricity, and can enable the energy-gathering bulb with the nominal power of 20W to normally work, not only can effectively reduce 90% of load of an illumination circuit, but also can play a role in shifting peaks and filling valleys, can provide uninterrupted illumination and uninterrupted low-voltage energy storage, and has obvious promotion on area safety construction and social benefits.

The energy-gathered area array LED intelligent bulb is more suitable for a new energy lamp powered by photovoltaic, and is not limited by direct irradiation of sunlight due to the fact that the energy-gathered area array LED intelligent bulb is continuously charged by standing on low current, so that the energy accumulator is effectively prevented from being damaged by overcharging, and charging safety is ensured.

In order to realize the function of long-flow energy-gathering charging of thin water, the internal resistance of a charging and energy storage loop is required to be very small, so that a large current which is tens of times higher than the input current can be instantly released to drive an area array LED light source, and the best illumination effect can be obtained by consuming the least electric energy.

SUMMERY OF THE UTILITY MODEL

The utility model provides an it can area array LED intelligence bulb to gather can change traditional bulb and directly convert the input electric energy into the single working method of light energy. After the gathered weak and small current which is lower than the current which can directly and normally drive the light source can be gathered to the energy accumulator through the energy accumulator, the area array LED light source is driven by the control of the controller in a pulse mode by the output current which is several times higher than the input current so as to obtain the instantaneous ultrahigh strong light output.

The utility model provides an it can area array LED intelligence bulb, includes columnar order wick, wherein, columnar order wick includes controller, energy memory, tubular lamp body and flexible LED lamp area, flexible LED lamp area winding is in order to form columnar order area array LED light emitting area on tubular lamp body's the lateral surface, the energy memory with the controller sets up in the tubular lamp body, flexible LED lamp area with the energy memory all with the controller is connected.

The utility model discloses a make area array LED light source start to have enough high light intensity output in the twinkling of an eye, at first will let the light source have enough big light emitting area, splice into cylinder type area array LED light emitting area with the mode of coiling through the flexible LED lamp area on tubular lamp body's surface and just can have enough big light emitting area. The length of the flexible LED lamp strip is randomly selected from one to tens of meters, the flexible LED lamp strip with a certain length is selected according to the size requirement of the light-emitting surface to be wound on tubular lamp bodies with different diameters and different heights, and the manufactured LED columnar lamp core can meet the requirement of the light-emitting surface.

The flexible LED lamp strip adopts conventional paster lamp pearls such as 2835, 3030, also can adopt flip-chip direct encapsulation to give out light through the fluorescent silica gel strip on the flexible substrate, and different width adjustment lamp area intervals can be selected for use in the flexible LED lamp strip, and the matching of load is satisfied in adjustment lamp pearl quantity.

The energy accumulator with corresponding capacity can be arranged according to the size of the inner space of the columnar lamp wick, the energy accumulator can adopt a super capacitor or a lithium battery with very small internal resistance, and the energy accumulator not only can adapt to the injection and aggregation of small current and thin water in a long flow type, but also can adapt to the instant discharge of large current, so that the light output intensity of the area array LED light source can reach the peak value instantly. A single chip microcomputer is arranged in the controller, and the controller controls the energy accumulator to charge and discharge.

Preferably, the energy-gathering area array LED intelligent bulb can adopt a structure of a single-end screw cap to realize fixation and electricity taking, or can also adopt a structure of lamp bases at two ends to realize fixation and electricity taking, or can also directly fix the cylindrical lamp core on the installation surface and adopt a wire connection mode to take electricity.

Preferably, the energy-gathering area array LED intelligent bulb further comprises a screw short lamp cap and a lamp body front cover, wherein the screw short lamp cap and the lamp body front cover are respectively arranged at two ends of the tubular lamp body; the LED lamp strip comprises a tubular lamp body and is characterized in that a tubular lamp body notch is formed in the tubular lamp body, and a power supply input end of the flexible LED lamp strip penetrates through the tubular lamp body notch and extends into the inner side of the tubular lamp body. The controller is arranged on the inner side surface of the front cover of the lamp body; the lamp body base is arranged at the bottom of the tubular lamp body, and the screw short lamp holder is arranged outside the lamp body base.

