CN109185799B - LED garden light source - Google Patents

Abstract

The invention relates to an LED garden light source, which comprises a connecting seat, a ground LED light source and a high-position LED light source; the connecting seat is arranged below the high-position LED light source and is connected with the high-position LED light source; the ground LED light source is in signal connection with the high-position LED light source, and the ground LED light source is movably connected with the connecting seat. The LED garden light source is provided with light emitting sources with different heights, can emit light on the ground and at high positions, and can realize multiple light emitting and various dependent light emitting effects based on different ground LED light source and high LED light source designs; the design of cooperation connecting seat, ground LED light source can be connected or break away from the connecting seat with the connecting seat, has and uses convenient advantage, is applicable to in the garden environment of various different designs.

Description

LED garden light source

Technical Field

The invention relates to the field of LED display, in particular to an LED garden light source.

Background

Light Emitting Diodes (LEDs) have the advantages of high brightness, low operating voltage, low power consumption, large size, long lifetime, impact resistance, stable performance, etc., and have been widely researched and applied, and the following three cases are given.

The Chinese patent with the application number of 201110300502.2 discloses a garden solar LED lamp, which belongs to the technical field of LED lamps and is characterized by comprising a disc-shaped aluminum alloy lampshade, wherein a support is arranged below the aluminum alloy lampshade and is connected with the outer edge of the aluminum alloy lampshade, an LED light source module is arranged at the bottom in the aluminum alloy lampshade, a support is arranged at the back of the aluminum alloy lampshade, a solar cell panel is arranged on the support and is connected with the LED light source module through a circuit, and aluminum alloy heat dissipation columns are distributed on the back of the aluminum alloy lampshade in the support; the invention aims to provide a garden solar LED lamp which is compact in structure, good in heat dissipation effect and attractive in appearance; it is used for illumination of gardens and courtyards.

Chinese patent application No. 201721509544.6 discloses a modular landscape lamp, including lamp pole, lamps and lanterns, LED light source and ring flange, the top of lamp pole is provided with lamps and lanterns, and lamps and lanterns embed has the LED light source, and the bottom of lamp pole is provided with ring flange, its characterized in that: the lamp post consists of a small-diameter tubular lamp post at the upper part and a large-diameter tubular lamp holder at the lower part, the lamp post and the lamp holder are connected into a whole by welding through an annular cover, and a pair of through holes are drilled on the annular cover; the lamp post is externally sleeved with an annular water sprayer supported by an annular cover. The utility model has the advantages that: when the sprinkler is applied to a traditional lamp post, only holes need to be drilled on the conventional lighting lamp post, and the sprinkler does not need to be greatly modified, so that the sprinkler is beneficial to batch modification and popularization; and when the sprinkler is blocked or has other problems, the disassembly and maintenance are very convenient.

The application number 201721612726.6 discloses a high-power garden street lamp, which comprises a lamp body and a lamp holder positioned at the bottom of the lamp body, wherein a top plate is installed at the top of the lamp body, a lampshade is arranged on the outer side of the lamp body, a controller is installed at the bottom of the inner side of the lamp body, an LED lamp post is installed above the controller, and a light direction adjusting mechanism is arranged on the outer side of the LED lamp post; an access window is arranged on one side of the lamp body; a solar cell panel is arranged at the top of the top plate; has the advantages that: the utility model adjusts the direction of the light emitted by the LED lamp post through the light direction adjusting mechanism, and can use the light source as a street lamp light source and a landscape light source, thereby improving the utilization rate of the light source; through adjustable the light can shelter from the light source to adjustment mechanism, only throws light on the road, avoids the light source to penetrate pedestrian's eye directly.

However, in the existing garden lighting, light is often emitted at one position.

Disclosure of Invention

Based on this, there is a need to provide an LED garden light source.

An LED garden light source comprises a connecting seat, a ground LED light source and a high-position LED light source; the connecting seat is arranged below the high-position LED light source and is connected with the high-position LED light source; the ground LED light source is in signal connection with the high-position LED light source, and the ground LED light source is movably connected with the connecting seat.

The LED garden light source is provided with light emitting sources with different heights, can emit light on the ground and at high positions, and can realize multiple light emitting and various dependent light emitting effects based on different ground LED light source and high LED light source designs; the design of cooperation connecting seat, ground LED light source can be connected or break away from the connecting seat with the connecting seat, has and uses convenient advantage, is applicable to in the garden environment of various different designs.

In one embodiment, the ground LED light source is provided with a roller structure, a driving device, an LED luminous body, a battery pack structure and a path setting storage device; the battery pack structure is respectively connected with the driving device and the path setting storage device; the driving device is respectively connected with the path setting and storing device and the roller structure and is used for driving the roller structure to advance according to the tour path; the power supply potential is on the tour route, and the driving device is used for controlling the battery pack structure to be connected with the power supply potential when the ground LED light source reaches the power supply potential.

In one embodiment, the high-position LED light source comprises at least one LED strip.

In one embodiment, the high-position LED light source comprises at least one LED tubular lighting structure.

In one embodiment, the LED tubular lighting structure comprises an LED lamp tube.

In one embodiment, the high-position LED light source comprises at least one LED lantern.

In one embodiment, the ground LED light source is provided with a self-walking structure, and the self-walking structure is used for enabling the ground LED light source to travel according to a preset tour path.

In one embodiment, the connecting base is provided with a power supply potential, the power supply potential is on the tour path, and the self-propelled structure is used for connecting the ground LED light source with the power supply potential when the ground LED light source reaches the power supply potential.

In one embodiment, the connecting seat is provided with a signal transmitter, and the ground LED light source is provided with a signal receiver; the signal receiver is used for acquiring positioning information of the power supply potential according to the signal transmitter, and the ground LED light source is used for connecting the power supply potential according to the positioning information.

In one embodiment, the high-position LED light source is provided with a central light emitting region and at least two peripheral light emitting regions, the connecting seat is disposed below the central light emitting region and connected to the central light emitting region, and each of the peripheral light emitting regions is connected to the central light emitting region.

In one embodiment, the central light emitting region has a circular ring shape.

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.

Fig. 4 is a schematic diagram of another embodiment of the present invention.

Fig. 5 is a schematic view 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 invention is an LED garden light source, which comprises a connecting seat, a ground LED light source and a high-position LED light source; the connecting seat is arranged below the high-position LED light source and is connected with the high-position LED light source; the ground LED light source is in signal connection with the high-position LED light source, and the ground LED light source is movably connected with the connecting seat. The LED garden light source is provided with light emitting sources with different heights, can emit light on the ground and at high positions, and can realize multiple light emitting and various dependent light emitting effects based on different ground LED light source and high LED light source designs; the design of cooperation connecting seat, ground LED light source can be connected or break away from the connecting seat with the connecting seat, has and uses convenient advantage, is applicable to in the garden environment of various different designs.

Further, in one embodiment, the connecting seat is electrically connected with the high-position LED light source. In one embodiment, the connecting seat is electrically connected with the high-position LED light source through a connecting wire; further, the LED garden light source further comprises the connecting wire. In one embodiment, as shown in fig. 1, the LED garden light source includes a connecting base 100, a ground LED light source 200 and a high LED light source 300, the connecting base is disposed below the high LED light source and connected to the high LED light source, and the ground LED light source is movably connected to the connecting base. In this embodiment, the connecting base is electrically connected with the high-position LED light source through a connecting wire, and the ground LED light source is in wireless signal connection with the high-position LED light source.

