CN114441148A - Courtyard lamp illumination detection feedback marking device and method - Google Patents

Abstract

The invention belongs to the technical field of lamp illumination detection, and particularly relates to a device and a method for detecting and feeding back a marker for the illumination of a garden lamp. This courtyard lamp illuminance detects feedback mark device includes: the center of the detection ball is fixed with a detected garden lamp through the lamp fixing component; a perception simulation component; the adjusting component comprises a range adjusting button and a brightness adjusting button which are respectively suitable for sending out a range adjusting signal and a brightness adjusting signal when being pressed; a marker rod assembly; and the control module is suitable for controlling the corresponding marking rod assembly to extend out according to the received range adjusting signal until the marking rod assembly abuts against the corresponding position of the outer surface of the garden lamp to be detected so as to leave a range adjusting mark, and controlling the corresponding marking rod assembly to extend out according to the received brightness adjusting signal until the marking rod assembly abuts against the corresponding position of the outer surface of the garden lamp to be detected so as to leave a brightness adjusting mark. By the invention, a tester can intuitively know how to adjust the appearance of the garden lamp to be tested.

Description

Courtyard lamp illumination detection feedback marking device and method

Technical Field

The invention belongs to the technical field of lamp illumination detection, and particularly relates to a device and a method for detecting and feeding back a marker for the illumination of a garden lamp.

Background

The special-shaped lamp is a lamp with the appearance different from lamps with conventional shapes such as a tubular lamp, a spherical lamp and the like. With the rise of consumption level, the special-shaped lamp has better decorative effect, especially occupies larger and larger market of courtyard lighting and lawn lighting, and is a direction of lamp development.

Because the special-shaped lamp has a unique appearance and a light-emitting structure different from that of a conventional lamp, it is necessary to consider the lighting effect of the garden lamp with a new shape, including the lighting range and the illumination intensity of all places in the lighting range, and according to the result of the study, the appearance of the garden lamp is adjusted, for example, the boundary line between a light-emitting region (light-transmitting housing) and a non-light-emitting region (a metal or plastic structure-like light-transmitting housing) is changed to obtain the required lighting effect, which is also necessary before the production, but at present, no equipment capable of detecting the lighting effect of the garden lamp and feeding back the adjustment of the lighting to the garden lamp is provided.

Disclosure of Invention

The invention aims to provide a yard lamp illumination detection feedback marking device and method, which are used for detecting the illumination effect of a yard lamp and feeding back the adjustment of illumination to the yard lamp.

Therefore, the invention provides a courtyard lamp illumination detection feedback marking device, which comprises: the inner surface of the detection ball is provided with a light absorption layer, and the center of the ball is fixed with a detected garden lamp through a lamp fixing component; the sensing simulation components are uniformly arranged on the outer surface of the detection ball, extend into the detection ball and are suitable for simulating light rays irradiated on the sensing simulation components by the garden lamp to be detected; the adjusting component is arranged on the simulated irradiation plane below the detection ball, is positioned on the connecting line of the center of the ball and each perception simulation component, comprises a range adjusting button and a brightness adjusting button and is respectively suitable for sending a range adjusting signal and a brightness adjusting signal when being pressed; the marking rod assembly is arranged on the outer surface of the detection ball, passes through the center of each sensing simulation assembly and is suitable for extending to the center of the detection ball; and the control module is suitable for controlling the corresponding marking rod assembly to extend out according to the received range adjusting signal until the marking rod assembly abuts against the corresponding position of the outer surface of the garden lamp to be detected so as to leave a range adjusting mark, and controlling the corresponding marking rod assembly to extend out according to the received brightness adjusting signal until the marking rod assembly abuts against the corresponding position of the outer surface of the garden lamp to be detected so as to leave a brightness adjusting mark.