The screw short lamp holder is arranged on the outer side of the bottom of the tubular lamp body, the energy-gathering area array LED intelligent bulb is screwed into a conventional screw lamp holder and cannot get electricity, so that the use safety is ensured, and if the commercial power needs to be got, the commercial power is reduced to the rear of the rated voltage of the energy-gathering area array LED bulb through a conversion connector and can normally work. In addition, a controller is arranged on the inner side of the front cover of the tubular lamp body and is responsible for controlling charging and discharging of the energy accumulator, and the controller is respectively connected with the flexible LED lamp strip, the energy accumulator and the screw cap through three groups of six wires.

Preferably, the surface of the column-shaped lampwick can be provided with a diffusion lampshade, so that the luminous surface of the bulb is more uniform and more attractive; of course, the pillar-shaped wick may be exposed.

Preferably, the top of the energy-gathering area array LED intelligent bulb can carry various intelligent electrical accessories, for example, a monitoring camera can be carried, and power supply support is provided for the monitoring camera.

Preferably, the energy-gathering area array LED intelligent bulb is connected with a state indicator, and the state indicator is used for indicating the working state and/or the electric energy storage capacity of the bulb. The diffusion lampshade is provided with an indicator light window for indicating the working state of the bulb.

Preferably, the control mode of the energy-gathering area array LED intelligent bulb can be supported by a single chip microcomputer, an infrared remote control module, a Bluetooth module and a network control function module. The duty ratio of an output power supply can be adjusted by setting or changing the PWM signal in an infrared remote control or 2.4G Bluetooth control mode, and the setting is controlled or the real-time control is carried out by direct networking.

The controller controls the working state of the area array LED light source in a PWM digital mode, and controls the actual energy consumption of the area array LED bulb in a mode of changing the duty ratio; on the basis of improving the lighting effect of the LED light source and increasing the light output of the bulb by adopting the novel technology of the high-lighting-effect LED chip and the area array light source, the energy consumption is further reduced by utilizing the super-large lighting surface of the area array LED light source and compressing the actual working time of the energy-gathered area array LED intelligent bulb within the national standard range of vision tolerance, and the optimal visual lighting effect is obtained under the condition of limited energy consumption by integrating three technical measures.

Because the energy-gathered area array LED intelligent bulb is safe and flexible in a small charging current power taking mode, the energy-gathered area array LED intelligent bulb can be directly charged by adopting electric energy generated by photovoltaic through connection of the lamp holder and the photovoltaic panel; and the alternating current 220V commercial power can be used for charging through the adapter. Due to the fact that charging current is small, charging energy consumption is similar to that of mobile phone charging, and the energy-gathering area array LED intelligent bulb can be used for public area illumination. By adopting the energy-gathering area array LED intelligent bulb, the limitation of sunlight and illumination angles on a new energy lamp can be eliminated, and ultra-limited weak and small charging current obtained by the photovoltaic panel is gathered to provide an adaptive energy source for the high-efficiency LED light source so as to meet the basic requirement of the lighting environment.

Drawings

In order to more clearly illustrate the embodiments and technical solutions of the present invention, the drawings that need to be used will be briefly described below through descriptions of embodiments or prior art, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is an appearance schematic diagram of an energy-gathered area array LED intelligent bulb provided by the present invention;

fig. 2 is a schematic diagram of an internal structure of the energy-gathered area array LED intelligent bulb provided by the present invention;

fig. 3 is an appearance schematic diagram of a pillar-shaped wick of an energy-gathered area array LED smart bulb provided by the present invention;

fig. 4 is an explosion diagram of the pillar-shaped wick of the energy-gathered area array LED smart bulb provided by the present invention;

fig. 5 is a schematic structural view of a flexible LED strip provided by the present invention, which adopts a patch lamp bead;

fig. 6 is a schematic structural view of a flexible LED strip packaged by a COB method according to the present invention;

fig. 7 is a schematic structural view of the energy-gathered area array LED smart bulb provided by the present invention connected to an adapter;

fig. 8 is an explosion schematic diagram of the energy-gathered area array LED intelligent bulb and the adapter provided by the present invention;