Further, in one embodiment, the high-position LED light source is fixedly disposed on the connecting seat; in one embodiment, as shown in fig. 2, the high-position LED light source 300 is fixedly disposed on the connecting base 100, the high-position LED light source 300 is in a semi-circular shape, and a plurality of LED lamp beads 310 are disposed thereon; in other embodiments, the high LED light source may have a semi-circular shape in the opposite direction to that shown in fig. 2. In one embodiment, the high-level LED light source comprises a street lamp; or, in one embodiment, the high-position LED light source comprises at least one LED strip; or, in one embodiment, the high-position LED light source comprises at least one LED tubular lighting structure; alternatively, in one embodiment, the LED tubular lighting structure comprises an LED tube; alternatively, in one embodiment, the high-position LED light source comprises at least one LED lantern. It can be understood that the shape and the structure of the high-position LED light source can be flexibly designed according to requirements so as to be suitable for various garden designs. In one embodiment, the high-position LED light source is provided with a central light emitting region and at least two peripheral light emitting regions, the connecting seat is disposed below the central light emitting region and connected to the central light emitting region, and each of the peripheral light emitting regions is connected to the central light emitting region. In one embodiment, the central light emitting region has a circular ring shape. Furthermore, the central light emitting area and the peripheral light emitting area are respectively provided with a plurality of LED lamp beads, and the power of the LED lamp beads in the central light emitting area is greater than that of the LED lamp beads in the peripheral light emitting area; therefore, on one hand, a high-position LED light source capable of emitting light in a centralized mode can be obtained, on the other hand, a central light emitting area with stronger light and a peripheral light emitting area with auxiliary light distribution can be provided, and on the other hand, the high-position LED light source can be matched with a ground LED light source to achieve an all-dimensional multi-area light emitting effect.

Further, in one embodiment, the high-position LED light source is provided with a signal transceiver, and the ground LED light source is provided with a signal receiver; the signal transceiver is used for sending a control signal, the signal receiver is used for receiving the control signal, and the ground LED light source is used for realizing light emitting control according to the control signal. Further, the light emission control includes light emission, movement, and charging. Further, the signal transceiver is used for receiving and forwarding the control signal. Therefore, the control signal can be sent to the high-position LED light source through external equipment such as a mobile phone, a tablet or a computer and the like, and is forwarded to the ground LED light source, so that the high-position LED light source and the ground LED light source are controlled.

In one embodiment, the ground LED light source is provided with a self-walking structure, and the self-walking structure is used for enabling the ground LED light source to travel according to a preset tour path. Further, the tour route is set or adjusted according to an external mobile terminal. In one embodiment, the connecting base is provided with a power supply potential, the power supply potential is on the tour path, and the self-propelled structure is used for connecting the ground LED light source with the power supply potential when the ground LED light source reaches the power supply potential. In this way, a mobile floor LED light source can be designed.

In one embodiment, the connecting seat is provided with a signal transmitter, and the ground LED light source is provided with a signal receiver; the signal receiver is used for acquiring positioning information of the power supply potential according to the signal transmitter, and the ground LED light source is used for connecting the power supply potential according to the positioning information. Like this, the position of connecting seat can be known to ground LED light source, finds the connecting seat intelligently and is connected with it to obtain the power supply, be favorable to realizing the lasting self-operation of intellectuality on the one hand, on the other hand can cooperate other designs to realize "going home" function. Further, in one embodiment, the control signal includes regression information, the signal receiver is configured to obtain the regression information according to the signal transmitter, and the ground LED light source, when receiving the regression information, moves to the connection seat and connects to the power supply potential according to the positioning information. Therefore, the ground LED light source can be remotely controlled to automatically find the power supply potential of the connecting seat and obtain power supply, so that the function of 'returning home' is realized, and intelligent lasting self-running can be realized.

Furthermore, the ground LED light source is provided with an LED luminous body, and the self-walking structure comprises a roller structure, a driving device, a battery pack structure and a path setting storage device; further, the self-propelled structure is provided with a shell, the LED luminous body is arranged on the shell, the roller structure is at least partially arranged outside the shell, and the driving device, the battery pack structure and the path setting and storing device are all arranged inside the shell; in one embodiment, the battery pack structure is provided with a connection terminal for connecting the supply potential; furthermore, the connecting end part is movably inserted into the power supply potential; in one embodiment, the battery pack structure is respectively connected with the driving device and the path setting storage device; the driving device is respectively connected with the path setting and storing device and the roller structure and is used for driving the roller structure to advance according to the tour path; the power supply potential is on the tour route, and the driving device is used for controlling the battery pack structure to be connected with the power supply potential when the ground LED light source reaches the power supply potential. In one embodiment, the ground LED light source is provided with a roller structure, a driving device, an LED luminous body, a battery pack structure and a path setting storage device; the battery pack structure is respectively connected with the driving device and the path setting storage device; the driving device is respectively connected with the path setting and storing device and the roller structure and is used for driving the roller structure to advance according to the tour path; the power supply potential is on the tour route, and the driving device is used for controlling the battery pack structure to be connected with the power supply potential when the ground LED light source reaches the power supply potential. The rest of the examples are analogized.

Further, in one embodiment, the high-position LED light source is detachably fixed on the connecting seat through a connecting rod; in one embodiment, as shown in fig. 3, the high LED light source 300 is detachably fixed on the connecting base 100 through a connecting rod 320, the high LED light source 300 is in an ellipsoidal shape, and a plurality of LED lamp beads 310 are arranged on the high LED light source 300; the connecting socket 100 has a power supply 110, the ground LED light source 200 has a roller structure 210, LED emitters 220, a housing 230 and a connecting end 240, and the connecting end 240 is plugged into the power supply 110, in this embodiment, the ground LED light source 200 has a plurality of LED emitters 220. Furthermore, a plurality of LED lamps are also arranged on the connecting seat; in one embodiment, as shown in fig. 4, the connecting socket 100 is also provided with a plurality of LED lamps 120. It can be understood that LED lamp pearl, LED lamp and LED luminous element all are the pointolite that has the luminous chip of LED, and the structure of three can be the same or different, also can unify to be called LED luminous element, promptly, high-order LED light source, connecting seat and/or ground LED light source are equipped with LED luminous element. In one embodiment, the number of the LED luminous bodies in the high-position LED light source, the connecting seat and/or the ground LED light source is one, two or more.

Further, in one embodiment, the number of the high-position LED light sources is multiple, and the multiple high-position LED light sources are respectively connected to the connecting base, or the LED garden light source includes a main cable, a connecting base, a ground LED light source and multiple high-position LED light sources, and the multiple high-position LED light sources are respectively connected to the main cable and the connecting base through the main cable. In one embodiment, the LED garden light source comprises a connecting line, a connecting seat, a ground LED light source and a plurality of high-level LED light sources, wherein the plurality of high-level LED light sources are respectively connected with the connecting seat through the connecting line. In one embodiment, as shown in fig. 5, the LED garden light source includes a plurality of tubular high-level LED light sources 340, each of the tubular high-level LED light sources 340 is connected to a main cable 330, the main cable 330 is connected to the connection base 100 through a connection cable 400, the connection base 100 is further extended with a waterproof cover 130 having a semi-enclosed structure, and the waterproof cover 130 is used for covering the power supply 110.

In one embodiment, the ground LED light source is provided with a roller structure, a driving device, an LED luminous body, a charging structure, a battery pack structure and a path setting storage device; the battery pack structure is respectively connected with the driving device, the LED luminous body, the charging structure and the path setting storage device; the path setting and storing device is used for setting and storing a tour path, the driving device is respectively connected with the LED luminous body, the path setting and storing device and the roller structure, and the driving device is used for driving the roller structure to advance according to the tour path and controlling the LED luminous body to emit light during advancing; the driving device is also used for controlling the charging structure to be connected with the power supply system when the roller structure is driven to move to the position where the power supply system is located; the power supply system is used for charging the battery pack structure when the charging structure is connected. Therefore, the ground LED light source can automatically travel along the tour path and can also automatically find the power supply system for charging, so that a new implementation mode is provided for regional illumination of the garden area, the LED light source is particularly suitable for providing an illumination path in a region without long-time illumination, a dynamic light emitting effect is realized, manual intervention is not needed or less manual intervention is needed in the process, and human resources are saved; the team mode can be realized by matching with a plurality of ground LED light sources, and the tour guide device is particularly suitable for tour use.