On the other hand, the invention also provides a yard lamp illumination detection feedback marking method, which comprises the following steps: the courtyard lamp illuminance detection feedback marking device is used for detecting the illuminance of the courtyard lamp; step S1, fixing the garden lamp to be detected at the center of the detection ball through the lamp fixing component; step S2, simulating the light of the detected garden lamp irradiating on the sensing simulation component through the sensing simulation component; step S3, respectively sending out a range adjusting signal and a brightness adjusting signal through a range adjusting button and a brightness adjusting button of the adjusting component; and step S4, controlling the corresponding marking rod assembly to extend out through the control module according to the received range adjusting signal until the corresponding marking rod assembly abuts against the corresponding position of the outer surface of the garden lamp to be detected so as to leave a range adjusting mark, and controlling the corresponding marking rod assembly to extend out according to the received brightness adjusting signal until the corresponding marking rod assembly abuts against the corresponding position of the outer surface of the garden lamp to be detected so as to leave a brightness adjusting mark.

The invention has the advantages that the garden lamp to be detected is fixed at the sphere center of the detection ball through the lamp fixing component, the illumination effect of the garden lamp to be detected is simulated through the sensing simulation component arranged on the detection ball, the simulation illumination plane is illuminated, a tester can directly observe the illuminated area of the simulation illumination plane and the illumination condition of each position in the illuminated area, when the illumination range needs to be enlarged or reduced, the range adjusting button on the adjusting component in the corresponding area is pressed, the range adjusting mark can be left on the outer surface of the garden lamp to be detected corresponding to the area through the marking rod component on the detection ball, when the illumination is required to be adjusted, the brightness adjusting mark can be left on the outer surface of the garden lamp to be detected corresponding to the area through the marking rod component on the detection ball, after the garden lamp to be detected is taken down, the user can intuitively know how to adjust the appearance of the garden lamp to be detected.

Drawings

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

FIG. 1 is a schematic diagram of a courtyard lighting illumination detection feedback marker of the present invention;

FIG. 2 is a schematic view of a detection ball of the yard lamp illumination detection feedback marker of the present invention;

FIG. 3 is a schematic structural view of a hemispherical shell of the courtyard lighting illuminance detection feedback marking device of the present invention;

FIG. 4 is a schematic view of a fixture mounting assembly of the yard lamp illuminance detection feedback marker apparatus of the present invention;

FIG. 5 is a schematic view of the placement of the sensory simulation module of the yard lamp illuminance detection feedback marker of the present invention;

FIG. 6 is a first schematic view of a marker post assembly of the yard lamp illuminance detection feedback marker of the present invention;

FIG. 7 is a second schematic structural view of a marker rod assembly of the yard lamp illuminance detection feedback marker of the present invention;

FIG. 8 is a cross-sectional view of a marker post of the yard lamp illuminance detection feedback marker of the present invention;

FIG. 9 is a schematic diagram of a regulating assembly of the yard lamp illuminance detection feedback marker of the present invention;

FIG. 10 is a control block diagram of a yard lamp illumination detection feedback marking arrangement of the present invention;

in the figure:

the detection ball 100, the folding clamping jaw 110, the hemispherical shell 120 and the mounting hole 130;

a light absorbing layer 200, a sensing well 210;

a lamp fixing component 300, a fixing top surface 310, an expansion link 320 and a suction nozzle 330;

the sensing simulation assembly 400, the illuminance sensing ring 410, the light-transmitting hollow ring 411, the sensing light intensity sensor 412, the light simulator 420, the annular lamp holder 421 and the lamp shade 422;

the adjusting component 500, the adjusting base pillar 510, the light receiving surface 520, the received light intensity adjusting knob 530, the range adjusting button 540, and the brightness adjusting button 550;

simulating an illumination plane 600;

the marking rod assembly 700, the connecting cylinder 710, the limiting cylinder 720, the driving notch 721, the driving cylinder 730, the driving teeth 731 and the micro motor 740;

the device comprises a marking rod 800, a hollow rod body 810, a pressure-sensitive chute 811, a range imprinting semi-cylinder 820, a brightness imprinting semi-cylinder 830, a pressure sensor 840, a range imprinting groove 821, a range imprinting air bag 822, a range imprinting core 823, a brightness imprinting groove 831, a brightness imprinting air bag 832, a brightness imprinting core 833, a range imprinting electromagnetic valve 824 and a brightness imprinting electromagnetic valve 834;

the garden light 910 is inspected.

Detailed Description

To make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings, and it is apparent that the described embodiments are some, but not all embodiments of the present invention. All other embodiments based on the embodiments of the present invention, which can be realized by a person skilled in the art without any inventive step, are within the scope of the present invention.

