CN108954024B - Out-of-order LED light source - Google Patents

Abstract

The invention relates to a disorder LED light source, which comprises a power device, a space structure and at least one LED light-emitting monomer; the space structure is provided with a transparent shell and a cavity arranged in the transparent shell, the inner wall of the transparent shell is provided with a buffer structure, the top of the transparent shell is partially spherical, and the bottom of the transparent shell is provided with an opening communicated with the cavity; the power device seals the opening, and power device sets up collecting region and emission region, and the LED luminous monomer is collected and is transmitted to the emission region in the collecting region, and the LED luminous monomer is launched when the emission region obtains the LED luminous monomer of collecting region transmission. The LED luminous single body emitting mode completely different from the traditional luminous mode is adopted, the LED luminous single body emitting mode is collected and continuously emitted after emitting, and therefore the chaotic state illumination effect is achieved, the effect is different when the LED luminous single body emitting mode is started or emitted every time, and the diversified chaotic dynamic illumination effect can be achieved by matching with the LED luminous single body emitting light.

Description

Out-of-order LED light source

Technical Field

The invention relates to the field of LED luminescence, in particular to an out-of-order LED light source.

Background

The LED is referred to as LED (light Emitting diode), and the LED light source is an LED light source, but the existing LED light source usually emits light only in a predetermined direction, and lacks of a disordered lighting effect.

Disclosure of Invention

Based on this, it is necessary to provide an out-of-order LED light source.

An out-of-order LED light source, comprising: the LED light-emitting device comprises a power device, a spatial structure and at least one LED light-emitting monomer; the space structure is provided with a transparent shell and a cavity arranged in the transparent shell, the inner wall of the transparent shell is provided with a buffer structure, the top of the transparent shell is in a partially spherical shape, and the bottom of the transparent shell is provided with an opening communicated with the cavity; the power device seals the opening, the power device is provided with a collecting region and an emitting region, the collecting region collects the LED luminous monomers and transmits the LED luminous monomers to the emitting region, and the emitting region emits the LED luminous monomers when the LED luminous monomers transmitted by the collecting region are obtained.

The disorder LED light source adopts a mode of emitting LED luminous monomers which is completely different from the traditional luminous mode, and the LED luminous monomers are collected and continuously emitted after being emitted, so that the disorder state illumination effect is obtained, the effect is different when being started or emitted every time, and the LED luminous monomers are matched to emit light, so that the diversified disorder dynamic illumination effect can be obtained.

In one embodiment, the collection region is disposed at the opening and the collection region closes the opening.

In one embodiment, the collection region is funnel-shaped.

In one embodiment, a transmission belt is arranged between the collecting region and the emitting region of the power device, and the collecting region transmits the LED light-emitting monomer to the emitting region through the transmission belt.

In one embodiment, the outlet of the emission region is disposed beside the collection region.

In one embodiment, the LED light emitting cells include a polyhedral structure.

In one embodiment, the LED light emitting unit includes a sphere structure.

In one embodiment, a linear track is disposed in the emitting area.

In one embodiment, the included angle between the linear track and the ground level is 70-90 degrees.

In one embodiment, the emitting area has a spiral track disposed therein.

In one embodiment, the outer surface of the LED luminous monomer is provided with an elastic body.

In one embodiment, the elastomer is arranged on a non-light-emitting area of the outer surface of the LED light-emitting monomer.

In one embodiment, the elastomer is a transparent body.

In one embodiment, the power device is provided with a plurality of the emission areas.

Further, the power device is further provided with an emitter, the collecting region collects the LED luminous monomers and transmits the LED luminous monomers to the emitting region, the emitter is arranged in the emitting region, and the emitter emits the LED luminous monomers when the emitting region obtains the LED luminous monomers transmitted by the collecting region.

Drawings

FIG. 1 is a schematic diagram of one embodiment of the present invention.

Fig. 2 is a schematic diagram of another embodiment of the present invention.

