CN216556754U - Lighting device capable of automatically tracking - Google Patents

Abstract

The utility model discloses an illuminating device capable of automatically tracking, which can sense whether a moving human body exists in a sensing range through a sensing element to correspondingly control the illumination lamp source to be turned on or off when in work, controls the illumination lamp source to be turned on when the sensing sensor I detects that the moving human body exists in the sensing range, controls the illumination lamp source to be turned on when the sensing sensor I detects that the moving human body enters the sensing range of the sensing sensor II from the sensing range of the sensing sensor I, controls the illumination lamp source to be turned off or turned off in a delayed mode through the sensing sensor I, controls the illumination lamp source to be turned on through the sensing sensor II, and controls the illumination lamp source to be turned off when the moving human body leaves the sensing range of the sensing sensor II, so that the illuminating device can correspondingly turn on or turn off the illumination lamp source I or the illumination lamp source II according to the fact that the moving human body enters the sensing range of the sensing element, has high integration, compact structure, simple structure, low cost, energy conservation and high practicability.

Description

Lighting device capable of automatically tracking

[ technical field ] A method for producing a semiconductor device

The utility model relates to the technical field of illumination, in particular to an illumination device capable of automatically tracking.

[ background of the utility model ]

Present response lamp is usually including the illumination lamp source and be used for the response to detect and remove the human body and open or the inductive sensor who closes in order to control the illumination lamp source, and above-mentioned response lamp is in order to reach required response scope, can install a large amount of LED lamp pearls in order to realize large-range illuminating effect on the mounted position usually, for this reason, when inductive sensor detected someone to pass through, then control whole LED lamp pearls and open and realize the illumination, has with high costs and the high problem of loss.

In addition, some response lamps have the problem of complicated structure through increasing slewing mechanism in order to adjust the response scope of illumination lamp source at present.

Therefore, the present invention has been made in view of the above problems.

[ Utility model ] content

The utility model aims to overcome the defects of the prior art, provides an illuminating device capable of automatically tracking, and can improve the problems in the prior art, whether a moving human body exists in a sensing range can be sensed and detected through a sensing element so as to correspondingly control the illumination lamp source to be turned on or off, when the sensing sensor I detects that the moving human body exists in the sensing range, the illumination lamp source I is controlled to be turned on, when the moving human body enters the sensing range of a sensing sensor II from the sensing range of the sensing sensor I, the illumination lamp source I is controlled to be turned off or turned off in a delayed mode through the sensing sensor I, the illumination lamp source II is controlled to be turned on through the sensing sensor II, and when the moving human body leaves the sensing range of the sensing sensor II, the illumination lamp source I or the illumination lamp source II is controlled to be turned off through the sensing sensor II, so that the illumination lamp source I or the illumination lamp source II can be correspondingly turned on or turned off according to the fact that the moving human body enters the sensing range of the sensing element, the system has the characteristics of high integration, compact structure, simple structure, low cost, energy conservation and high practicability.

The utility model is realized by the following technical scheme:

an illuminating device capable of automatically tracking comprises a main body 1, wherein at least two groups of sensing elements capable of sensing and detecting the movement of a human body are arranged on the main body 1, each group of sensing elements has a sensing range, the two groups of sensing elements are a first sensing sensor 2 and a second sensing sensor 3 respectively, a first illuminating lamp source 4 and a second illuminating lamp source 5 are further arranged on the main body 1, the first illuminating lamp source 4 and the second illuminating lamp source 5 are respectively controlled by the first sensing sensor 2 and the second sensing sensor 3 in a sensing mode, and when the first sensing sensor 2 detects that the moving human body enters the sensing range, the first illuminating lamp source 4 is controlled to be turned on; when the moving human body enters the sensing range of the second sensing sensor 3 from the sensing range of the first sensing sensor 2, the second sensing sensor 3 controls the second lighting lamp source 5 to be turned on, and the first sensing sensor 2 controls the first lighting lamp source 4 to be turned off or turned off in a delayed mode; when the moving human body leaves the sensing range of the second sensing sensor 3, the second sensing sensor 3 controls the second lighting lamp source 5 to be turned off or turned off in a delayed mode.