Examples

As shown in fig. 1, the invention provides a courtyard lamp illumination detection feedback marking device, comprising: the detection ball 100, refer to fig. 3, has a light absorbing layer 200 on its inner surface, refer to fig. 2, and has a garden lamp 910 fixed at the center of the ball by a lamp fixing component 300; as shown in fig. 1, the sensing and simulating assembly 400 is uniformly arranged on the outer surface of the detection ball 100 and extends into the detection ball 100, and is suitable for simulating the light of the garden lamp 910 to be detected irradiating on the sensing and simulating assembly 400; the adjusting assembly 500 is arranged on the simulated irradiation plane 600 below the detection ball 100, is positioned on the connection line of the center of the ball and each sensing simulation assembly 400, and comprises a range adjusting button 540 and a brightness adjusting button 550 which are respectively suitable for sending a range adjusting signal and a brightness adjusting signal when being pressed; referring to fig. 2, a marker post assembly 700 disposed on an outer surface of the inspection ball 100 and passing through a center of each sensing analog assembly 400, adapted to extend toward a center of the inspection ball 100; as shown in fig. 10, the control module is adapted to control the corresponding marker post assembly 700 to extend out until it abuts against a corresponding position on the outer surface of the garden lamp 910 to be inspected, according to the received range adjustment signal, so as to leave a range adjustment mark, and to control the corresponding marker post assembly 700 to extend out until it abuts against a corresponding position on the outer surface of the garden lamp 910 to be inspected, according to the received brightness adjustment signal, so as to leave a brightness adjustment mark. In this embodiment, the control module may adopt a PLC module.

The invention fixes the garden lamp 910 to be detected at the center of the detection ball 100 through the lamp fixing component 300, simulates the illumination effect of the garden lamp 910 to be detected through the sensing simulation component 400 arranged on the detection ball 100, illuminates the simulation illumination plane 600, so that a tester can directly observe the illuminated area of the simulation illumination plane 600 and the illumination condition of each position in the illuminated area, when the illumination area needs to be enlarged or reduced, the range adjusting button 540 on the adjusting component 500 in the corresponding area is pressed, namely, a range adjusting mark is left on the outer surface of the garden lamp 910 to be detected corresponding to the area through the mark rod component 700 on the detection ball 100, when the illumination needs to be adjusted, the brightness adjusting button 550 on the adjusting component 500 in the corresponding area is pressed, namely, a brightness adjusting mark is left on the outer surface of the garden lamp 910 corresponding to the area through the mark rod component 700 on the detection ball 100, after the garden lamp 910 to be inspected is taken down, the appearance of the garden lamp 910 to be inspected can be intuitively adjusted.

As shown in fig. 4, the lamp fixing assembly 300 may include: the fixed top surface 310 and the telescopic rods 320 are arranged on the fixed top surface 310, and the extending ends of the telescopic rods are provided with a plurality of suction nozzles 330 so as to adsorb and fix the garden lamp 910 to be detected; the detection ball 100 includes a folding clamping jaw 110, which is disposed on the fixed top surface 310, and is combined with fig. 2, and is respectively and fixedly connected with a hemispherical shell 120, and is adapted to lift the detected garden lamp 910 to the center of the ball and then fold the telescopic rod 320, so that the two hemispherical shells 120 are covered to form the detection ball 100.