Fig. 3 is a schematic diagram of another embodiment of the present invention.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

One embodiment of the present invention is an out-of-order LED light source, comprising: the LED light-emitting device comprises a power device, a spatial structure and at least one LED light-emitting monomer; the space structure is provided with a transparent shell and a cavity arranged in the transparent shell, the inner wall of the transparent shell is provided with a buffer structure, the top of the transparent shell is in a partially spherical shape, and the bottom of the transparent shell is provided with an opening communicated with the cavity; the power device seals the opening, the power device is provided with a collecting region and an emitting region, the collecting region collects the LED luminous monomer and transmits the LED luminous monomer to the emitting region, and the emitting region emits the LED luminous monomer when obtaining the LED luminous monomer. In one embodiment, the emitting region emits the LED light-emitting cells when the LED light-emitting cells are directly obtained. In one embodiment, the emitting region emits the LED light-emitting cells when the LED light-emitting cells are obtained through the collecting region.

One embodiment of the present invention is an out-of-order LED light source, comprising: the LED light-emitting device comprises a power device, a spatial structure and at least one LED light-emitting monomer; the space structure is provided with a transparent shell and a cavity arranged in the transparent shell, the inner wall of the transparent shell is provided with a buffer structure, the top of the transparent shell is in a partially spherical shape, and the bottom of the transparent shell is provided with an opening communicated with the cavity; the power device seals the opening, the power device is provided with a collecting region and an emitting region, the collecting region collects the LED luminous monomers and transmits the LED luminous monomers to the emitting region, and the emitting region emits the LED luminous monomers when the LED luminous monomers transmitted by the collecting region are obtained. The disorder LED light source adopts a mode of emitting LED luminous monomers which is completely different from the traditional luminous mode, and the LED luminous monomers are collected and continuously emitted after being emitted, so that the disorder state illumination effect is obtained, the effect is different when being started or emitted every time, and the LED luminous monomers are matched to emit light, so that the diversified disorder dynamic illumination effect can be obtained.

Further, in one embodiment, the LED light emitting cells are configured to emit light when being emitted or moved; in one embodiment, the LED luminous unit is provided with a switch which is used for controlling the LED luminous unit to emit light when being emitted or moved; in one embodiment, the switch is a vibration switch or a dynamic balance switch; further, the number of the LED light emitting units is plural, for example, the disorder LED light source is provided with 5, 10, 20 or 100 LED light emitting units. Further, the number of the LED light emitting units is proportional to the volume of the cavity, and in one embodiment, the value obtained by dividing the volume of the cavity by 4000 to 9000 cubic centimeters is the number of the LED light emitting units. In one embodiment, the value obtained by dividing the volume of the cavity by 8000 cubic centimeters is the number of the LED light-emitting monomers. Further, the maximum width of the LED light-emitting unit is proportional to the volume of the cavity, and in one embodiment, the LED light-emitting unit is a sphere with a diameter proportional to the volume of the cavity; in one embodiment, the maximum width of the LED light-emitting unit is 1 to 5 cm, and the value of the maximum width is proportional to the volume of the cavity. The design can make the LED luminous monomer have certain quantity and volume in the cavity, and the luminous of LED luminous monomer is cooperated, thereby obtaining a changeable chaotic dynamic illumination effect. Further, in one embodiment, the transparent shell is a glass cylinder or is made of PMMA, PP, PVC, PET, PC, PS or ABS, and further, the transparent shell is provided with a light-transmitting region for transmitting light of the LED light-emitting monomer. Furthermore, the transparent shell is provided with a shielding area, and the shielding area is used for shielding the light of the LED light-emitting monomer. Further, the transparent shell is provided with a plurality of shielding areas, the shielding areas are arranged at intervals, in one embodiment, the shielding areas are circular areas, and the diameter of each shielding area is 70% -90% of the diameter of the LED light-emitting monomer. Furthermore, the transparent shell is provided with a light-transmitting area and a plurality of circular shielding areas distributed in the light-transmitting area at intervals, the circular shielding areas are arranged at intervals, the diameter of each circular shielding area is 70% -90% of the diameter of the LED light-emitting monomer, and the total area of each circular shielding area is 8% -12% of the area of the light-transmitting area. The design is such that the light emitted by the LED luminous monomer in the movement process can often but not always transmit out of the transparent shell, thereby adding the flashing property to the lighting effect and having a random illumination effect which is not artificially controlled. Furthermore, the transparent shell is provided with a through groove, so that on one hand, light transmission is facilitated, and on the other hand, heat dissipation is facilitated. Furthermore, a plurality of through grooves which are parallel to each other are formed in the transparent shell, and it can be understood that the parallel to each other means that the through grooves or extension lines thereof are parallel to each other; further, the wall of the through groove is provided with an internal reflection coating, and the reflection direction of the internal reflection coating faces to the inside of the transparent shell; such design is favorable to realizing the cell body light-emitting of logical groove and transparent casing inside scattering in order to follow transparent casing's pipeline printing opacity. Further, in one embodiment, the buffer structure includes an elastic pad and a fluorescent layer covering the entire surface of the elastic pad facing the cavity, and the elastic pad and the fluorescent layer are used for generating contact deformation when the LED light-emitting units collide; the fluorescent layer is coated with fluorescent powder and used for emitting light in a dark environment; therefore, when the LED luminous monomers collide with the fluorescent layer, the elastic cushion body is pressed to deform, so that the fluorescent light changes, the dynamic effect of the disorder LED light source is further improved, and the better disorder dynamic change effect of the light source is achieved by matching with the buffer structures and the light emission and collision of the LED luminous monomers.