According to the lighting device capable of automatically tracking, the sensing range of the first sensing sensor 2 is partially overlapped with the sensing range of the second sensing sensor 3, when a moving human body enters the overlapped part of the sensing ranges of the first sensing sensor 2 and the second sensing sensor 3, the first sensing sensor 2 and the second sensing sensor 3 correspondingly control the first lighting lamp source 4 and the second lighting lamp source 5 to be turned on, and when the moving human body leaves from the overlapped part of the sensing ranges of the first sensing sensor 2 and the second sensing sensor 3, the first sensing sensor 2 and the second sensing sensor 3 correspondingly control the first lighting lamp source 4 and the second lighting lamp source 5 to be turned off or turned off in a delayed mode.

According to the lighting device capable of automatically tracking, the main body 1 is further provided with the MCU, and the first induction sensor 2 and the second induction sensor 3 correspondingly control the first lighting lamp source 4 and the second lighting lamp source 5 to be turned on or turned off through the MCU.

The lighting device capable of automatically tracking is characterized in that the main body 1 is further provided with a photosensitive sensor, and the photosensitive sensor controls the lighting lamp source I4 and the lighting lamp source II 5 to be turned on or off through the MCU.

As described above, in the lighting apparatus capable of automatically tracking, the first inductive sensor 2 and the second inductive sensor 3 are both PIR sensors, and the main body 1 is connected with a fresnel lens for covering the PIR sensors.

The lighting device capable of automatically tracking as described above, the main body 1 includes a mounting base 11 and a lamp housing 12 connected to the mounting base 11, the lamp housing 12 is provided with a light transmitting opening 121, the light transmitting opening 121 is connected to a light transmitting cover 122, a lens 123 or a reflector is provided in the lamp housing 12, the first lighting lamp source 4 and the second lighting lamp source 5 are both provided in the lamp housing 12, and the lighting beams of the first lighting lamp source 4 and the second lighting lamp source 5 irradiate on the light transmitting cover 122 and the lens 123, or the reflector reflects the lighting beams of the first lighting lamp source 4 and the second lighting lamp source 5 on the light transmitting cover 122; and the first induction sensor 2 and the second induction sensor 3 are both arranged on the mounting seat 11.

In the lighting device capable of automatically tracking as described above, the rotating structure 6 capable of rotating the lamp housing 12 relative to the mounting base 11 is disposed between the lamp housing 12 and the mounting base 11.

According to the lighting device capable of automatically tracking, a connecting block 125 is arranged between the lamp housing 12 and the mounting base 11, and one end of the connecting block 125 is connected with the lamp housing 12; the rotating structure 6 includes a connecting shaft 61 disposed at the other end of the connecting block 125, and a connecting hole sleeve 62 is disposed on the mounting seat 11 for allowing the connecting shaft 61 to rotate so that the lamp housing 12 can rotate along the circumferential direction outside the mounting seat 11.

The lighting device capable of automatically tracking as described above, the lamp housing 12 is provided with a rotating block 124; the rotating structure 6 further includes a rotating hole sleeve 63 disposed at one end of the connecting block 125, and the rotating block 124 is provided with a rotating shaft 64 penetrating through the rotating hole sleeve 63 so that the lamp housing 12 can rotate relative to the mounting base 11.

As described above, in the lighting device capable of automatically tracking, the end of the mounting base 11 is provided with the mounting location 110 for the connection belt to pass through to connect the mounting base 11 with the outside, and the mounting location 110 includes the transverse hole 1101 and the vertical hole 1102.

The utility model also provides an illuminating device capable of automatically tracking, which comprises a main body 1, wherein at least one group of sensing elements capable of sensing and detecting the movement of a human body are arranged on the main body 1, the sensing elements are provided with at least two groups of sensing ranges, the two groups of sensing ranges are respectively a sensing range I and a sensing range II, an illuminating lamp source I4 and an illuminating lamp source II 5 are also arranged on the main body 1, the illuminating lamp source I4 and the illuminating lamp source II 5 are controlled by sensing of the sensing elements, and when the sensing elements detect that the moving human body enters the sensing ranges, the sensing elements control the illuminating lamp source I4 to be turned on; when the moving human body enters the sensing range II from the sensing range I, the sensing element controls the lighting lamp source II 5 to be turned on and controls the lighting lamp source I4 to be turned off or turned off in a delayed mode; when the moving human body leaves the second sensing range, the second lighting lamp source 4 is controlled to be turned off or turned off in a delayed mode by the sensing element.