In one embodiment, the connecting seat is used as a power supply structure of the ground LED light source and is used for supplying power to the ground LED light source so that the ground LED light source can obtain the energy for traveling. Wherein the travel path comprises the tour path, the priority path, and/or the roaming path. In one embodiment, the power supply system is located in the path of travel, for example, the power supply system is designed as a small arch. In one embodiment, the power supply system is located on the travel path, and the LED garden light source is provided with two power supply systems. In one embodiment, the power supply system is located on one side of the path of travel.

In one embodiment, the ground LED light source is provided with a roller structure, a driving device, an LED luminous body, a charging structure, a battery pack structure and a path setting storage device; in one embodiment, the ground LED light source is provided with a frame, the roller structure, the battery pack structure, the driving device, the LED illuminator, the charging structure and the path setting storage device are all disposed on the frame, and the roller structure is located at the bottom of the frame. Further, the ground LED light source is provided with a shell, the LED luminous body is arranged on the shell, the roller structure is arranged at the bottom of the shell, and the battery pack structure, the driving device, the charging structure and the path setting and storing device are arranged inside the shell. In one embodiment, the LED lighting device includes at least one LED lamp and a driving module thereof, and the LED lamp is connected to the driving device and the battery pack structure through the driving module. The luminous surface of the LED lamp is arranged on the shell, and the rest part of the LED luminous body is arranged in the shell. In one embodiment, the ground LED light source is provided with a housing, the roller structure is disposed at the bottom of the housing, the LED light emitter, the battery structure, the driving device, the charging structure and the path setting storage device are disposed inside the housing, and the housing is provided with a transparent plate or an opening at a light emitting surface of the LED lamp for transmitting light.

In one embodiment, the battery pack structure is respectively connected with the driving device, the LED light emitter, the charging structure and the path setting storage device; the battery pack structure is used for supplying power, namely the driving device, the LED luminous body, the charging structure and the path setting storage device are respectively supplied with power. Further, the battery pack structure is provided with a switch circuit and a storage battery; the storage battery is connected with the driving device, the LED luminous body, the charging structure and the path setting storage device through the switch circuit respectively.

In one embodiment, the roller structure comprises two or more roller groups, each roller group comprises at least two rollers, or the roller structure comprises three or more rollers; in one embodiment, the roller structure comprises a driving wheel connected with the driving device and a driven wheel rolling along with the driving wheel, and the driving device is used for driving the driving wheel to enable the ground LED light source to travel; further, the driving wheel is provided with a rotating structure.

In one embodiment, the path setting storage device is used for setting and storing a tour path, the driving device is respectively connected with the LED light-emitting body, the path setting storage device and the roller structure, and the driving device is used for driving the roller structure to travel along the tour path and controlling the LED light-emitting body to emit light when the roller structure travels; namely, the driving device is used for driving the roller structure to roll so as to enable the ground LED light source to travel along the tour path, and the driving device is used for controlling the LED luminous body to emit light during traveling. Further, the driving device is provided with a dynamic induction switch connected with the LED luminous body, and the dynamic induction switch is used for controlling the LED luminous body to emit light when the ground LED light source is induced to travel; further, the dynamic induction switch is connected with the roller structure, and the dynamic induction switch is used for controlling the LED luminous body to emit light when inducing the roller structure to roll. Further, the dynamic induction switch is connected with the driving wheel or the driven wheel.

In one embodiment, the driving device is further configured to control the charging structure to be connected to the power supply system when the roller structure is driven to travel to the position where the power supply system is located; the power supply system is used for charging the battery pack structure when the charging structure is connected. In one embodiment, the driving device is used for driving the roller structure to enable the ground LED light source to travel to the position of the power supply system, and the driving device controls the charging structure to be connected with the power supply system; the power supply system then charges the battery pack structure of the ground LED light source at its location. In one embodiment, the driving device controls the charging structure to abut against a charging end of the power supply system to realize electrical connection in a contact manner, and the power supply system is connected with the charging structure and charges the battery pack structure, namely, the power supply system is connected with the charging structure and charges the battery pack structure through the charging structure.

In one embodiment, the route setting and storing device is used for setting the tour route so that the power supply system is located on the tour route; the power supply system is provided with a signal transmitter, and the ground LED light source is also provided with a signal receiver; the signal receiver is used for acquiring positioning information of the position where the power supply system is located according to the signal transmitter, the driving device is connected with the signal receiver, and the driving device drives the roller structure to move to the position where the power supply system is located according to the tour path according to the positioning information, controls the charging structure to be connected with the power supply system and controls the roller structure to stop moving until charging is completed. Therefore, the ground LED light source can know the position of the power supply system, and the power supply system can be intelligently found through the driving device, so that the electric connection and the charging are realized.

In one embodiment, the driving device is provided with a controller, a judging module and a driving motor structure, and the battery pack structure is respectively connected with the controller, the judging module and the driving motor structure; the controller is respectively connected with the path setting storage device, the judging module, the driving motor structure and the signal receiver, the driving motor structure is connected with the roller structure, and the controller is used for driving the roller structure to travel along the tour path through the driving motor structure; the signal receiver is used for acquiring positioning information of the position of the power supply system according to the signal transmitter and transmitting the positioning information to the controller, and the controller is used for controlling the battery pack structure to be connected with the power supply system and controlling the roller structure to pause to advance until charging is completed when the judging module judges that the ground LED light source reaches the power supply system according to the positioning information. Thus, intelligent charging can be achieved. Further, the controller is used for controlling the battery pack structure to be connected with the power supply system and controlling the roller structure to pause to advance until charging is completed when the judging module judges that the ground LED light source reaches the power supply system according to the positioning information and further judges that the electric quantity of the battery pack structure needs charging. Like this, can realize intelligent charging, when the electric quantity is enough, need not all to charge at every turn.

In one embodiment, the ground LED light source is provided with a charging determining device, the charging determining device is respectively connected to the battery pack structure and the driving device, and the charging determining device is configured to directly drive the roller structure to advance to the position of the power supply system through the driving device when the electric quantity of the battery pack structure is lower than a preset threshold. In one embodiment, the path setting storage device has a setting module and a storage module, the battery pack structure is respectively connected with the setting module and the storage module, the setting module is used for setting a priority path and the tour path, and the storage module is used for storing the priority path and the tour path; the driving device is respectively connected with the setting module and the storage module, and the charging device is used for controlling the driving device to directly drive the roller structure to move to the position of the power supply system according to the priority path when the electric quantity of the battery pack structure is lower than a preset threshold value. Like this, when the electric quantity is lower, can directly run to charge, avoid unable in time charging to lead to lying prone the nest.

In one embodiment, the setting module is further configured to set a roaming path, and the storage module is further configured to store the roaming path, where at least one intersection point exists between the roaming path and the priority path. Further, the range of the roaming path is larger than the tour path. Further, the roaming path connects the tour paths through a plurality of the priority paths. Thus, a travel network can be formed, for example, a tour path is a daily path, a priority path is a crisis path, and a roaming path is an extended path.

In one embodiment, the power supply system is provided with a power supply potential, and the power supply potential is used for connecting the charging structure; the driving device is further used for controlling the charging structure to be connected with the power supply potential and controlling the roller structure to pause to advance until charging is completed when the roller structure is driven to advance to the position of the power supply system. In one embodiment, the power supply system is further provided with a waterproof cover for covering the power supply potential, so as to provide a better waterproof effect. In one embodiment, the waterproof cover has a semi-enclosed structure. Thus, the waterproof effect is better.

In one embodiment, the charging structure comprises a wireless charging module; the power supply system is equipped with wireless charging circuit in tour route below, drive arrangement still is used for the drive the gyro wheel structure is according when tour route marching, control wireless charging module connects power supply system's wireless charging circuit. In one embodiment, the power supply system is provided with a wireless charging circuit below part of the travel path. Furthermore, the power supply system is provided with wireless charging lines below all the tour routes. In one embodiment, the power supply system is provided with a wireless charging circuit below all the traveling paths. Furthermore, the power supply system is provided with wireless charging circuits below all the traveling paths. Therefore, uninterrupted charging effect can be realized, and the charging device is particularly suitable for occasions with not too long paths.