In order to acquire the lighting effect of the garden lamp 910 to be inspected, adjust the lighting effect, and mark the adjusted result on the garden lamp 910 to be inspected, the sensing simulation assembly 400, the adjustment assembly 500, and the marking rod assembly 700 are provided on the detection ball 100. In this embodiment, referring to fig. 3, the hemispherical shell 120 is uniformly provided with mounting holes 130, it should be noted that, for convenience of reading, fig. 3 only shows 6 uniformly provided mounting holes 130, and the rest of the mounting holes 130 are also uniformly provided on the hemispherical shell 120 as in fig. 3; the inner surfaces of the hemispherical shells 120 are all provided with light absorbing layers 200, and sensing holes 210 corresponding to the mounting holes 130 are formed in the light absorbing layers 200; in this embodiment, the light absorbing layer 200 may be made of light absorbing cotton to prevent the light emitted from the garden lamp 910 to be inspected from being reflected inside the detection ball 100 and illuminating the entire inner surface of the detection ball 100. As shown in fig. 2, the sensing simulation component 400 may include: the illuminance sensing ring 410 is inserted into the mounting hole 130 and extends into the hemispherical shell 120 through the sensing hole 210 to obtain a garden lamp light intensity signal at a corresponding position of the illuminated area of the light absorbing layer 200; a light simulator 420 fixed on the outer surface of the hemispherical shell 120 and located on the connection line between the center of sphere and each illuminance sensing ring 410; referring to fig. 10, the control module is adapted to control the corresponding light simulator 420 to emit light rays with corresponding illuminance according to the received courtyard light intensity signal, for example, as shown in fig. 2, a bottom illuminance sensing ring 410 detects a courtyard light intensity signal of the light rays irradiated by the detected courtyard light 910, and transmits the signal to the control module, and the control module controls the light simulator 420 located on a connection line between the center of the sphere and the illuminance sensing ring 410, that is, the bottom light simulator 420 in fig. 2 emits light with the same intensity.

As shown in fig. 6, the illuminance sensing ring 410 may include: a light-transmitting hollow ring 411 screw-fitted with the mounting hole 130; a sensor 412 for sensing light intensity, arranged inside said light-transmissive hollow ring 411, adapted to detect and transmit said courtyard light intensity signal; as shown in fig. 5, it should be noted that, for convenience of reading, only 14 light simulators 420 are shown in fig. 5, 1, 2 and 9, and the rest of the light simulators 420 are also uniformly arranged on the outer surface of the detection ball 100 as shown in fig. 5; the light simulator 420 may include: an annular lamp head 421 disposed on the periphery of the hemispherical shell 120 and located on a connection line between the center of sphere and each light-transmitting hollow ring 411; the lampshades 422 are fixed on the outer surface of the hemispherical shell 120, the lampshades 422 are mutually abutted so as to equally divide the shell surface space of the hemispherical shell 120, and the annular lampheads 421 are accommodated in the lampshade core so as to simulate the light path of the garden lamp 910 to be detected; the control module is adapted to control the corresponding annular lamp head 421 to emit light rays with corresponding illuminance according to the received garden lamp light intensity signal, so as to completely simulate the illumination effect of the detected garden lamp 910.

In this embodiment, the inner wall of the light-transmissive hollow ring 411 is threaded; as shown in fig. 6 and 7, the marking rod assembly 700 may include: a connector 710 which mates with the threads of the inner wall of the light-transmissive hollow ring 411; the limiting cylinder 720 is fixedly connected to one end of the connecting cylinder 710, which is positioned outside the hemispherical shell 120, and the cylinder body is provided with a driving gap 721; the driving cylinder 730 is arranged in the limiting cylinder 720, and the outer cylinder wall of the driving cylinder 730 is provided with driving teeth 731; preferably, the driving cylinder 730 can be arranged in the limiting cylinder 720 through a bearing seat; a marking rod 800 screw-engaged with an inner wall of the driving cylinder 730; a micro motor 740 fixedly connected to the connecting cylinder 710 and in transmission connection with the driving teeth 731 through the driving gap 721; since the driving cylinder 730 can only rotate around the axis in the limiting cylinder 720 and cannot advance or retreat, when the micro motor 740 drives the driving cylinder 730 to rotate, the marking rod 800 in threaded fit with the driving cylinder 730 correspondingly extends into the detection ball 100 or withdraws from the detection ball 100; the control module is adapted to control the corresponding micro motor 740 to start up after receiving the range adjustment signal or the brightness adjustment signal, so as to drive the driving cylinder 730 to rotate in the limiting cylinder 720, so that the marking rod 800 extends to the detected garden lamp 910 at the center of the sphere.