In one embodiment, the outer surface of the LED luminous monomer is provided with an elastic body. In one embodiment, the elastomer is arranged on a non-light-emitting area of the outer surface of the LED light-emitting monomer. In one embodiment, the elastomer is a transparent body. Therefore, the LED luminous monomer can be protected to a certain extent, and the service life of the LED luminous monomer is prolonged. Further, in one embodiment, an elastic body and/or a light-transmitting protective layer are arranged on the outer surface of the shell of the LED light-emitting unit. In one embodiment, the light-transmitting protective layer completely covers the shell of the LED light-emitting monomer. In one embodiment, the light-transmitting protective layer is made of PMMA, PP, PVC, PET, PC, PS or ABS. Further, the light-transmitting protective layer is made of a flexible light-transmitting material. Therefore, the light of the LED luminous monomer can be transmitted out, and the LED luminous monomer is protected from being damaged by collision. In one embodiment, the elastic body is a flexible layer structure, and the flexible layer structure is provided with a through hole at the light emitting position of the LED light emitting unit. In one embodiment, the through holes are in the shape of a cylinder or a truncated cone; in one embodiment, the through hole is in a shape of a truncated cone, the smaller bottom surface of the truncated cone faces the LED light-emitting unit, and the larger bottom surface of the truncated cone faces the outside. Further, the flexible layer structure is made of a non-transparent material, and the through holes are filled with a light-transmitting material to form a cylinder or a truncated cone, wherein the light-transmitting material is PMMA, PP, PVC, PET, PC, PS or ABS, for example. Furthermore, air bubbles which are not uniformly distributed are arranged inside the cylinder or the circular truncated cone body so as to enhance the scattering effect of the transmitted light.

Further, in one embodiment, an energy supply module, a control module and at least one LED lamp are arranged inside a housing of the LED light emitting unit, a lamp cap of each LED lamp is exposed on the housing, and the energy supply module is connected to each LED lamp through the control module. Furthermore, the shell is provided with lamp holes corresponding to the number of the LED lamps, and lamp caps of the LED lamps are embedded in the lamp holes in a one-to-one correspondence manner. Further, the lamp caps of the LED lamps are uniformly distributed on the shell of the LED light-emitting monomer and integrally form a ring. Further, the lamp caps of the LED lamps are uniformly distributed on the shell of the LED light-emitting monomer and integrally form a plurality of parallel rings. Further, the lamp caps of the LED lamps are uniformly distributed on the outer shell of the LED light-emitting monomer and form a regular polyhedron integrally, the regular polyhedron comprises a regular tetrahedron, a regular hexahedron, a regular octahedron, a regular 12-face body or a regular 20-face body, in one embodiment, the lamp caps of six LED lamps are uniformly distributed on the outer shell of the LED light-emitting monomer to form a regular octahedron integrally; in one embodiment, the lamp caps of the eight LED lamps are uniformly distributed on the shell of the LED light-emitting monomer to form a regular hexahedron; the rest of the examples are analogized. Furthermore, a flexible layer structure is arranged on the shell of the LED light-emitting monomer, through holes are respectively formed in each light-emitting position of the LED light-emitting monomer by the flexible layer structure, a light-transmitting material is filled in each through hole to form a cylinder or a circular truncated cone, and air bubbles which are not uniformly distributed are arranged in each cylinder or circular truncated cone to enhance the scattering effect of the transmitted light.