Further, in each embodiment, the ground LED light source is further provided with a light sensing module connected to the driving device, the light sensing module is configured to sense an ambient brightness, and enable the driving device when the ambient brightness is lower than a preset brightness value, that is, the driving device drives the roller structure to travel along the tour route, and controls the LED light emitter to emit light when traveling; further, the light sensing module is further configured to control the driving device to drive the roller structure to move to the position of the power supply system when the ambient brightness is not lower than a preset brightness value, and the driving device controls the charging structure to be connected with the power supply system; the power supply system is used for charging the battery pack structure when the charging structure is connected. Therefore, the vehicle can be automatically charged when the ambient brightness is high, and can automatically walk when the ambient brightness is low.

Furthermore, the ground LED light source is also provided with monitoring equipment, the monitoring equipment is respectively connected with the battery pack structure and the driving device, and the driving device is also used for controlling the monitoring equipment to acquire monitoring information during traveling. In one embodiment, the monitoring device includes a camera. In one embodiment, the monitoring device further comprises a rotating base, and the camera is fixed on the rotating base. In one embodiment, the driving device is connected with the rotating base. Therefore, the monitoring information can be obtained when the ground LED light source travels, and the method is suitable for patrolling in a factory or a cell. The cooperation charge structure includes wireless charging module just power supply system in patrol the route below and be equipped with the embodiment of wireless charging line, can reach the monitoring effect of patrolling uninterruptedly.

Furthermore, the ground LED light source is further provided with a transmission device, the transmission device is respectively connected to the battery pack structure, the route setting storage device and the driving device, the transmission device is configured to receive control information, select the tour route, the priority route and/or the roaming route from the route setting storage device according to the control information, or reset the tour route, the priority route and/or the roaming route through the route setting storage device, and drive the roller structure to travel according to the tour route, the priority route or the roaming route through the driving device. In this way, the user can remotely select or adjust the travel path in the background. Furthermore, the transmission device is connected with the monitoring device through the driving device, and the transmission device is also used for controlling the on-off of the monitoring device through the driving device according to the control information; further, the transmission device is further connected to the monitoring device, and the transmission device is configured to send the monitoring information of the monitoring device according to the control information, for example, transmit the monitoring information of the monitoring device to a target terminal. In this way, the user can remotely acquire the monitoring information in the background. Furthermore, the driving device is connected with the rotating base, and the transmission equipment is further used for controlling the rotating base to rotate through the driving device according to the control information so as to adjust the shooting direction of the camera. In this way, the user can remotely acquire the monitoring information of the target direction in the background. The embodiment can be applied to the aspect of special line patrol and can be made into children toys.

Furthermore, the ground LED light source also comprises at least one LED auxiliary light-emitting piece which is arranged in a hanging manner; in one embodiment, the LED auxiliary lighting element is suspended on the frame or the housing. In one embodiment, each LED auxiliary illuminating piece is suspended in a supporting manner through a connecting hanging piece; the connecting hanging piece comprises a connecting rod and a hanging silk thread, one end of the connecting rod is fixed on the ground LED light source, for example, the connecting rod is fixed on the rack or the shell, and the other end of the connecting rod is connected with the LED auxiliary light-emitting piece through the hanging silk thread. In one embodiment, the LED auxiliary illuminating member comprises a support, an LED surface-mounted lamp, a control module, an energy supply structure and a light-transmitting sealing structure, wherein the LED surface-mounted lamp, the control module and the energy supply structure are all fixedly arranged on the support, the energy supply structure is respectively connected with the LED surface-mounted lamp and the control module, the control module is connected with the LED surface-mounted lamp, and the light-transmitting sealing structure covers the support, the LED surface-mounted lamp, the control module and the energy supply structure. Furthermore, the light-transmitting sealing structure is provided with a plurality of light-transmitting parts corresponding to the positions of the LED surface-mounted lamps and used for transmitting light rays of the LED surface-mounted lamps. Further, the light-transmitting sealing structure is a light-transmitting plastic product, for example, the light-transmitting material is PMMA, PP, PVC, PET, PC, PS, ABS, or the like. Further, in one embodiment, the LED auxiliary illuminating member includes a support, an LED surface-mounted lamp, a control module, an energy supply structure and a light-transmitting sealing structure, the LED surface-mounted lamp, the control module and the energy supply structure are all fixedly disposed on the support, the energy supply structure is respectively connected with the LED surface-mounted lamp and the control module, the control module is connected with the LED surface-mounted lamp, and the light-transmitting sealing structure covers the support, the LED surface-mounted lamp, the control module and the energy supply structure and the outer surface of the light-transmitting sealing structure form a spherical shape. Further, the installation cavity has been seted up to printing opacity seal structure, the support energy supply structure control module with LED table pastes the lamp and all sets up in the installation cavity. In one embodiment, a light-transmitting protective layer is disposed on the light-transmitting sealing structure. In one embodiment, the light-transmitting protective layer completely covers the light-transmitting sealing structure of the LED auxiliary light emitting member. Further, the light-transmitting protective layer is made of a flexible light-transmitting material. In one embodiment, a flexible layer is arranged on the light-transmitting sealing structure of the LED auxiliary light-emitting member, and through holes are formed in the flexible layer at light-emitting positions of the LED auxiliary light-emitting member. 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 auxiliary light emitting piece, and the larger bottom surface of the truncated cone faces the outside. Furthermore, the flexible layer is made of opaque materials, the through holes are filled with light-transmitting materials to form a cylinder or a truncated cone, and further, air bubbles which are distributed non-uniformly are arranged inside the cylinder or the truncated cone to enhance the scattering effect of the transmitted light. Furthermore, the number of the light-transmitting sealing structures corresponding to the LED surface-mounted lamps is provided with lamp holes, and the light-emitting ends of the LED surface-mounted lamps are embedded in the lamp holes in a one-to-one correspondence manner. Furthermore, the light emitting ends of the LED surface-mounted lamps are uniformly distributed on the light-transmitting sealing structure of the LED auxiliary light emitting piece and form a ring integrally. Furthermore, the light emitting ends of the LED surface-mounted lamps are uniformly distributed on the light-transmitting sealing structure of the LED auxiliary light-emitting piece and integrally form a plurality of parallel rings. Further, the light emitting ends of the LED surface mount lamps are uniformly distributed on the light transmitting sealing structure of the LED auxiliary light emitting member and integrally form a regular polyhedron, 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 light emitting ends of the six LED surface mount lamps are uniformly distributed on the light transmitting sealing structure of the LED auxiliary light emitting member and integrally form a regular octahedron; in one embodiment, the light emitting ends of the eight LED surface-mounted lamps are uniformly distributed on the light-transmitting sealing structure of the LED auxiliary light-emitting piece to form a regular hexahedron; the rest of the examples are analogized. Furthermore, a flexible layer is arranged on the light-transmitting sealing structure of the LED auxiliary light-emitting member, through holes are respectively formed in each light-emitting position of the LED auxiliary light-emitting member on the flexible layer, light-transmitting materials are filled in the through holes to form cylinders or round platforms, and air bubbles which are not uniformly distributed are arranged in each cylinder or round platform to enhance the scattering effect of the transmitted light.

In one embodiment, the ground LED light source further comprises a plurality of the LED auxiliary illuminating pieces which are arranged in a hanging way; 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 structure and each LED surface-mounted lamp, so that a user or an administrator can control the LED auxiliary light-emitting piece to emit light or extinguish through the mobile terminal. Furthermore, the control modules of the LED auxiliary light-emitting pieces are uniformly arranged and used for uniformly receiving external control signals and simultaneously conducting or simultaneously cutting off the connection between the energy supply structure and the LED surface-mounted lamps. In one embodiment, the transmission device is connected to the uniformly set control modules, and the transmission device is further configured to control the uniformly set control modules according to the control information; or the transmission equipment is respectively connected with each control module, and the transmission equipment is also used for controlling each control module according to the control information.