Compared with the prior art, the utility model has the following advantages:

1. when the utility model works, whether a moving human body exists in the sensing range can be sensed and detected through the sensing element so as to correspondingly control the lighting lamp source I or the lighting lamp source II to be turned on or turned off, when the sensing sensor I detects that the moving human body exists in the sensing range, the lighting lamp source I is controlled to be turned on, when the moving human body enters the sensing range of the sensing sensor II from the sensing range of the sensing sensor I, the lighting lamp source I is controlled to be turned off or turned off in a delayed mode, the lighting lamp source II is controlled to be turned on by the sensing sensor II, when the moving human body leaves the sensing range of the sensing sensor II, the lighting lamp source II is controlled to be turned off or turned off in a delayed mode, therefore, the utility model can correspondingly turn on or turn off the lighting lamp source I or the lighting lamp source II according to the fact that the moving human body enters the sensing range of the sensing element, compared with the sensing lamp in the prior art, the problem of high loss exists because all the lighting lamp sources are required to be turned on, the utility model only needs to correspondingly turn on the lighting lamp source for lighting the induction range of the moving human body, and has the characteristics of high integration, compact structure, simple structure, low cost, energy conservation and high practicability.

2. In order to improve the sensing capability of the sensing sensor to a moving human body and improve the sensing detection effect, the first sensing sensor and the second sensing sensor are both PIR sensors, and the main body is connected with a Fresnel lens used for covering the PIR sensors.

[ description of the drawings ]

The following detailed description of embodiments of the utility model is provided in conjunction with the appended drawings, in which:

fig. 1 is a perspective view of embodiment 1 of the present invention.

Fig. 2 is an overall sectional view of embodiment 1 of the present invention.

Fig. 3 is a schematic view of illumination light beams of an illumination lamp source i and an illumination lamp source ii according to embodiment 1 of the present invention.

Fig. 4 is an exploded view of example 1 of the present invention.

Fig. 5 is an exploded view of the second embodiment of the present invention 1.

Fig. 6 is a side view of an induction sensor of embodiment 1 of the present invention.

Fig. 7 is a front view of an induction sensor of embodiment 1 of the present invention.

Fig. 8 is a perspective view of embodiment 2 of the present invention.

Fig. 9 is a schematic structural diagram of embodiment 2 of the present invention.

Fig. 10 is a perspective view of embodiment 3 of the present invention.

Fig. 11 is a schematic structural diagram of embodiment 3 of the present invention.

Fig. 12 is an overall sectional view of embodiment 3 of the present invention.

Fig. 13 is a schematic view of illumination light beams of an illumination light source i and an illumination light source ii according to embodiment 3 of the present invention.

Fig. 14 is a perspective view of embodiment 4 of the present invention.

Fig. 15 is a sectional view of embodiment 4 of the present invention.

Fig. 16 is a perspective view of embodiment 5 of the present invention.

Fig. 17 is a sectional view of embodiment 5 of the present invention.

Fig. 18 is a schematic control diagram according to embodiments 1 to 5 of the present invention.

Fig. 19 is a schematic control diagram of another embodiment of the present invention.

[ detailed description ] embodiments

Embodiments of the present invention will be described in detail below with reference to fig. 1 to 19.