fig. 9 is a schematic diagram of the energy-gathering area array LED intelligent bulb provided by the present invention used in cooperation with a solar photovoltaic panel with a lamp holder;

fig. 10 is an explosion schematic diagram of the energy-gathering area array LED smart bulb and the solar photovoltaic panel with a lamp holder provided by the present invention;

fig. 11 is another schematic view of the energy-gathering area array LED smart bulb provided by the present invention used in cooperation with a solar photovoltaic panel having a lamp holder;

fig. 12 is an explosion schematic diagram of the energy-gathering area array LED smart bulb and the solar photovoltaic panel with a lamp holder provided by the present invention;

fig. 13 is an application schematic diagram of a solar garden lamp employing a shaped-energy area-array LED smart bulb provided by the present invention;

fig. 14 is a schematic structural diagram of a double-end energy-gathering area array LED intelligent bulb provided by the present invention;

fig. 15 is a schematic structural view of a projection lamp adopting a double-end energy-gathering area array LED intelligent bulb provided by the present invention;

fig. 16 is the utility model provides a take surveillance camera head gather ability area array LED intelligence bulb's structural schematic.

In the figure: 1-energy-gathering area array LED intelligent bulb; 2-status indicator lights; 3-diffusion lampshade; 4-column type wick; 5-screw short lamp holder; 6-a tubular lamp body; 7-lamp body front cover; 8-a flexible LED strip; 9-lamp body base; 10-a controller; 11-a charged negative electrode lead; 12-charging positive electrode lead; 13-energy storage negative electrode lead; 14-energy storage positive electrode lead; 15-lamp with negative wire; 16-lamp with positive wire; 17-a tubular lamp body recess; 18-a lamp with a negative pad; 19-a lamp with a positive pad; 20-energy storage negative pad; 21-energy storage positive pad; 22-an energy storage; 23-screw short lamp holder shell; 24-a top welding plate of the screw lamp holder; 25-LED paster lamp beads; 26-lamp with negative pole circuit; 27-lamp with positive circuit; 28-a flexible substrate; 29-fluorescent silica gel strips; 30-flip-chip LED chip; 31-a crossover joint; 32-screw lamp cap; 33-a voltage reduction module; 34-screw short lamp holder; 35-photovoltaic panel back; 36-photovoltaic panel front side; 37-courtyard lamp cover; 38-yard lamp base; 39-courtyard lamp pole; 40-a bi-terminal post-type lamp body end cap; 41-negative pole lamp base of double-end bulb; 42-double-end energy-gathering area array LED intelligent bulb; 43-double-end bulb positive lamp base; 44-a light projector fixture; 45-lamp support; 46-monitoring camera.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer, the technical solutions of the present invention will be described in detail below. It is to be understood that the embodiments described are only some embodiments of the invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

Fig. 1 is an appearance diagram of an energy-gathering area array LED intelligent bulb 1, and a status indicator lamp 2 for indicating the working status of the bulb and the storage capacity of electric energy is arranged on the top of the energy-gathering area array LED intelligent bulb.

Fig. 2 is a schematic diagram of the internal structure of an energy-gathering area array LED intelligent bulb 1, which includes a diffusion lampshade 3, a cylindrical lampwick 4 and a screw short lamp holder 5.

Fig. 3 is a schematic structural diagram of a cylindrical lampwick 4, and fig. 3 illustrates a tubular lamp body 6, a lamp body front cover 7, a flexible LED strip 8, a lamp body base 9, and a screw cap 5.

Fig. 4 is a schematic diagram of the internal structure of a columnar lampwick 4, and an embodiment of the energy-gathered area array LED intelligent bulb 1 is further explained with reference to the internal structure diagram of the columnar lampwick 4 in fig. 4: a flexible LED strip 8 with a length of more than 1 meter is wound on the surface of the tubular lamp body 6, and a power input end of the flexible LED strip 8 passes through the tubular lamp body notch 17 and enters the inner side of the tubular lamp body 6 to be connected with a corresponding lead on the controller 10. The lamp strip cathode bonding pad 18 is connected with a lamp strip cathode lead 15 on the controller 10; the lamp strip positive electrode bonding pad 19 is connected with the lamp strip positive electrode lead 16 on the controller 10. Because the length of the flexible LED lamp strip 8 can reach more than tens of meters, the quantity of the LED chips which are densely connected in parallel can be thousands, and an area array LED cylindrical huge luminous body is formed to obtain instant ultrahigh light intensity output.