In one embodiment, a main switch for controlling all the LED auxiliary illuminating parts is arranged on the ground LED light source, and all the LED auxiliary illuminating parts can illuminate when the main switch is turned on; with the design, a user can start all the LED auxiliary light-emitting pieces; in one embodiment, the LED auxiliary illuminating part is provided with a touch switch to control the LED surface-mounted lamp to illuminate in a motion state. Further, the LED auxiliary illuminating part is provided with a switch connected with the LED surface-mounted lamp or the control module in the installation cavity, the switch is used for controlling the LED auxiliary illuminating part to emit light during movement, and further the switch is used for enabling the LED surface-mounted lamp to emit light when the LED auxiliary illuminating part is in a movement state. Further, the switch is also used for cutting off when the LED auxiliary light-emitting piece is in a static state so as to stop the LED surface-mounted lamp from emitting light. In one embodiment, the switch is an inductive switch, and the inductive switch is used for inducing the LED auxiliary light-emitting member to be turned on when the speed exceeds a preset value in a motion state, for example, so that the LED surface-mounted lamp emits light. Further, the inductive switch is also used for inducing the LED auxiliary light-emitting piece to cut off after stopping moving so as to enable the LED surface-mounted lamp to stop emitting light. In one embodiment, the switch is a vibration switch or a dynamic balance switch. In one embodiment, the transmission device is connected to the main switch through the driving device, and the transmission device is further configured to control the main switch through the driving device according to the control information.

In one embodiment, the LED auxiliary light emitting element is a sphere or a sphere with an extended structure, for example, the sphere with the extended structure is a sphere plus a wire and other accessories. Or, in one embodiment, the LED auxiliary light emitting piece is integrally a preset molded piece. For example, the LED auxiliary light emitting piece is a handle with a preset shape as a whole. In one embodiment, the predetermined figure comprises a pyramid, a multi-layer tower, a character, an automobile, a building, a video, a plant, an insect, an archaea, or a model of a predetermined fantasy; for example, the predetermined shape may include dragon, apple, Zhujie, transformers, revenge alliance, Guangong Dazhanqiong, and/or seven cucurbit baby brothers. Furthermore, the preset modeling piece is customized according to the received user requirements, so that the ground LED light source with the updated trend can be provided in cooperation with the times change and the fashion trend. Further, in each embodiment, a sound piece is further connected to one end, away from the connecting hanging piece, of the LED auxiliary light emitting piece through a connecting line, and the sound piece is used for emitting sound, for example, when the ground LED light source moves; in one embodiment, the sound piece comprises a bell or a bell tube. Therefore, the acousto-optic effect can be realized for the ground LED light source, and particularly, the acousto-optic effect under the motion state is suitable for large rain and small rain in daytime and at night.

Further, the number of the ground LED light sources is multiple, so that a plurality of ground light sources can be formed, and a team or a queue can be formed. In order to facilitate charging, further, the number of the power supply system is plural. Further, the number of the power supply systems is greater than or equal to the number of the ground LED light sources.

Further, in one embodiment, the LED garden light source is further provided with a bracket structure; the high-position LED light source is fixedly arranged on the support structure, and the connecting seat is arranged at the lower part of the support structure and is connected with the high-position LED light source. Further, in one embodiment, a branch structure extends from the support structure, and the high-position LED light source includes a flower-shaped light and is disposed on the branch structure; namely, a plurality of flower-shaped lamps are arranged on the branch-shaped structure, and each flower-shaped lamp is provided with at least one LED lamp bead; therefore, the branch-shaped structure forms a section of flowering branch, and the landscape lighting effect that flowers are in water and are illuminated is achieved by matching with the water tank. Further, in one embodiment, the support structure further extends to form a main branch structure, and the main branch structure extends to form a plurality of branch structures. Thus, the main branch structure and each branch-shaped structure are integrally formed to resemble a flower, and a light distribution scene resembling a flower tree is formed. Further, in one embodiment, the number of main branch structures on the stent structure is at least two. It can be understood that the branch-shaped structure and the flower-shaped lamp are connected to an external power supply line through a conductive circuit to obtain electric energy. Further, in one embodiment, the high-position LED light source includes a tubular structure, and the support structure further extends around at least one of the branch structures to form at least one tubular structure that is communicated end to end, that is, the tubular structure is arranged on the support structure as a part or all of the high-position LED light source; in one embodiment, the stent structure is provided with one, two or more tubular structures extending from end to end, each tubular structure surrounding at least one of the dendritic structures; in one embodiment, the surrounding of at least one of the branched structures includes surrounding outside at least one of the branched structures, and surrounding between and/or outside a plurality of the branched structures; further, an LED lamp bead is arranged inside the tubular structure, and in one embodiment, the LED lamp bead and the LED luminous body are the same in shape and structure; further, in one embodiment, the tubular structure comprises a power device, a transparent conduit and at least one LED lamp bead; the LED lamp beads are movably arranged in the transparent conduit; the transparent conduit surrounds at least one branch-shaped structure, is communicated with the transparent conduit end to end and is fixed on the bracket structure; the power device provides power for the LED lamp beads; the LED lamp beads move in the transparent conduit under the power action of the power device; that is to say, this embodiment also is equipped with LED lamp pearl in tubular structure. Further, the number of the LED lamp beads in the tubular structure or the transparent conduit is plural, for example, 5, 10, 20, or 100 LED lamp beads are movably disposed in the transparent conduit. Further, the number of the LED lamp beads is proportional to the length of the transparent conduit, for example, the number of the LED lamp beads in the transparent conduit is 1 per 10 cm of the length of the transparent conduit. Further, the LED lamp beads are arranged in the transparent conduit in a sliding or rolling mode, the LED lamp beads move in the transparent conduit under the power action of the power device, and the movement comprises sliding or rolling. Further, the width of the transparent conduit is 1.2 to 1.6 times of the diameter of the LED lamp bead. Therefore, the LED lamp beads cannot be arranged side by side in the transparent conduit, and the orderliness of the channel of the transparent conduit is ensured. Further, in one embodiment, the transparent conduit is a glass cylinder, wherein a cylindrical and/or arc-shaped channel is provided for the LED lamp bead to move inside the transparent conduit. Further, the transparent conduit is a glass cylinder body connected end to end. Further, transparent pipe is transparent setting entirely, and further, transparent pipe is transparent setting partially, transparent pipe is equipped with the printing opacity district, the printing opacity district is used for passing through the light of LED lamp pearl.

Furthermore, the transparent conduit is provided with a shielding area, and the shielding area is used for shielding the light of the LED lamp beads. Further, the transparent conduit 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 lamp bead. Furthermore, the transparent conduit 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 lamp bead, and the total area of each circular shielding area is 8% -12% of the area of the light transmitting area. Due to the design, light emitted by the LED lamp beads in the moving process can often but not always transmit out of the transparent conduit, so that the flashing property is added to the lighting effect, and the random illumination effect is more non-artificial.

In one embodiment, the transparent conduit is at least partially enclosed. Furthermore, the transparent conduit is provided with a through groove, so that on one hand, the transparent conduit is beneficial to light transmission, and on the other hand, the transparent conduit is beneficial to heat dissipation. Furthermore, the transparent conduit is provided with a plurality of through grooves which are parallel to each other, and it can be understood that the parallel to each other means that the through grooves or the 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 conduit; such design is favorable to realizing the cell body light-emitting of logical groove and transparent pipe inside scattering in order to follow transparent pipe's pipeline printing opacity.

In one embodiment, the transparent conduit is arranged in a totally enclosed manner. Therefore, the LED lamp beads can be prevented from being separated from the transparent conduit. In one embodiment, the transparent conduits are arranged end to end in a communicating manner, that is, the transparent conduits are arranged end to end in a communicating manner to form a loop transparent conduit. The transparent guide pipe is arranged in a totally-enclosed manner, namely the LED lamp beads cannot be separated from the transparent guide pipe when being arranged in the transparent guide pipe; for example, the totally closed setting of transparent pipe includes that the head and the tail both ends of transparent pipe seal the setting, the pipeline of transparent pipe seals the setting, or the head and the tail both ends of transparent pipe intercommunication sets up and the pipeline of transparent pipe seals, or the head and the tail both ends of transparent pipe intercommunication sets up and the pipeline of transparent pipe has seted up logical groove and has stopped LED lamp pearl breaks away from transparent pipe.