As shown in fig. 8, the marker shaft 800 may include: the hollow rod body 810 is provided with an outer rod wall which is in threaded fit with the inner cylinder wall of the driving cylinder 730, and a pressure-sensitive sliding groove 811 is arranged on the inner wall of the end part extending into the hemispherical shell 120 so as to print a semi-cylinder 820 and a brightness print semi-cylinder 830 in a sliding connection range; a pressure sensor 840 fixed within said hollow shaft 810 and partially ejecting the range print semi-cylinder 820 and the intensity print semi-cylinder 830 out of the hollow shaft 810, adapted to signal garden light contact when pressed; the outward surface of the range mark semi-cylinder 820 is provided with a range mark groove 821, the bottom of the range mark groove 821 is provided with a range mark air bag 822 which is suitable for ejecting a range mark core head 823 which is connected to the wall of the groove in a sliding way out of the range mark groove 821 after being inflated so as to coat a range adjustment mark when contacting the detected garden lamp 910; the brightness imprint semi-cylinder 830 is provided with a brightness imprint groove 831 on the outward surface, and a brightness imprint air bag 832 is arranged at the bottom of the brightness imprint groove 831 and is suitable for ejecting a brightness imprint core 833 which is connected to the groove wall in a sliding manner out of the brightness imprint groove 831 after being inflated so as to coat brightness adjustment imprints when contacting the detected garden lamp 910; referring to fig. 9, the range-print bladder 822 may be in gas communication with a gas source via a range-print solenoid valve 824; the brightness print air bag 832 can be communicated with an air source through a brightness print electromagnetic valve 834 and an air pipe; also shown in FIG. 9 are only partial range imprint solenoid valve 824 and partial brightness imprint solenoid valve 834; the control module is suitable for controlling the range marking electromagnetic valve 824 of the corresponding marking rod 800 to be opened according to the received range adjusting signal, the corresponding range marking air bag 822 swells, the range marking core head 823 is pushed out of the range marking groove 821, the range marking core head 823 moves towards the garden lamp 910 to be detected along with the hollow rod body 810, referring to fig. 2, after the hollow rod body 810 extends for a certain distance, the range marking core head 823 abuts against the outer surface of the garden lamp 910 to be detected, if the hollow rod body 810 continues to extend, the range marking core head 823 abuts against the outer surface of the fixed garden lamp 910 to be detected, the range adjusting mark is left and is simultaneously subjected to a reaction force, the reaction force is transmitted to the range marking semi-cylinder 820 through the range marking air bag 822, the range marking semi-cylinder 820 has a downward sliding trend in the pressure sensing sliding groove 811, the pressure sensor 840 detects the reaction force, and generates a garden lamp contact signal, when the control module receives that the contact signal of the garden lamp exceeds a preset threshold value, the control module controls the corresponding micro motor 740 to stop; the process of leaving the brightness adjustment mark is also the same as the process of leaving the range adjustment mark, that is, the control module controls the brightness mark solenoid valve 834 of the corresponding marking rod 800 to open according to the received brightness adjustment signal, and controls the corresponding micro motor 740 to stop when the received garden lamp contact signal exceeds the preset threshold value.

As shown in fig. 9, the adjusting assembly 500 may include: an adjustment base 510 disposed on the simulated illumination plane 600; a light-facing surface 520, which is disposed on the adjusting base column 510 and faces the detection ball 100, and the center of each light-facing surface 520 is located on the connection line between the center of the ball and each light-transmitting hollow ring 411; a received light intensity adjusting knob 530, which is arranged on the light facing surface 520 and is adapted to send out an adjusting signal when rotating, and the control module is adapted to adjust the illuminance of the corresponding annular lamp head 421 again according to the received adjusting signal and record the adjusted illuminance of the annular lamp head 421; a range adjustment button 540, provided on the light-facing surface 520, adapted to issue the range adjustment signal when pressed; a brightness adjustment button 550, disposed on the light facing surface 520, adapted to emit the brightness adjustment signal when pressed. The tester can directly observe the illuminated area of the simulated illumination plane 600 and the illumination conditions of various places in the illuminated area, when the illumination range needs to be enlarged or reduced, the range adjustment button 540 on the adjustment assembly 500 in the corresponding area is pressed, taking fig. 2 as an example, the bottommost marking rod 800 corresponds to the adjustment assembly 500 positioned in the center of the simulated illumination plane 600 in fig. 9, the oblique marking rod 800 corresponds to the adjustment assembly 500 positioned at the edge of the simulated illumination plane 600 in fig. 9, it should be noted that, for reading, only the two aforementioned adjustment assemblies 500 are shown in fig. 9, the rest of the adjustment assemblies 500 also correspond to a sensing simulation assembly 400 and a marking rod assembly 700, for example, the adjustment assembly 500 at the edge of the simulated illumination plane 600 is not in the existing illumination range, but it is considered that the illumination is needed after observation, the range adjustment button 540 on the adjustment assembly 500 is pressed, the control module controls the corresponding marker rod 800 to extend to the tested garden lamp 910 as shown in fig. 2, and leaves a range adjustment mark thereon as described above, if it is necessary to know the illumination intensity at the position is appropriate, the received light intensity adjusting knob 530 is rotated, the control module can control the corresponding light simulator 420 which does not emit light originally to emit light with corresponding intensity, and record the adjusted illumination intensity, and after the illumination intensity is adjusted, the tester can press the brightness adjusting button 550 to leave a brightness adjustment mark on the tested garden lamp 910; in this embodiment, each of the range print core 823 and the brightness print core 833 may be marked with a mark such as a number, so as to facilitate the examination of the recorded illumination corresponding to the brightness adjustment print after the garden lamp 910 to be examined is removed.