In one embodiment, the energy supply module is provided with a storage battery and a wireless charging unit which are connected. In one embodiment, the battery is a lithium ion battery. In one embodiment, a wireless charging coil is arranged inside the transparent shell, and the transparent shell dynamic light source further comprises a wireless charging device connected with the wireless charging coil; the wireless charging device wirelessly charges the storage battery through the wireless charging coil and the wireless charging unit. Therefore, the LED luminous unit can be charged without being taken out, so that the LED luminous unit can be used for a long time in a closed environment, is particularly suitable for a completely closed transparent shell, and avoids dust from entering the transparent shell. Further, the control module is a wireless control module and is used for receiving an external control signal to switch on or switch off the connection between the energy supply module and each LED lamp, so that a user or an administrator can externally control the LED light-emitting monomer to emit light or extinguish. Further, the control modules of the LED light-emitting monomers are uniformly arranged and used for uniformly receiving external control signals and simultaneously conducting or simultaneously cutting off the connection between the energy supply module and the LED lamps.

Further, in one embodiment, the cavity has a plurality of interconnected airspaces, at least one collision body is suspended in each airspace, and the collision body includes an LED structure for emitting light of random wavelength in a period of random length while shaking after being collided, thereby increasing the dynamic disorder illumination effect of the disorder LED light source. In one embodiment, the collision body comprises an installation part, and a hoisting part, a lithium battery, an LED structure, a timer, a vibrator, a random number generator and a control module which are respectively and fixedly installed on the installation part, wherein the hoisting part is used for hoisting the collision body in a space, the lithium battery is respectively connected with the control module, the LED structure, the timer and the random number generator and is used for supplying energy, the vibrator is connected with the control module, the control module is respectively connected with the LED structure, the timer and the random number generator, the vibrator is used for starting the control module when vibration occurs, the control module is used for obtaining a time random length within a preset range and a random wavelength within the preset range from the random number generator when starting, and controlling the LED structure to emit random wavelength light in a time period of the random length, the timer is used for timing and turning off the control module after a time period of random length is reached so as to stop the LED structure from emitting light.

In one embodiment, as shown in FIG. 1, an out-of-order LED light source comprises: a power device 300, a spatial structure and at least one LED light-emitting unit 400; the space structure comprises a transparent shell 100 and a cavity 200 arranged in the transparent shell, the inner wall of the transparent shell is provided with a buffer structure 110, the top 120 of the transparent shell is partially spherical, and the bottom of the transparent shell is provided with an opening 130 communicated with the cavity 200; the power device 300 closes the opening, the power device is provided with a collecting region 310 and an emitting region 320, the collecting region collects the LED luminous monomers and transmits the LED luminous monomers to the emitting region, and the emitting region emits the LED luminous monomers when the LED luminous monomers transmitted by the collecting region are obtained. In one embodiment, as shown in fig. 1, an LED light unit 400 moves in a moving direction 410; in one embodiment, as shown in fig. 1, the inner wall of the transparent casing is provided with a plurality of buffer structures 110 spaced apart from each other, in which case the light transmission performance is better and the material used is less. In one embodiment, as shown in FIG. 1, the direction in which the collection region 310 emits the LED monomer is vertically oriented such that the LED monomer is vertically oriented when emitting. In one embodiment, the collection area 310 is funnel shaped, as shown in FIG. 1.

In one embodiment, as shown in fig. 2, the inner wall of the transparent casing is provided with an integral buffer structure 110, in this embodiment, the buffer structure is made of a flexible transparent material, and in one embodiment, the buffer structure is made of PVC soft plastic or the like. In one embodiment, as shown in FIG. 2, the direction in which the LED emitter is emitted from the collection region 310 is tilted such that the LED emitter is tilted upward when emitting.