Further, in one embodiment, an elastic cushion body and a fluorescent layer arranged on the elastic cushion body are arranged on the inner wall of the transparent conduit, and the elastic cushion body and the fluorescent layer are used for generating contact deformation when the LED lamp beads pass through; the fluorescent layer is coated with fluorescent powder and used for emitting light in a dark environment; the elastic cushion body and the fluorescent layer form a narrow channel inside the transparent conduit, and the LED lamp beads are pressed to deform when passing through, so that the fluorescence changes, the dynamic effect of a light source is further improved, and the elastic cushion body and the fluorescent layer are matched with the light emission and sequential passing of the LED lamp beads, so that a good dynamic change effect of the light source is achieved; especially, the fluorescent layer advertisement has better effect.

Further, in one embodiment, the transparent conduit has at least 3 turning areas, and the turning areas are used for turning the LED lamp beads movably arranged in the transparent conduit by more than 75 degrees. Further, the transparent conduit has at least 4 of the turning regions. Further, the transparent conduit has at least 16 of the turning regions. Further, in one embodiment, the transparent conduit has a plurality of the motive devices; further, in one embodiment, the transparent conduit has a plurality of transparent conduits and a plurality of power devices, and each transparent conduit is provided with at least one power device; further, the transparent conduit is provided with at least one power device according to the length and/or ascending gradient of the transparent conduit; further, the transparent conduit is provided with at least two power devices according to the length and/or ascending gradient of the transparent conduit; further, the transparent conduit is provided with at least one of the power units prior to the position upstream of the transparent conduit. Go upward the position that LED lamp pearl goes upward or the ascending position of slope perpendicularly in transparent pipe promptly, set up at least one before going upward the position power device helps promoting the power of LED lamp pearl, avoids LED lamp pearl to be difficult to go upward. Further, the transparent conduit is provided with at least two upstream positions, and the transparent conduit is provided with at least one power device before the upstream position of the transparent conduit. In this way, transparent conduits of various shapes and paths can be realized.

In one embodiment, the tubular structure has a plurality of mutually-intersected transparent conduits, and each transparent conduit has at least one LED lamp bead. In one embodiment, the tubular structure has a plurality of transparent conduits that do not intersect each other, each of the transparent conduits being disposed parallel to each other. In one embodiment, the tubular structure has a plurality of transparent conduits which do not intersect with each other, and the coincidence degree of the projection of each transparent conduit on the ground is 20-40%. Therefore, a large number of LED lamp beads can emit light at each position of each transparent conduit at the same time, and therefore a plurality of moving bright spots are formed in a certain area, and the LED lamp beads can be used as atmosphere lamps and can also be used for light distribution or background light.

In one embodiment, the tubular structure has a plurality of transparent conduits which intersect, that is, the tubular structure has a plurality of transparent conduits, and the transparent conduits are arranged to intersect, that is, the transparent conduits are arranged to communicate; further, in one embodiment, the transparent conduits intersect at the same position, that is, the transparent conduits are arranged in communication at one position; furthermore, each transparent conduit is intersected at the same intersection position, a gating baffle is arranged at the intersection position, when one LED lamp bead arrives, one transparent conduit is randomly gated by the gating baffle according to a preset probability, so that the arrived LED lamp bead enters the gated transparent conduit, and the preset probabilities of the transparent conduits are the same. This is advantageous for further obtaining random dynamic lighting effects. Further, in one embodiment, the transparent conduit is provided with an opening and a sealing plate detachably mounted on the opening, and the LED lamp beads are placed into the transparent conduit from the opening or taken out of the transparent conduit by opening the sealing plate.

In one embodiment, a wireless charging coil is arranged inside or outside the transparent conduit, and the transparent conduit further comprises a wireless charging device connected with the wireless charging coil; the wireless charging device wirelessly charges the storage battery of the LED lamp beads inside the transparent conduit through the wireless charging coil and the wireless charging unit. Like this, need not to take out LED lamp pearl and just can charge for it to can realize using for a long time under the confined environment, be particularly suitable for the transparent pipe of totally enclosed, avoid inside the dust gets into transparent pipe.

Further, the power device is arranged inside or outside the transparent conduit; in one embodiment, the power device is arranged on two sides of the outer part of the transparent conduit. In one embodiment, the power device comprises a push rod or an elastic member; in one embodiment, the LED lamp beads are provided with magnetic members, the power device is an electromagnet, and the electromagnet accelerates the LED lamp beads by using lorentz force generated by an electromagnetic field in an electromagnetic system, so that the LED lamp beads obtain kinetic energy required by movement, that is, move under the power action 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. Like this, through utilizing electromagnetic force, have even and easy control's advantage, can form gravitation and repulsion through electromagnetic action in transparent pipe outside to do under the prerequisite that does not influence transparent pipe inner structure LED lamp pearl provides power, and then realizes better power output control effect. Further, the power device is arranged outside the transparent conduit 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 lamp beads 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, in one embodiment, the LED garden light source further comprises a water tank, a water flow direction controller and a plurality of LED floating bodies; the water tank is arranged below the high-position LED light source and is communicated end to end, the water tank is provided with a light-transmitting wall part, and the water tank is used for containing a certain volume of water to bear the LED floating bodies; the water flow direction controller is fixed in the water tank, at least part of the water flow direction controller is positioned in the water tank and is used for contacting with the water, and the water flow direction controller is used for controlling the water flow direction of the water; the LED floating body includes an LED illuminating body and a transparent lightweight portion at least partially covering an outer surface of the LED illuminating body. Above-mentioned LED gardens light source, the LED body floats in the aquatic of basin, and the position of LED body changes in the basin always, and the position that sends light also moves along with water in the basin always, and these changes are controlled in the approximate direction, but the subtlety is random and lack the law to can obtain the luminous effect of change, not only be applicable to indoor illumination decoration such as house, still be applicable to the occasion that needs irregular dynamic luminescence such as movie & TV, show, performance, amusement and business surpass. In one embodiment, the transparent lightweight portion comprises a plastic and/or inflatable member. Through adopting the transparent lightweight portion that density is less, make on the one hand that the LED body can float in the aquatic of basin, on the other hand makes the light that LED illuminating body sent can see through in the transparent lightweight portion. Further, the transparent light part comprises a plastic part with an air sealing cavity arranged inside, the air sealing cavity is arranged in a sealing mode and filled with air, and therefore the transparent light part with smaller density can be provided, and smaller mass of the LED floating body can be achieved on the premise of the same size. Further, the transparent lightweight part comprises a plurality of plastic parts and/or a plurality of inflatable parts; or the transparent light part comprises a plurality of plastic pieces with air sealing cavities inside; the plurality of plastic parts and/or the plurality of inflatable parts or the plurality of plastic parts with the air sealing cavities arranged inside are uniformly distributed relative to the LED illuminating body. Further, the LED luminary has a spherical or spheroidal shape. Further, the LED illuminating body is provided with a plurality of LED lamps, and one plastic piece or the inflatable piece or the plastic piece with the air sealing cavity arranged inside is arranged around the outer part of each LED lamp; the plastic part or the inflatable part or the plastic part with the air sealing cavity arranged inside surrounds the LED lamp, so that the LED lamp is protected from direct collision, light rays emitted by the LED lamp cannot be shielded, and the heat dissipation effect of the LED lamp caused by water in the water tank cannot be shielded. It is understood that the transparent in the transparent lightweight portion means capable of transmitting light, i.e., having a certain light transmittance. Further, the LED garden light source further comprises the water, and the water is contained in the water tank; that is, the LED garden light source further includes water received in the water tank, and it is understood that the LED garden light source further includes a volume of water received in the water tank. In normal use, this water needs to be replaced at intervals to avoid bacterial growth. Furthermore, the LED garden light source also comprises a water inlet pipe communicated with the water tank and a water outlet pipe communicated with the water tank, wherein the water inlet pipe is used for inputting an external water source into the water tank, and the water outlet pipe is used for discharging water in the water tank to the outside; thus, the water changing operation can be conveniently carried out. Furthermore, the water tank is respectively provided with a water inlet and a water outlet, the water inlet is communicated with the water inlet pipe, the water outlet is communicated with the water outlet pipe, and the calibers of the water inlet and the water outlet are both smaller than the minimum width of the LED floating body; further, in one embodiment, the LED floating body has a spherical structure or a similar spherical structure, and the aperture of the water inlet and the aperture of the water outlet are both smaller than the diameter or the minimum diameter of the LED floating body. Therefore, the LED floating body can be prevented from leaking out of the water tank or into the water outlet pipe when water is changed. In one embodiment, the water flow direction controller comprises a water pump and/or a propeller structure. Further, the water flow direction controller comprises a water pump and a propeller structure. Further, the water flow direction controller includes a plurality of water pumps. Further, the water flow direction controller comprises a plurality of propeller structures. Further, the water flow direction controller comprises a water pump and a plurality of propeller structures. Therefore, the water flow direction can be better controlled, the water flow rate is improved to a certain extent, and the position change speed of the LED floating body is further improved. It will be appreciated that for sinks arranged end to end, in one embodiment the sink has a dog-ear position. Further, the water tank has an arc-shaped folded angle position. Therefore, the adoption of the arc-shaped bevel position is beneficial to protecting the LED floating body and reducing the damage risk caused by collision. In one embodiment, the water trough has a height difference. Further, the water flow direction controller is used for controlling the water flow direction of the water according to the direction of the height difference. In one embodiment, the LED garden light source further comprises a vortex generator for generating a vortex. Therefore, the LED floating body in the water tank can generate a certain rotation amount, a certain degree of path unpredictability is added, and a variable is added to the position of the LED floating body in the water tank, so that more variable light-emitting effects can be obtained. Further, the number of the vortex generators is multiple. Further, in one embodiment, the LED garden light source further includes a plurality of vortex generators, the vortex generators in each group are divided into at least two groups, each vortex generator in each group is arranged in a zigzag shape, and the distance between two adjacent vortex generators is 4 to 6 times the maximum width of the LED floating body, so that the center distance between the vortex flows emitted by two adjacent vortex generators is 4 to 6 times the maximum width of the LED floating body, thereby enabling the LED floating body to generate an uncontrollable position change and to receive an appropriate traction force of the adjacent vortex generators when passing through the vortex generators, and at this time, due to the width limitation of the water tank and the limitation of the water amount, the forced movement of the LED floating body is random and irregular, thereby obtaining a varying light emitting effect. Further, in one embodiment, the vortex generator is fixed to the water tank and is at least partially located in the water tank and adapted to contact the water. Further, in one embodiment, the vortex generator includes a motor and a fan blade connected to an output shaft of the motor, the motor is fixed to the water tank, for example, fixed to the outside of the water tank, for example, fixed to the wall of the water tank or the outside of the wall, the output shaft is inserted through the wall of the water tank, and the fan blade is located in the water tank and is used for contacting with the water.