Examples 1, 3:

as shown in fig. 1-7, 10-13, and 18, the illumination device capable of automatically tracking according to the present invention includes a main body 1, at least two sets of sensing elements capable of sensing and detecting movement of a human body are disposed on the main body 1, each set of sensing elements has a sensing range, the two sets of sensing elements are a first sensing sensor 2 and a second sensing sensor 3, the main body 1 is further disposed with a first illumination lamp source 4 and a second illumination lamp source 5, the first illumination lamp source 4 and the second illumination lamp source 5 are respectively controlled by a first sensing sensor 2 and a second sensing sensor 3, and when the first sensing sensor 2 detects that the moving human body enters the sensing range, the first illumination lamp source 4 is controlled to be turned on; when the moving human body enters the sensing range of the second sensing sensor 3 from the sensing range of the first sensing sensor 2, the second sensing sensor 3 controls the second lighting lamp source 5 to be turned on, and the first sensing sensor 2 controls the first lighting lamp source 4 to be turned off or turned off in a delayed mode; when the moving human body leaves the sensing range of the second sensing sensor 3, the second sensing sensor 3 controls the second lighting lamp source 5 to be turned off or turned off in a delayed mode. The utility model can sense whether a moving human body exists in the sensing range through the sensing element to correspondingly control the lighting lamp source I or the lighting lamp source II to be turned on or turned off, when the sensing sensor I detects that the moving human body exists in the sensing range, the lighting lamp source I is controlled to be turned on, when the moving human body enters the sensing range of the sensing sensor II from the sensing range of the sensing sensor I, the sensing sensor I controls the lighting lamp source I to be turned off or turned off in a delayed mode, the sensing sensor II controls the lighting lamp source II to be turned on or turned off in a delayed mode, when the moving human body leaves the sensing range of the sensing sensor II, the sensing sensor II controls the lighting lamp source II to be turned off or turned off in a delayed mode, therefore, the utility model can correspondingly turn on or turn off the lighting lamp source I or the lighting lamp source II according to the moving human body entering the sensing range of the sensing element, compared with the sensing lamp in the prior art, the problem of high loss exists because all the lighting lamp sources need to be turned on, the utility model only needs to correspondingly turn on the lighting lamp source for lighting the induction range of the moving human body, and has the characteristics of high integration, compact structure, simple structure, low cost, energy conservation and high practicability. The inductive elements used in the embodiments 1 and 3 are binary inductive elements.

As shown in fig. 1-7, 10-13 and 18, the sensing range of the first sensing sensor 2 and the sensing range of the second sensing sensor 3 are partially overlapped, when a moving human body enters the overlapped part of the sensing ranges of the first sensing sensor 2 and the second sensing sensor 3, the first sensing sensor 2 and the second sensing sensor 3 correspondingly control the first lighting lamp source 4 and the second lighting lamp source 5 to be turned on, and when the moving human body leaves from the overlapped part of the sensing ranges of the first sensing sensor 2 and the second sensing sensor 3, the first sensing sensor 2 and the second sensing sensor 3 correspondingly control the first lighting lamp source 4 and the second lighting lamp source 5 to be turned off or turned off in a delayed mode.

As shown in fig. 1-7, 10-13 and 18, in order to better control the on or off of the lighting lamp source, the main body 1 is further provided with an MCU, and the first inductive sensor 2 and the second inductive sensor 3 correspondingly control the on or off of the first lighting lamp source 4 and the second lighting lamp source 5 through the MCU.

As shown in fig. 1-7, 10-13 and 18, the main body 1 is further provided with a photosensitive sensor, and the photosensitive sensor controls the lighting lamp source one 4 and the lighting lamp source two 5 to be turned on or off through the MCU. In this embodiment, the main body 1 is further provided with a control switch, not shown, for controlling the connection or disconnection between the photosensor and the MCU.

As shown in fig. 1-7, 10-13 and 18, in order to improve the sensing capability of the sensing sensor to the moving human body and improve the sensing detection effect, the first sensing sensor 2 and the second sensing sensor 3 are both PIR sensors, and the main body 1 is connected with a fresnel lens for covering the PIR sensors.

As shown in fig. 1-7, 10-13 and 18, the main body 1 includes a mounting base 11 and a lamp housing 12 connected to the mounting base 11, a light-transmitting opening 121 is formed in the lamp housing 12, the light-transmitting opening 121 is connected to a light-transmitting cover 122, a lens 123 is arranged in the lamp housing 12, the first illumination lamp source 4 and the second illumination lamp source 5 are both arranged in the lamp housing 12, and illumination light beams of the first illumination lamp source 4 and the second illumination lamp source 5 irradiate on the light-transmitting cover 122 and the lens 123, so that the illumination light beams passing through the lens are more uniform and softer; and the first induction sensor 2 and the second induction sensor 3 are both arranged on the mounting seat 11.