In one embodiment, the power device is provided with a plurality of the emission areas. In one embodiment, as shown in fig. 3, the power device is symmetrically provided with two emission areas. Furthermore, the emission time of each emission area is the same or different; and/or the emission frequencies of the emission regions are arranged in the same or different ways; and/or the launching powers of all the launching areas are arranged in the same or different ways; and/or the emission predicted track of each emission area is arranged in an intersecting or non-intersecting way. Thus, the LED luminous monomers can be emitted from two or more emitting regions simultaneously or at intervals, and the complicated disorder change illumination effect is realized. In one embodiment, the power device is symmetrically provided with two emission areas, the emission time of the two emission areas is the same, the emission frequency of the two emission areas is different, the emission power of the two emission areas is the same, and the emission predicted tracks are intersected, so that part of the LED light-emitting monomers emitted by the two emission areas collide with each other at different positions, and the disorder dynamic illumination effect is increased.

In one embodiment, as shown in fig. 3, a plurality of LED light-emitting units move in the cavity at different positions in the same or different directions and at the same or different speeds, and are matched with possible collisions, so as to obtain a disordered chaotic-state illumination effect, break through the law that LEDs in a conventional light-emitting manner are immobile, and can be used as a new light source. Further, the emission interval of the emission region in the disorder LED light source is 4% -10% of the time of the LED luminous monomers falling into the collection region from the highest position under a collision-free condition; in this way, after the disordered LED light source is activated, i.e. the first LED light-emitting cell is emitted by the emitting region, it is ensured that a certain number, e.g. 10 to 30, of LED light-emitting cells move in the cavity out of order. In one embodiment, the collection region is disposed at the opening and the collection region closes the opening. Further, in one embodiment, the LED light-emitting units collected in the collection region are transported to the emission region by gravity between the collection region and the emission region. In one embodiment, a transmission belt is arranged between the collecting region and the emitting region of the power device, and the collecting region transmits the LED light-emitting monomer to the emitting region through the transmission belt. Therefore, the collected LED luminous monomers can be conveniently transmitted and continuously emitted by the emitting area, and the continuous out-of-order illumination effect is realized.

In one embodiment, the power device comprises a push rod or an elastic member; in one embodiment, the LED light-emitting units are provided with a magnetic member, the power device is or comprises an electromagnet, and the electromagnet accelerates the LED light-emitting units by using lorentz force generated by an electromagnetic field in an electromagnetic system, so that the LED light-emitting units obtain kinetic energy required by movement, that is, the LED light-emitting units move under the power of the power device, and have high speed and momentum. Further, the electromagnet comprises an energy supply assembly, an accelerator and an electromagnetic switch; in one embodiment, the energy supply assembly comprises a battery pack, a flux concentrator or a homopolar generator for storing energy; in one embodiment, the accelerator comprises a low voltage dc monopole generator powered orbital accelerator or a coaxial synchrotron with discrete or continuous coil configuration for converting electromagnetic energy into kinetic energy; the electromagnetic switch is used for controlling the connection or disconnection of the energy supply assembly and the accelerator. Therefore, by utilizing the electromagnetic force, the LED light-emitting module has the advantages of uniformity and easiness in control, and can form attractive force and repulsive force through the electromagnetic action outside the transparent shell, so that the LED light-emitting module provides power on the premise of not influencing the internal structure of the transparent shell, and a better power output control effect is realized. Further, the power device is arranged outside the transparent shell in a sliding mode, and further the power device is further provided with a control switch used for being controlled to supply power to the LED light-emitting monomer or stop supplying power. For example, the control switch is a wireless control switch, so that a user or an administrator can remotely send a control signal through a mobile phone or a computer to control the power device.

Further, the power device is further provided with an emitter, the collecting region collects the LED luminous monomer and transmits the LED luminous monomer to the emitting region, the emitter is arranged in the emitting region or outside the emitting region, and the emitter emits the LED luminous monomer when the emitting region obtains the LED luminous monomer transmitted by the collecting region. Further, in one embodiment, the power device is provided with an emitter in the emitting region, and the emitter emits the LED light-emitting unit when the LED light-emitting unit transmitted by the collecting region is obtained. In one embodiment, the transmitter is similar to a marble transmitter. Further, in one embodiment, an adsorption structure is arranged at one end of the emitter close to the collection region, a pushing structure is arranged at one end of the emitter close to the outlet of the emission region, a conveying channel is arranged between the adsorption structure and the pushing structure, the adsorption structure is used for adsorbing the LED light-emitting monomers and conveying the LED light-emitting monomers to the pushing structure through the conveying channel, and the pushing structure is used for emitting the LED light-emitting monomers. In one embodiment, the adsorption structure comprises a suction adsorption structure, in one embodiment, a vacuum adsorption structure, and the LED luminous monomer is vacuumed and adsorbed in one embodiment by suction; in one embodiment, the adsorption structure comprises a magnetic adsorption structure, and the LED light-emitting unit has a magnetic body, and the magnetic adsorption structure is used for adsorbing the LED light-emitting unit by adsorbing the magnetic body. In this way, the LED light emitting cells can be conveniently moved to a suitable emission position for accurate and sufficient kinetic energy emission.