The energy storage negative lead 13 on the controller 10 passes through the inner side of the tubular lamp body 6 to be connected with the energy storage negative pad 20 on the energy storage device 22; the energy storage positive lead 14 on the control unit 10 is connected to the energy storage positive bonding pad 21 on the energy storage 22 through the inner side of the tubular lamp body 6. The energy storage 22 needs to be a 2.7V super capacitor, a 3.2V lithium iron battery or a 3.7V ternary lithium battery with small internal resistance.

A charging negative lead 11 on the controller 10 passes through the inner side of the tubular lamp body 6 and is connected with a screw short lamp cap shell 23 of a screw short lamp cap 5 on the lamp body base 9; the charging positive conductor 12 of the controller 10 is connected to the screw cap top pad 24 of the screw cap 5 through the inside of the tubular lamp body 6.

The controller 10 is internally provided with a single chip microcomputer for controlling the charging and discharging of the energy storage device 22, and the duty ratio of an output power supply can be adjusted by changing a PWM signal in a set or infrared remote control and 2.4G Bluetooth control mode, so that the energy-gathered area array LED intelligent bulb 1 can still provide the best visual lighting effect on the premise of consuming a small amount of electric energy.

Fig. 5 is a schematic structural view of a flexible LED strip 8 manufactured by using a conventional LED patch lamp bead 25, and the production process is simple and the cost is low.

Fig. 6 is a schematic structural view of a flexible LED strip 8 manufactured by a COB process by directly packaging an inverted LED chip 30, which can integrate more LED chips and has better visual effect.

Fig. 7 is an application example of energy-collecting area array LED intelligent bulb 1 charged by commercial power, because the working voltages are different, the screw cap 5 on the energy-collecting area array LED intelligent bulb 1 needs to be screwed into the screw cap short lamp holder 34 on the adapter 31, and the screw cap 32 on the adapter 31 ensures that the energy-collecting area array LED intelligent bulb 1 can safely get electricity from the screw cap short lamp holder 34 through the adapter 31. The adapter 31 is provided with an ac/dc voltage reduction module 33, and the input end of the ac/dc voltage reduction module is connected with the screw lamp head 32, and the output end of the ac/dc voltage reduction module is connected with the screw short lamp holder 34.

Fig. 8 is an application example of the energy-gathered area array LED intelligent bulb 1 for taking electricity from a photovoltaic panel, wherein a screw socket 34 is installed on the back surface of the photovoltaic panel, a screw socket of the screw socket 34 is connected with the negative electrode of the photovoltaic panel, and a central contact at the bottom of the screw socket 34 is connected with the positive electrode of the photovoltaic panel. The front 36 of the photovoltaic panel is illuminated to generate electric energy to charge the energy-gathered area array LED intelligent bulb.

Fig. 9 is a garden lamp cover 37 on which the energy-gathering area array LED intelligent bulb 1 and the solar photovoltaic panel are combined and fixed, and the garden lamp cover is very convenient to use by fixing the garden lamp holder 38 and the garden lamp post 39.

Fig. 10 is a schematic structural diagram of an LED intelligent bulb 42 adopting a double-end energy-gathering area array. In the figure, two ends of a columnar lamp core 4 are respectively provided with a double-end columnar lamp body end cover 40, and a double-end bulb cathode lamp base 41 and a double-end bulb anode lamp base 43 on the double-end columnar lamp body end cover 40 are respectively arranged on the outer side of the double-end columnar lamp body end cover 40 and are fixed with a matched double-end lamp holder to take electricity.

Fig. 11 is an embodiment of a double-ended energy concentrating area array LED smart bulb 42 for use in a projector. The light projector 44 is shown secured to the mounting surface by a light fixture bracket 45.

Fig. 12 shows an embodiment in which the energy-gathering area-array LED smart bulb 1 is used as a low-voltage energy platform, and can provide surplus lighting power to various onboard smart electrical accessories, in which the monitoring camera 46 is one of the smart electrical accessories.