As shown in fig. 1 to 7 and 18, in order to adjust the lamp housing to adjust the illumination angle of the first illumination lamp source and the second illumination lamp source and adapt to the illumination requirements of different scene environments, a rotating structure 6 capable of rotating the lamp housing 12 relative to the mounting base 11 is disposed between the lamp housing 12 and the mounting base 11.

As shown in fig. 1-7 and 18, in order to realize multi-angle adjustment of the illumination angle of the illumination lamp source, a connection block 125 is arranged between the lamp housing 12 and the mounting base 11, and one end of the connection block 125 is connected with the lamp housing 12; the rotating structure 6 includes a connecting shaft 61 disposed at the other end of the connecting block 125, and a connecting hole sleeve 62 is disposed on the mounting seat 11 for allowing the connecting shaft 61 to rotate so that the lamp housing 12 can rotate along the circumferential direction outside the mounting seat 11.

In order to make the connection block 125 and the mounting seat 11 be connected more firmly, the lower end of the connection rotating shaft 61 is provided with a limiting block which can abut against the edge of the lower port of the connection hole sleeve 62 to prevent the connection rotating shaft 61 from separating from the mounting seat 11 when the connection rotating shaft 61 is inserted into the connection hole sleeve 62, and the limiting block is not marked in the drawing.

As shown in fig. 1-7 and 18, in order to realize multi-angle adjustment of the illumination angle of the illumination lamp source, a rotating block 124 is provided on the lamp housing 12; the rotating structure 6 further includes a rotating hole sleeve 63 disposed at one end of the connecting block 125, and the rotating block 124 is provided with a rotating shaft 64 penetrating through the rotating hole sleeve 63 so that the lamp housing 12 can rotate relative to the mounting base 11.

For the convenience of disassembly and assembly, the rotating block 124 is connected with the lamp housing 12 by a snap fit.

As shown in fig. 1-7 and 10-13, an end of the mounting seat 11 is provided with a mounting location 110 for a connecting belt to pass through to connect the mounting seat 11 with the outside, and the mounting location 110 includes a transverse hole 1101 and a vertical hole 1102. When the lighting lamp is installed, the connection band is inserted into the horizontal hole 1101 or the vertical hole 1102 and is connected and bound with an external installation position, so that the irradiation direction of the lighting lamp source can be changed correspondingly.

As shown in fig. 1-7 and 10-13, the first illumination light source 4 is a high beam and the second illumination light source 5 is a low beam. In order to better control the first lighting lamp source 4 and the second lighting lamp source 5, a distance sensor is further arranged on the main body 1, and the distance sensor is a radar sensor.

As shown in fig. 1-7 and 10-13, the first lighting lamp source 4 and the second lighting lamp source 5 are PCB boards with LED beads.

Working principle of the embodiments 1 and 3:

as shown in fig. 1-7, 10-13 and 18, when the first induction sensor detects that a moving human body enters the induction range during operation, the first induction sensor controls the lighting lamp source to be turned on through the MCU for lighting; when the moving human body moves from the sensing range of the first sensing sensor to the sensing range of the second sensing sensor, the first sensing sensor controls the first lighting lamp source to be turned off or turned off in a delayed mode through the MCU, and meanwhile, the second sensing sensor controls the second lighting lamp source to be turned on through the MCU to illuminate; when the moving human body moves from the sensing range of the second sensing sensor to the sensing range of the N sensing sensor, the second sensing sensor controls the second lighting lamp source to be turned off or turned off in a delayed mode through the MCU, and meanwhile, the N sensing sensor controls the lighting lamp source to be turned on through the MCU to illuminate; when the moving human body leaves from the sensing range of the sensing sensor N, the sensing sensor N controls the lighting lamp source N to be turned off or turned off in a delayed mode through the MCU.