In this embodiment, a yard lamp illuminance detection feedback marking method is further provided, including: the courtyard lamp illuminance detection feedback marking device is used for detecting the illuminance of the courtyard lamp; step S1, fixing the garden lamp 910 to be detected at the center of the detection ball 100 through the lamp fixing component 300; step S2, simulating the light ray irradiated on the sensing simulation assembly 400 by the tested garden lamp 910 through the sensing simulation assembly 400; step S3, sending a range adjusting signal and a brightness adjusting signal through the range adjusting button 540 and the brightness adjusting button 550 of the adjusting assembly 500, respectively; and step S4, controlling the corresponding marking rod assembly 700 to extend out through the control module according to the received range adjusting signal until the corresponding position of the outer surface of the garden lamp 910 to be detected is abutted so as to leave a range adjusting mark, and controlling the corresponding marking rod assembly 700 to extend out according to the received brightness adjusting signal until the corresponding position of the outer surface of the garden lamp 910 to be detected is abutted so as to leave a brightness adjusting mark. The specific process of detecting the feedback mark has been described in detail above, and is not described in detail.

In summary, the invention fixes the garden lamp to be detected at the center of the detection ball through the lamp fixing component, simulates the illumination effect of the garden lamp to be detected through the sensing simulation component arranged on the detection ball, illuminates the simulation irradiation plane, so that the tester can directly observe the illuminated area of the simulation irradiation plane and the illumination condition of each place in the illuminated area, when the illumination range needs to be enlarged or reduced, the range adjusting button on the adjusting component in the corresponding area is pressed, namely, the range adjusting mark is left on the outer surface of the garden lamp to be detected corresponding to the area through the marking rod component on the detection ball, when the illumination is needed to be adjusted, the brightness adjusting button on the adjusting component in the corresponding area is pressed, namely, the brightness adjusting mark is left on the outer surface of the garden lamp to be detected corresponding to the area through the marking rod component on the detection ball, and the garden lamp to be detected is taken down, the method can intuitively know how to adjust the appearance of the garden lamp to be detected.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

In light of the foregoing description of the preferred embodiments of the present invention, it is to be understood that various changes and modifications may be made by one skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims (8)

1. A courtyard lamp illuminance detection feedback marking device, comprising:

the inner surface of the detection ball (100) is provided with a light absorption layer (200), and the spherical center is fixed with a detected garden lamp (910) through a lamp fixing component (300);

the sensing simulation assembly (400) is uniformly arranged on the outer surface of the detection ball (100), extends into the detection ball (100), and is suitable for simulating the light rays irradiated on the sensing simulation assembly (400) by the garden lamp (910) to be detected;

the adjusting assembly (500) is arranged on the simulation irradiation plane (600) below the detection ball (100), is positioned on a connecting line of the center of the ball and each perception simulation assembly (400), and comprises a range adjusting button (540) and a brightness adjusting button (550) which are respectively suitable for sending out a range adjusting signal and a brightness adjusting signal when being pressed;

a marking rod assembly (700) which is arranged on the outer surface of the detection ball (100), passes through the center of each perception simulation assembly (400) and is suitable for extending to the center of the detection ball (100);

and the control module is suitable for controlling the corresponding marking rod assembly (700) to extend until the corresponding position is pressed against the outer surface of the garden lamp (910) to be detected according to the received range adjusting signal so as to leave a range adjusting mark, and controlling the corresponding marking rod assembly (700) to extend until the corresponding position is pressed against the outer surface of the garden lamp (910) to be detected so as to leave a brightness adjusting mark according to the received brightness adjusting signal.