In one embodiment, the outlet of the emission region is disposed beside the collection region. Further, in one embodiment, a baffle is arranged at an outlet of the emitting area of the power device, the baffle is in linkage with the emitter, the baffle is opened at a first preset time before the emitter is ready to emit, and is closed at a second preset time after the emitter emits, so that interference caused by the fact that the LED luminous monomer enters the emitting area from the outlet of the emitting area is avoided. In one embodiment, the first predetermined time is 0.2 to 0.8 seconds, and/or the second predetermined time is 0.3 to 0.5 seconds; in one embodiment, the first predetermined time is 0.5 seconds, and/or the second predetermined time is 0.5 seconds; further, in one embodiment, the first preset time and the second preset time are set according to a transmission speed of the transmitter. In this way, it is possible to ensure the control of the emission and to avoid the clogging of the outlet of the emission area.

In one embodiment, the LED light emitting cells include a polyhedral structure. In one embodiment, the LED light emitting unit has a regular polyhedron structure. In one embodiment, the LED light-emitting unit has a 12-sided structure. In one embodiment, the LED light emitting unit includes a sphere structure. In one embodiment, the LED light emitting unit is a sphere structure. In one embodiment, the LED light emitting unit has a spherical or ellipsoidal structure. This is advantageous for achieving emission and ensures uniformity of emission by uniformity of the LED light emitting cells.

In one embodiment, a linear track is disposed in the emitting area. In one embodiment, the included angle between the linear track and the ground level is 70-90 degrees. In one embodiment, the included angle between the linear track and the ground level is 90 degrees, that is, the linear track is vertically upward. In one embodiment, the linear track forms an angle of 70 degrees or 75 degrees with the horizontal line, and when the linear track is inclined upwards, the emitted LED light-emitting unit may collide with the transparent shell.

In one embodiment, the emitting area has a spiral track disposed therein. Therefore, the LED luminous monomer can be emitted in a spiral ascending way through the spiral track, the variable of the rotary collision is increased, and the direction after the collision is more diversified. Further, in one embodiment, the power device is provided with an emitter and an output direction adjuster thereof in the emitting area, and the output direction adjuster is used for randomly adjusting the output direction of the emitter within a preset direction range, so as to control the emitter to output non-directional thrust and push the LED light-emitting units to enter the cavity non-directionally. Therefore, the tracks of the LED light-emitting monomers are more and more complicated, and the disorder degree of disorder is increased.

Furthermore, disorder LED light source is provided with brake valve lever, brake valve lever connects control switch and/or electromagnetic switch, brake valve lever is used for providing direct manual operation control for the user, is favorable to realizing directly perceived control like this, is similar to marble game, is particularly suitable for the recreation usage of miniature disorder LED light source. Furthermore, the disorder LED light source is provided with a plurality of openings and a plurality of corresponding power devices, and each power device seals one corresponding opening, so that a plurality of collecting areas and a plurality of emitting areas can be realized, the disorder state of the light source is increased, the disorder LED light source is particularly suitable for dazzling application of large-scale disorder LED light sources, can be arranged in squares, markets, scenic spots and the like, and is also suitable for movie televisions. Furthermore, the out-of-order LED light source is provided with an electronic lock switch connected with the control handle and a wireless receiving module connected with the electronic lock switch, the wireless receiving module is used for receiving wireless signals and transmitting the wireless signals to the electronic lock switch, and the electronic lock switch is used for verifying the wireless signals and enabling the control handle when the wireless signals pass the verification. Furthermore, the out-of-order LED light source is provided with a timing module connected with the electronic lock switch, the timing module is used for starting timing when the electronic lock switch verifies that the wireless signal passes and/or the electronic lock switch enables the control handle, and sending a timing signal to the electronic lock switch when the preset control time is reached, and the electronic lock switch is also used for locking the control handle when the timing signal is received. That is, the control handle is controllable within a period of time after the wireless signal verification is passed and is locked after the period of time is exceeded, so that the control condition and the control time of the control handle can be ensured, the control effect on the control handle is enhanced, in an application scene, a user scans the two-dimensional code to send an identification signal to the server, the server sends a wireless signal after the identification, the wireless receiving module receives the wireless signal and transmits the wireless signal to the electronic lock switch, the electronic lock switch enables the control handle when the wireless signal is passed and starts to time by the timing module, and the control handle is locked after a certain time, such as 1 minute or 5 minutes.