Further, in one embodiment, the water tank is at least partially enclosed. In one embodiment, the water tank is closed. Further, in one embodiment, the water tank is arranged in a fully closed manner; thus avoiding breeding mosquitoes. In one embodiment, the water flow direction controller is fixed in the water tank. Further, in one embodiment, the water tank is provided with a collecting area, one end or two ends of the collecting area are provided with control baffles, the control baffles are provided with a plurality of meshes, the meshes are used for enabling water to flow through and preventing the LED floating bodies from passing through, the control baffles are used for being opened or closed under the control, and the control baffles are used for preventing the LED floating bodies from passing through when being closed, so that the LED floating bodies are gathered in the collecting area, and the collection and the cleaning of the LED floating bodies are facilitated. In one embodiment, the maximum aperture of the mesh is smaller than the minimum width of the LED float.

Further, in one embodiment, the wall is made of glass, PMMA, PP, PVC, PET, PC, PS or ABS. In one embodiment, several shielding parts are arranged outside the wall part. The shielding part is used for shielding the light of the LED illuminating body. Further, the wall portion is provided with a plurality of shielding portions, the shielding portions are arranged at intervals, in one embodiment, the shielding portions are circular areas, and the diameter of each shielding portion is 70% -90% of the diameter of the LED illuminating body. Furthermore, the wall portion is provided with a light-transmitting area and a plurality of circular shielding portions distributed in the light-transmitting area at intervals, the circular shielding portions are arranged at intervals, the diameter of each circular shielding portion is 70% -90% of the diameter of the LED illuminating body, and the total area of each circular shielding portion is 8% -12% of the area of the light-transmitting area. The design is such that the light emitted by the LED luminary while floating is often, but not always, transmitted through the wall portion, thereby adding a flashing property to the lighting effect, with a more non-artificial random illumination effect.

Further, in one embodiment, the LED illuminating body is adapted to illuminate when in motion, i.e. when floating; further, in one embodiment, the LED illuminator is configured to illuminate when a rate of motion exceeds a threshold; in this way, the lighting state of the LED luminary can be regulated by controlling the rate of water flow. In one embodiment, the LED illuminating body is provided with a switch which is used for controlling the LED illuminating body to emit light when in motion; further, in one embodiment, the switch is used for controlling the LED illuminating body to emit light when the movement speed exceeds a threshold value; in one embodiment, the switch comprises a vibration switch or a dynamic balance switch. In one embodiment, the LED illuminating body has a spherical structure. Therefore, the LED illuminating body can roll or rotate in water, so that the light direction changes more, on one hand, the LED illuminating body has different light emitting directions in the water, and on the other hand, the light emitting direction changes continuously when the LED illuminating body floats along the water. Further, in one embodiment, the LED illuminating body is provided with a shell, and the transparent light-weight part at least partially covers the outer surface of the shell; further, at least one LED lamp is arranged on or in the housing, or a lamp cap of at least one LED lamp is positioned on the housing; further, in one embodiment, a flexible layer is disposed on the housing of the LED illuminator, and the flexible layer is provided with through holes at light exit positions of the LED illuminator. 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 the shape of a truncated cone, the smaller bottom surface of the truncated cone faces the LED illuminating body, and the larger bottom surface of the truncated cone faces the outside. Further, the flexible layer is made of an opaque 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. In one embodiment, the housing of the LED lighting body is provided with a light-transmissive protective layer. In one embodiment, the light transmissive protective layer completely covers the outer envelope of the LED luminary. 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. In this way, the light of the LED luminary can be transmitted out. Further, the light-transmitting protective layer is integrally provided with the transparent lightweight portion.

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 lighting body, 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 outer shell of the LED illuminating body and integrally form a ring shape. Further, the lamp caps of the LED lamps are uniformly distributed on the shell of the LED illuminating body and integrally form a plurality of rings which are parallel to each other. Further, the lamp caps of the LED lamps are uniformly distributed on the outer shell of the LED illuminating body and integrally form a regular polyhedron, the regular polyhedron comprises a regular tetrahedron, a regular hexahedron, a regular octahedron, a regular 12-face body or a regular 20-face body, and in one embodiment, the lamp caps of the six LED lamps are uniformly distributed on the outer shell of the LED illuminating body and integrally form a regular octahedron; in one embodiment, the lamp heads of eight LED lamps are uniformly distributed on the outer shell of the LED illuminating body to form a regular hexahedron; the rest of the examples are analogized. Furthermore, a flexible layer is arranged on the shell of the LED illuminating body, through holes are respectively formed in each light emitting position of the LED illuminating body on the flexible layer, light-transmitting materials are filled in the through holes to form cylinders or round platforms, and air bubbles which are not uniformly distributed are arranged inside each cylinder or round platform 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 or outside the water tank or the wall part of the water tank, and the water tank is further provided with a wireless charging device connected with the wireless charging coil; the wireless charging device wirelessly charges the storage battery of the LED illuminating body on the water tank through the wireless charging coil and the wireless charging unit. It is understood that the wireless charging device is connected to an external power supply line through a conductive line to obtain power. Thus, the LED illuminating body can be charged without being taken out, and long-term use in a closed environment can be realized. Further, in one embodiment, the water tank is provided with the wireless charging coil in the collection area or in a wall of the collection area, and a wireless charging device connected with the wireless charging coil is arranged outside the collection area or outside the wall of the collection area.