2. The yard lamp illuminance detection feedback marking device as claimed in claim 1,

the luminaire securing assembly (300) comprises:

a fixed top surface (310),

the telescopic rod (320) is arranged on the fixed top surface (310), and the extending end of the telescopic rod is provided with a plurality of suction nozzles (330) for sucking and fixing the garden lamp (910) to be detected;

the detection ball (100) comprises

And the folding clamping jaws (110) are arranged on the fixed top surface (310), are respectively fixedly connected with a hemispherical shell (120), and are suitable for lifting the garden lamp (910) to be detected to the center of a sphere and then folding the garden lamp, so that the two hemispherical shells (120) are covered to form the detection ball (100).

3. The yard light illuminance detection feedback marker as claimed in claim 2,

mounting holes (130) are uniformly formed in the hemispherical shell (120);

the inner surfaces of the hemispherical shells (120) are provided with light absorbing layers (200), and sensing holes (210) corresponding to the mounting holes (130) are formed in the light absorbing layers (200);

the perception simulation component (400) comprises:

the illuminance sensing ring (410) is inserted into the mounting hole (130) and extends into the hemispherical shell (120) through the sensing hole (210) so as to acquire a courtyard light intensity signal at a corresponding position of an illuminated area of the light absorption layer (200);

the light simulator (420) is fixed on the outer surface of the hemispherical shell (120) and is positioned on a connecting line of the spherical center and each illuminance sensing ring (410);

the control module is suitable for controlling the corresponding light simulator (420) to emit light rays with corresponding illumination intensity according to the received courtyard light intensity signal.

4. The yard light illuminance detection feedback marker as claimed in claim 3,

the illuminance sensing loop (410) comprises:

a light-transmissive hollow ring (411) that is screw-fitted with the mounting hole (130);

a sensor (412) of perceived light intensity, arranged inside said light-transmissive hollow ring (411), adapted to detect and send said courtyard light intensity signal;

the light simulator (420) comprises:

the annular lamp holder (421) is arranged on the periphery of the hemispherical shell (120) and is positioned on a connecting line between the spherical center and each light-transmitting hollow ring (411);

the lampshades (422) are fixed on the outer surface of the hemispherical shell (120), the lampshades (422) are mutually abutted so as to equally divide the shell surface space of the hemispherical shell (120), and the annular lampholders (421) are accommodated in the lampshade core so as to simulate the light path of the garden lamp (910) to be detected;

the control module is suitable for controlling the corresponding annular lamp holder (421) to emit light rays with corresponding illumination intensity according to the received courtyard light intensity signal.

5. The yard lamp illuminance detection feedback marking device as claimed in claim 4,

the inner wall of the light-transmitting hollow ring (411) is provided with threads;

the marker post assembly (700) comprises:

a connector barrel (710) in threaded engagement with an inner wall of the light-transmissive hollow ring (411);

the limiting cylinder (720) is fixedly connected to one end, positioned outside the hemispherical shell (120), of the connecting cylinder (710), and a driving gap (721) is formed in the cylinder body;

the driving barrel (730) is arranged in the limiting barrel (720), and the outer barrel wall of the driving barrel (730) is provided with driving teeth (731);

a marker stem (800) in threaded engagement with the inner cylindrical wall of the drive cartridge (730);

the micro motor (740) is fixedly connected to the connecting cylinder (710) and is in transmission connection with the driving teeth (731) through the driving notches (721);

the control module is suitable for controlling the corresponding micro motor (740) to start after receiving the range adjusting signal or the brightness adjusting signal, and driving the driving cylinder (730) to rotate in the limiting cylinder (720), so that the marking rod (800) extends to the detected garden lamp (910) at the center of a sphere.