Other embodiments of the present invention further include a practicable disorder LED light source formed by combining technical features of the above embodiments.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. An out-of-order LED light source, comprising: the LED light-emitting device comprises a power device, a spatial structure and at least one LED light-emitting monomer;

the space structure is provided with a transparent shell and a cavity arranged in the transparent shell, the inner wall of the transparent shell is provided with a buffer structure, the top of the transparent shell is in a partially spherical shape, and the bottom of the transparent shell is provided with an opening communicated with the cavity;

the power device seals the opening, the power device is provided with a collecting region and an emitting region, the collecting region collects the LED luminous monomers and transmits the LED luminous monomers to the emitting region, and the emitting region emits the LED luminous monomers when the LED luminous monomers transmitted by the collecting region are obtained;

the transparent shell is provided with a light transmitting area and a plurality of circular shielding areas distributed in the light transmitting area at intervals, the circular shielding areas are arranged at intervals, the diameter of each circular shielding area is 70% -90% of the diameter of the LED light-emitting monomer, and the total area of each circular shielding area is 8% -12% of the area of the light transmitting area;

the buffer structure comprises an elastic cushion body and a fluorescent layer which is covered on the whole surface of the elastic cushion body facing the cavity, and the elastic cushion body and the fluorescent layer are used for generating contact deformation when the LED light-emitting monomers collide; the fluorescent layer is coated with fluorescent powder and used for emitting light in a dark environment;

an energy supply module, a control module and at least one LED lamp are arranged in a shell of the LED light-emitting monomer, a lamp cap of each LED lamp is exposed on the shell, and the energy supply module is respectively connected with each LED lamp through the control module;

the control module is a wireless control module and is used for receiving an external control signal to switch on or switch off the connection between the energy supply module and each LED lamp;

the energy supply module is provided with a storage battery and a wireless charging unit which are connected, a wireless charging coil is arranged in the transparent shell, and the transparent shell dynamic light source further comprises a wireless charging device connected with the wireless charging coil; the wireless charging device wirelessly charges the storage battery through the wireless charging coil and the wireless charging unit;

the cavity is provided with a plurality of mutually communicated airspaces, at least one collision body is hung in each airspace, and each collision body comprises an LED structure and is used for shaking after being collided and emitting light rays with random wavelengths in a time period with random length.

2. The scrambled LED light source of claim 1, wherein the collection region is funnel-shaped.

3. The disorder LED light source of claim 2, wherein a transmission belt is disposed between the collecting region and the emitting region, and the collecting region transmits the LED light-emitting units to the emitting region via the transmission belt.

4. The scrambled LED light source of claim 3, wherein the exit of the emission region is disposed beside the collection region.

5. The out-of-order LED light source of claim 1, wherein the LED light-emitting cells comprise a polyhedral structure.

6. The out-of-order LED light source of claim 1, wherein the LED light-emitting cells comprise a spherical structure.

7. The out-of-order LED light source of claim 1, wherein a linear track is disposed in the emission area.

8. The disorder LED light source of claim 7, wherein the linear track has an angle of 70-90 degrees with respect to the horizon.

9. The scrambled LED light source of claim 1 wherein a spiral track is disposed in the emission region.

10. An out-of-order LED light source as claimed in any one of claims 1 to 9 wherein the power means provides a plurality of said emission regions.

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