Example 2:

embodiment 2 is different from embodiment 1 in that, as shown in fig. 8 and 9, the number of the lamp housings 12 is three, each of the lamp housings 12 is rotatably connected with the mounting base 11 through a rotating structure 6, the three lamp housings 12 are sequentially arranged along the circumferential direction of the outer periphery of the mounting base 11, the number of the induction sensors is 6, and each of the induction sensors is correspondingly controlled and connected with an illumination lamp source through an MCU.

Example 4:

embodiment 4 is different from embodiment 1 in that, as shown in fig. 14 and 15, a light reflecting member is provided in the lamp housing 12, and the light reflecting member reflects the illumination light beams of the illumination light sources one 4 and two 5 on the light-transmitting cover 122, so that the illumination light beams reflected by the light reflecting member are more uniform and softer, and the illumination light beams are prevented from directly irradiating the outside. In this embodiment, the reflector is a reflective cup, and the second illumination light source 5 is located inside the reflective cup.

Example 5:

embodiment 5 is different from embodiment 2 in that, as shown in fig. 16 and 17, a reflector is disposed in the lamp housing 12, and reflects the illumination light beams of the illumination light source one 4 and the illumination light source two 5 on the light-transmitting cover 122, so that the illumination light beams reflected by the reflector are more uniform and softer, and the illumination light beams are prevented from directly irradiating the outside. In this embodiment, the reflector is a reflective cup, and the second illumination light source 5 is located inside the reflective cup.

As shown in fig. 19, the illumination device capable of automatically tracking according to the present invention includes a main body 1, wherein at least one set of sensing element capable of sensing and detecting the movement of a human body is disposed on the main body 1, the sensing element has at least two sets of sensing ranges, the two sets of sensing ranges are a first sensing range and a second sensing range, the main body 1 is further disposed with a first illumination light source 4 and a second illumination light source 5, the first illumination light source 4 and the second illumination light source 5 are controlled by the sensing element, and when the sensing element detects that the moving human body enters the first sensing range, the sensing element controls the first illumination light source 4 to be turned on; when the moving human body enters the sensing range II from the sensing range I, the sensing element controls the lighting lamp source II 5 to be turned on and controls the lighting lamp source I4 to be turned off or turned off in a delayed manner; when the moving human body leaves the sensing range II, the sensing element controls the lighting lamp source II 4 to be turned off or turned off in a delayed mode. The present embodiment is different from embodiments 1 and 3 in that the inductive element used in the present embodiment is a quaternary inductive element. The sensing element in this embodiment has at least two sets of sensing angles, and different sensing ranges of the sensing element are formed by different sensing angles.

Claims (11)

1. An illuminating device capable of automatically tracking is characterized by comprising a main body (1), wherein at least two groups of sensing elements capable of sensing and detecting movement of a human body are arranged on the main body (1), each group of sensing elements is provided with a sensing range, the two groups of sensing elements are a first sensing sensor (2) and a second sensing sensor (3), the main body (1) is further provided with a first illuminating lamp source (4) and a second illuminating lamp source (5), the first illuminating lamp source (4) and the second illuminating lamp source (5) are respectively controlled by the first sensing sensor (2) and the second sensing sensor (3) in a sensing mode, and when the first sensing sensor (2) detects that the moving human body enters the sensing range, the first illuminating lamp source (4) is controlled to be turned on; when the moving human body enters the sensing range of the second sensing sensor (3) from the sensing range of the first sensing sensor (2), the second sensing sensor (3) controls the second lighting lamp source (5) to be turned on, and the first sensing sensor (2) controls the first lighting lamp source (4) to be turned off or turned off in a delayed manner; when the moving human body leaves the sensing range of the second sensing sensor (3), the second sensing sensor (3) controls the second lighting lamp source (5) to be turned off or turned off in a delayed mode.

2. The auto-traceable lighting device according to claim 1, wherein the sensing range of the first sensing sensor (2) and the sensing range of the second sensing sensor (3) partially overlap, when the moving body enters the overlapping portion of the sensing ranges of the first sensing sensor (2) and the second sensing sensor (3), the first sensing sensor (2) and the second sensing sensor (3) correspondingly control the first lighting lamp (4) and the second lighting lamp (5) to be turned on, and when the moving body leaves the overlapping portion of the sensing ranges of the first sensing sensor (2) and the second sensing sensor (3), the first sensing sensor (2) and the second sensing sensor (3) correspondingly control the first lighting lamp (4) and the second lighting lamp (5) to be turned off or turned off with a delay.