6. The yard lamp illuminance detection feedback marking device as claimed in claim 5,

the marker post (800) comprises:

the hollow rod body (810) is provided with a pressure-sensitive sliding groove (811) on the inner wall of the end part extending into the hemispherical shell (120) so as to print a semi-cylinder (820) and a brightness print semi-cylinder (830) in a sliding connection range;

a pressure sensor (840) secured within said hollow shaft (810) and partially ejecting the range print semi-cylinder (820) and the intensity print semi-cylinder (830) out of the hollow shaft (810) adapted to signal garden light contact when pressurized;

the range mark semi-cylinder (820) is provided with a range mark groove (821) on the outward surface, the bottom of the range mark groove (821) is provided with a range mark air bag (822) which is suitable for ejecting a range mark core head (823) which is connected to the wall of the groove in a sliding mode out of the range mark groove (821) after inflation, and therefore a range adjustment mark is coated when the range mark semi-cylinder (820) contacts the detected garden lamp (910);

the brightness imprint semi-cylinder (830) is provided with a brightness imprint groove (831) on the outward surface, the bottom of the brightness imprint groove (831) is provided with a brightness imprint air bag (832) which is suitable for ejecting a brightness imprint core head (833) which is connected to the groove wall in a sliding way out of the brightness imprint groove (831) after being inflated so as to paint brightness adjustment imprints when contacting the detected garden lamp (910);

the range mark air bag (822) is communicated with an air source through a range mark electromagnetic valve (824) and an air pipe;

the brightness imprint air bag (832) is communicated with an air source through a brightness imprint electromagnetic valve (834) and an air pipe;

the control module is adapted to control the range print solenoid valve (824) of the respective marker post (800) to open and control the respective micro-motor (740) to stop upon receiving the yard light contact signal exceeding a preset threshold, based on the received range adjustment signal, and to control the brightness print solenoid valve (834) of the respective marker post (800) to open and control the respective micro-motor (740) to stop upon receiving the yard light contact signal exceeding a preset threshold, based on the received brightness adjustment signal.

7. The yard lamp illuminance detection feedback marking device as claimed in claim 6,

the adjustment assembly (500) comprises:

an adjustment base (510) disposed on the simulated illumination plane (600);

the light-facing surfaces (520) are arranged on the adjusting base columns (510) and face the detection ball (100), and the centers of the light-facing surfaces (520) are positioned on a connecting line of the spherical center and the light-transmitting hollow rings (411);

the received light intensity adjusting knob (530) is arranged on the light facing surface (520) and is suitable for sending out an adjusting signal when the light facing surface is rotated, and the control module is suitable for adjusting the illumination intensity of the corresponding annular lamp head (421) again according to the received adjusting signal and recording the illumination intensity after the annular lamp head (421) is adjusted;

a range adjustment button (540) disposed on the light-facing surface (520) adapted to issue the range adjustment signal when pressed;

a brightness adjustment button (550) disposed on the light facing surface (520) and adapted to emit the brightness adjustment signal when pressed.

8. A courtyard lamp illumination detection feedback marking method is characterized by comprising the following steps:

the yard light illuminance detection feedback marker as claimed in any one of claims 1 to 7;

step S1, fixing the garden lamp (910) to be detected at the center of the detection ball (100) through the lamp fixing component (300);

step S2, simulating the light ray irradiated on the sensing simulation component (400) by the tested garden lamp (910) through the sensing simulation component (400);

step S3, respectively sending out a range adjusting signal and a brightness adjusting signal through a range adjusting button (540) and a brightness adjusting button (550) of the adjusting component (500);

and step S4, controlling the corresponding marking rod assembly (700) to extend out until the corresponding marking rod assembly abuts against the corresponding position of the outer surface of the garden lamp (910) to be detected through the control module according to the received range adjusting signal so as to leave a range adjusting mark, and controlling the corresponding marking rod assembly (700) to extend out until the corresponding marking rod assembly abuts against the corresponding position of the outer surface of the garden lamp (910) to be detected so as to leave a brightness adjusting mark according to the received brightness adjusting signal.

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