Further, the control module is a wireless control module for receiving an external control signal to switch on or off the connection between the energy supply module and each of the LED lamps, so that a user or an administrator can externally control the on or off of the LED illuminating body. Furthermore, the control modules of the LED illuminating bodies are uniformly arranged and used for uniformly receiving external control signals and simultaneously switching on or switching off the connection between the energy supply module and the LED lamps, so that the LED illuminating device has the advantages of simplicity and convenience in use and control by users.

It should be noted that other embodiments of the present invention further include an implementable LED garden light source formed by combining technical features of the above embodiments with each other.

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 LED garden light source is characterized by comprising a connecting seat, a support structure, a ground LED light source and a high-position LED light source;

the high-position LED light source is fixedly arranged on the support structure, and the connecting seat is arranged at the lower part of the support structure and is connected with the high-position LED light source; the ground LED light source is in signal connection with the high-position LED light source and is movably connected with the connecting seat;

the high-position LED light source is provided with a signal transceiver, and the ground LED light source is provided with a signal receiver; the signal transceiver is used for sending a control signal, the signal receiver is used for receiving and forwarding the control signal, and the ground LED light source is used for realizing light emitting control according to the control signal, wherein the light emitting control comprises light emitting, moving and charging;

the ground LED light source is provided with a self-walking structure, and the self-walking structure is used for enabling the ground LED light source to travel according to a preset tour path; the ground LED light source is provided with an LED luminous body, the self-propelled structure comprises a roller structure, a driving device, a battery pack structure and a path setting storage device, the self-propelled structure is provided with a shell, the LED luminous body is arranged on the shell, at least part of the roller structure is arranged outside the shell, and the driving device, the battery pack structure and the path setting storage device are all arranged inside the shell; the battery pack structure is provided with a connecting end part for connecting a power supply potential, and the connecting end part is movably inserted into the power supply potential; the battery pack structure is respectively connected with the driving device and the path setting storage device; the driving device is respectively connected with the path setting and storing device and the roller structure and is used for driving the roller structure to advance according to the tour path; the power supply potential is on the tour route, and the driving device is used for controlling the battery pack structure to be connected with the power supply potential when the ground LED light source reaches the power supply potential;

the connecting seat is provided with a signal emitter, the signal receiver is used for acquiring positioning information of the power supply potential according to the signal emitter, and the ground LED light source is used for connecting the power supply potential according to the positioning information; the control signal comprises regression information, the signal receiver is used for obtaining the regression information according to the signal transmitter, and the ground LED light source automatically moves to the connecting seat and is connected with the power supply potential according to the positioning information when receiving the regression information; the route setting and storing device is provided with a setting module and a storage module, the battery pack structure is respectively connected with the setting module and the storage module, the setting module is used for setting a priority route and the tour route, and the storage module is used for storing the priority route and the tour route; the driving device is respectively connected with the setting module and the storage module, and the charging device is used for controlling the driving device to directly drive the roller structure to move to the position of the power supply system according to the priority path when the electric quantity of the battery pack structure is lower than a preset threshold value; the setting module is further configured to set a roaming path, the storage module is further configured to store the roaming path, at least one intersection point exists between the roaming path and the priority path, the range of the roaming path is larger than that of the tour path, and the roaming path is connected to the tour path through a plurality of priority paths;

the support structure is also provided with a main branch structure in an extending mode, the main branch structure is provided with a plurality of branch-shaped structures in an extending mode, and the high-position LED light source comprises a flower-shaped lamp and is arranged on the branch-shaped structures; the high-position LED light source comprises a tubular structure, the support structure is provided with at least one tubular structure which is communicated end to end around at least one branch-shaped structure in an extending manner, and the tubular structure comprises a power device, a transparent conduit and at least one LED lamp bead; the LED lamp beads are movably arranged in the transparent conduit; the transparent conduit surrounds at least one branch-shaped structure, is communicated with the transparent conduit end to end and is fixed on the bracket structure; the power device provides power for the LED lamp beads; the LED lamp beads move in the transparent conduit under the power action of the power device;

the transparent guide tube 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 that of the LED lamp bead, and the total area of each circular shielding area is 8% -12% of that of the light transmitting area;

the inner wall of the transparent conduit is provided with an elastic cushion body and a fluorescent layer arranged on the elastic cushion body, and the elastic cushion body and the fluorescent layer are used for generating contact deformation when the LED lamp beads pass through; the fluorescent layer is coated with fluorescent powder and used for emitting light in a dark environment; the elastic cushion body and the fluorescent layer form a narrow channel inside the transparent conduit, and the LED lamp beads deform under pressure when passing through the narrow channel.

2. The LED garden light source of claim 1, wherein the high-level LED light source comprises at least one LED strip.

3. The LED garden light source of claim 1, wherein the high-position LED light source comprises at least one LED tubular lighting structure.

4. The LED garden light source of claim 3, wherein the LED tubular lighting structure comprises an LED tube.

5. The LED garden light source of claim 1, wherein the high-position LED light source comprises at least one LED lantern.

6. The LED garden light source of claim 1, wherein the transparent conduit has a plurality of the transparent conduits and a plurality of the power devices, the transparent conduit being provided with at least two of the power devices for the transparent conduit according to a length and/or an upward slope of the transparent conduit; the power device is arranged on two sides of the outside of the transparent conduit, the LED lamp beads are provided with magnetic pieces, the power device is an electromagnet, and the electromagnet accelerates the LED lamp beads by utilizing the Lorentz force generated by an electromagnetic field in an electromagnetic system; the electromagnet comprises an energy supply assembly, an accelerator and an electromagnetic switch, wherein the energy supply assembly comprises a storage battery pack, a magnetic flux compression device or a single-pole generator and is used for storing energy; the accelerator comprises an orbital accelerator powered by a low-voltage direct-current monopole generator or a coaxial synchrotron adopting a discrete or continuous coil structure and is used 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.

7. The LED garden light source of claim 6, further comprising a water tank, a water flow direction controller and a plurality of LED floats; the water tank is arranged below the high-position LED light source, is communicated end to end and is fully sealed, and is provided with a light-transmitting wall part and used for containing a certain volume of water to bear the LED floating bodies; the water flow direction controller is fixed in the water tank, at least part of the water flow direction controller is positioned in the water tank and is used for contacting with the water, and the water flow direction controller is used for controlling the water flow direction of the water; the LED floating body comprises an LED illuminating body and a transparent light-weight part at least partially covering the outer surface of the LED illuminating body; the transparent light part comprises a plurality of plastic parts and/or a plurality of inflatable parts; the plurality of plastic parts and/or the plurality of inflatable parts are uniformly distributed relative to the LED illuminating body; the LED illuminating body is provided with a plurality of LED lamps, and one plastic piece or the inflatable piece or the plastic piece with the air sealing cavity arranged inside is arranged around the outside of each LED lamp; the LED garden light source further comprises a plurality of vortex generators, the vortex generators are divided into at least two groups, each vortex generator in each group is arranged in a zigzag shape, the distance between every two adjacent vortex generators is 4-6 times of the maximum width of the LED floating body, and therefore the central distance between vortex flows emitted by the two adjacent vortex generators is 4-6 times of the maximum width of the LED floating body.

8. The LED garden light source as claimed in claim 1, wherein the transparent light part comprises a plurality of plastic members having air tight cavities therein, and the plurality of plastic members having air tight cavities therein are uniformly distributed with respect to the LED illuminator.

9. The LED garden light source as claimed in any one of claims 1 to 8, wherein the high-position LED light source is provided with a central light emitting area and at least two peripheral light emitting areas, the connecting base is arranged below the central light emitting area and connected with the central light emitting area, and each peripheral light emitting area is respectively connected with the central light emitting area.

10. The LED garden light source of claim 9, wherein the central light emitting region is circular.

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