The protection scope of the present invention is not limited thereto, and any person skilled in the art can easily think of changes or replacements within the technical scope of the present invention, which should be covered by the protection scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (10)

1. An energy-gathering area array LED intelligent bulb is characterized by comprising a column-shaped lamp wick (4), wherein,

columnar lamp wick (4) include controller (10), energy storage ware (22), tubular lamp body (6) and flexible LED lamp area (8), flexible LED lamp area (8) winding is in order to form columnar order face array LED light emitting area on the lateral surface of tubular lamp body (6), energy storage ware (22) with controller (10) set up in tubular lamp body (6), flexible LED lamp area (8) with energy storage ware (22) all with controller (10) are connected.

2. The energy-gathering area array LED intelligent bulb as claimed in claim 1, wherein the energy-gathering area array LED intelligent bulb adopts a single-ended screw cap structure or a double-ended lamp base structure or adopts a wire connection mode after the cylindrical lamp core (4) is directly fixed for getting electricity.

3. The energy-gathering area array LED intelligent bulb as claimed in claim 1 or 2, characterized in that the energy-gathering area array LED intelligent bulb further comprises a screw short lamp cap (5) and a lamp body front cover (7), wherein the screw short lamp cap (5) and the lamp body front cover (7) are respectively arranged at two ends of the tubular lamp body (6);

a tubular lamp body notch (17) is formed in the tubular lamp body (6), and a power supply input end of the flexible LED lamp strip (8) penetrates through the tubular lamp body notch (17) and extends into the inner side of the tubular lamp body (6).

4. The energy-gathered area array LED intelligent bulb as claimed in claim 3, wherein the controller (10) is arranged on the inner side surface of the front cover (7) of the lamp body; a lamp body base (9) is arranged at the bottom of the tubular lamp body (6), and the screw short lamp cap (5) is arranged outside the lamp body base (9);

a lamp strip negative electrode bonding pad (18) on the flexible LED lamp strip (8) is connected with a lamp strip negative electrode lead (15) on the controller (10), and a lamp strip positive electrode bonding pad (19) on the flexible LED lamp strip (8) is connected with a lamp strip positive electrode lead (16) on the controller (10);

an energy storage negative electrode bonding pad (20) on the energy storage device (22) is connected with an energy storage negative electrode lead (13) on the controller (10), and an energy storage positive electrode bonding pad (21) on the energy storage device (22) is connected with an energy storage positive electrode lead (14) on the controller (10);

the charging negative electrode lead (11) on the controller (10) enters the tubular lamp body (6) to be connected with the screw cap short lamp holder shell (23) of the screw cap short lamp holder (5), and the charging positive electrode lead (12) on the controller (10) passes through the tubular lamp body (6) to be connected with a screw cap top bonding pad (24) of the screw cap short lamp holder (5).

5. The energy-gathering area array LED intelligent bulb as claimed in claim 1, further comprising a diffusion lampshade (3), wherein the diffusion lampshade (3) is sleeved outside the column-shaped lamp core (4); or the column-shaped lamp wick (4) is exposed outside.

6. The energy-gathering area array LED intelligent bulb as claimed in claim 1, wherein intelligent electrical accessories are connected to the energy-gathering area array LED intelligent bulb.

7. The energy-gathering area array LED intelligent bulb as claimed in claim 1, wherein a status indicator lamp (2) is connected to the energy-gathering area array LED intelligent bulb, and the status indicator lamp (2) is used for indicating the working state and/or the electric energy storage capacity of the bulb.

8. The energy-gathering area array LED intelligent bulb as claimed in claim 1, wherein the energy-gathering area array LED intelligent bulb is connected with a photovoltaic panel, or a conversion connector (31) convenient for being connected with a mains supply is arranged on the energy-gathering area array LED intelligent bulb.

9. The energy-gathered area array LED intelligent bulb is characterized by further comprising an infrared remote sensing module and/or a Bluetooth module.

10. An intelligent lamp, comprising the energy-gathered area array LED intelligent bulb as claimed in any one of claims 1 to 9.

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