3. The lighting device capable of automatically tracking according to claim 1, wherein the main body (1) is further provided with an MCU, and the first inductive sensor (2) and the second inductive sensor (3) correspondingly control the first lighting lamp source (4) and the second lighting lamp source (5) to be turned on or off through the MCU.

4. The lighting device capable of automatically tracking according to claim 3, wherein the main body (1) is further provided with a photosensitive sensor, and the photosensitive sensor controls the first lighting lamp source (4) and the second lighting lamp source (5) to be turned on or off through the MCU.

5. An automatically traceable lighting device according to any of claims 1-4, characterized in that said first (2) and second (3) inductive sensors are each PIR sensors, and said main body (1) is connected with a Fresnel lens for covering said PIR sensors.

6. The lighting device capable of automatically tracking according to any one of claims 1 to 4, wherein the main body (1) comprises a mounting base (11) and a lamp housing (12) connected with the mounting base (11), the lamp housing (12) is provided with a light transmitting opening (121), the light transmitting opening (121) is connected with a light transmitting cover (122), the lamp housing (12) is provided with a lens (123) or a reflector, the first lighting lamp source (4) and the second lighting lamp source (5) are both arranged in the lamp housing (12), and the lighting beams of the first lighting lamp source (4) and the second lighting lamp source (5) irradiate on the light transmitting cover (122) and the lens (123), or the reflector reflects the lighting beams of the first lighting lamp source (4) and the second lighting lamp source (5) on the light transmitting cover (122); the first induction sensor (2) and the second induction sensor (3) are arranged on the mounting seat (11).

7. The lighting device capable of automatically tracking according to claim 6, wherein a rotating structure (6) capable of rotating the lamp housing (12) relative to the mounting seat (11) is arranged between the lamp housing (12) and the mounting seat (11).

8. The lighting device capable of automatically tracking according to claim 7, wherein a connecting block (125) is arranged between the lamp housing (12) and the mounting seat (11), and one end of the connecting block (125) is connected with the lamp housing (12); rotating-structure (6) are including establishing connection pivot (61) on the connecting block (125) other end, be equipped with on mount pad (11) and supply to connect pivot (61) and rotate so that lamp body (12) can be along mount pad (11) outside circumferential direction's connecting hole cover (62).

9. The lighting device capable of automatically tracking as claimed in claim 8, wherein said lamp housing (12) is provided with a rotating block (124); the rotating structure (6) further comprises a rotating hole sleeve (63) arranged at one end of the connecting block (125), and a rotating shaft (64) penetrating through the rotating hole sleeve (63) to enable the lamp housing (12) to rotate relative to the mounting base (11) is arranged on the rotating block (124).

10. An automatically traceable lighting device according to claim 6, characterized in that said mounting seat (11) is provided at the end with a mounting position (110) for the connection strap to pass through to connect said mounting seat (11) with the outside, said mounting position (110) comprising a transverse hole (1101) and a vertical hole (1102).

11. The lighting device capable of automatically tracking is characterized by comprising a main body (1), wherein at least one group of sensing elements capable of sensing and detecting the movement of a human body are arranged on the main body (1), the sensing elements are provided with at least two groups of sensing ranges, the two groups of sensing ranges are a sensing range I and a sensing range II respectively, a lighting lamp source I (4) and a lighting lamp source II (5) are further arranged on the main body (1), the lighting lamp source I (4) and the lighting lamp source II (5) are controlled by sensing of the sensing elements, and when the sensing elements detect that the moving human body enters the sensing ranges, the sensing elements control the lighting lamp source I (4) to be turned on; when the moving human body enters the sensing range II from the sensing range I, the sensing element controls the lighting lamp source II (5) to be turned on and controls the lighting lamp source I (4) to be turned off or turned off in a delayed manner; when the moving human body leaves the second sensing range, the second lighting lamp source (4) is controlled to be turned off or turned off in a delayed mode by the sensing element.

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