CN210042333U - Lighting system for carrying out induction control on moving object - Google Patents

Abstract

The application relates to the field of lighting systems, provides a carry out moving object response control's lighting system, including banks, air switch and be connected and be used for controlling the on-off controller that the banks was thrown light on with air switch, air switch and power bus are connected, on-off controller is connected with the removal response module, through being equipped with at least one reflection type photoelectric sensor perception object in rated distance in the removal response module makes the switching of on-off controller control banks through carrying out signal feedback. The lighting system of the utility model is simple and reliable, and can effectively detect the moving object passing through the channel in the corresponding space through the specially designed mobile induction module, thereby feeding back the signal to the switch controller to control the lamp bank in the corresponding area to be switched on and off; the system can be flexibly set, and different numbers of mobile induction modules are arranged according to actual space requirements, so that a better control effect is achieved.

Description

Lighting system for carrying out induction control on moving object

Technical Field

The application relates to the field of lighting equipment, in particular to an intelligent lighting system, which relates to a lighting system for performing induction control on a moving object.

Background

The intelligent lighting system is a general name of a series of equipment for lighting control by adopting the intelligent lighting control system, and is a lighting control system which utilizes advanced electromagnetic voltage regulation and electronic induction technology, takes public lighting unified grid intelligence as a platform, monitors and tracks power supply in real time, automatically and smoothly regulates the voltage and current amplitude of a circuit, improves extra power consumption caused by unbalanced load in a lighting circuit, improves power factors, reduces the working temperature of lamps and lines and achieves the purpose of optimizing power supply.

The switch controller is a programmable controller with MCU, the controller is installed by standard guide rail, and the connection wire is plug-in type connection terminal, so that it is easy to install and maintain. The debugging is very simple and convenient by combining the local control button and the loop state indicator lamp. The controller reserves an emergency signal (e.g. fire) interface which ensures that the particular lighting device is secured in case of an emergency.

In the existing use scene, a plurality of sensors are arranged in the corresponding space of more intelligent lighting systems, so that the effect of automatically sensing and controlling lighting is achieved. However, in the existing intelligent lighting system, for some subdivided scenes, such as the functional requirements of sensing the moving object and controlling lighting, the moving object detection sensor with higher cost is mostly adopted, so that not only the stability is not high, but also the maintenance cost is higher.

SUMMERY OF THE UTILITY MODEL

The application provides a simple and reliable moving object response lighting system to solve the complicated higher problem of maintenance cost of intelligent lighting system structure among the prior art.

The embodiment of the application is realized as follows:

the embodiment of the application provides a lighting system for induction control of a moving object, which comprises a lamp set, an air switch and a switch controller, wherein the switch controller is connected with the air switch and is used for controlling the lighting of the lamp set, the air switch is connected with a power bus,

the switch controller is connected with a movable induction module, and at least one reflective photoelectric sensor is arranged in the movable induction module, senses an object in a rated distance and feeds back a signal to enable the switch controller to control the on-off of the lamp bank.

The utility model provides a be equipped with special signal interface on the switch controller for connect removal response module, the object through the reflection type photoelectric sensor detectable specific position that is equipped with passes through the signal. The reflective photoelectric sensor is a photoelectric sensor which is characterized in that a transmitter and a receiver are arranged in the same device, a reflector is arranged in front of the transmitter and the receiver, and the photoelectric control function is completed by utilizing the reflection principle. That is, the device is provided with a light source and a light receiving device, light emitted by the light source is reflected by the object to be measured and received by the photosensitive element, and the light is processed by the relevant circuit to obtain the required information. The device can be used for detecting the change of ground light and shade and color and detecting whether an approaching object exists or not.

Generally, one or more motion sensing modules are disposed in a single space, and are disposed at specific positions on a wall, so as to effectively sense the motion of a specific object, thereby generating a feedback signal. The movable induction module is generally arranged at the door entrance position or on a necessary passage, the movable induction module is arranged on a wall body at one side, a corresponding reflector is arranged on the wall body at the other side, and the reflector is parallel to the emitting end face of a corresponding reflection type photoelectric sensor in the movable induction module, so that a better reflection effect is ensured. When no moving object passes through the detection position in the whole room, the optical signals received by all the reflective photoelectric sensors are kept constant (it is worth to say that the constant is relatively large signal change generated when the moving object is directly blocked or reflected at other angles, the change is small, and corresponding environmental interference can be eliminated through a set filtering algorithm so as to keep a stable state; so-called environmental interference, for example, influence generated when a part of optical paths are blocked due to floating dust in the air on the optical paths between the reflective photoelectric sensors and the reflecting plate, and the existing reflective photoelectric sensors can automatically filter).

Once people or a large moving object moves and blocks the light path, so that the variation of the received reflected light signal is large, a feedback signal is generated and sent to the switch controller to control the preset lamp group to be started. In actual use, a person skilled in the art can perform different control modes by presetting a program of the switch controller. For example, feedback signals generated by the movement sensing modules at different positions can be used for controlling illuminating lamps at corresponding positions.

Furthermore, the mobile sensing module comprises a split type shell, and a transparent cover plate for allowing light of the reflective photoelectric sensor to penetrate is arranged on the shell; the reflection type photoelectric sensor is arranged in the shell and is rotationally connected with the shell.

The connection mode of the whole mobile induction module and the reflection type photoelectric sensor is optimized and limited, and the angle of the reflection type photoelectric sensor can be adjusted through the rotary connection. When installing the movable sensing module, need fix the shell earlier, then install the reflector panel that corresponds again, but when installing the reflector panel, need adjust the reflector panel to suitable position and fix to guarantee that reflection formula photoelectric sensor can receive effectual reflected light signal as initial set value. However, in actual installation, the wall surface of the installation position may be uneven, and a certain angle deviation may be generated in fixing, and if the angle of the wall surface cannot be adjusted, the adaptability of the wall surface is poor, the planar structure where the installation is located needs to be processed, and the installation efficiency is reduced.

Furthermore, the shell is of a pre-buried structure and comprises a top cover and a base buried in a preset groove of a wall body, the outer side of the top cover protrudes outwards to form a sensor mounting seat, at least one mounting groove is formed in the sensor mounting seat, the reflective photoelectric sensor is arranged in the mounting groove, and the transparent cover plate is arranged at an opening of the mounting groove.

The sensor mounting base is outwards protruding and can have a large angle adjustment range, and meanwhile the occupied space inside the whole shell is reduced, so that a cable is arranged to transmit signals and supply power. The mounting groove is a groove structure formed by cutting on the raised sensor mounting seat, is similar to a hinged ear seat structure, can facilitate the rotary connection of the reflection type photoelectric sensor, and because the common angle adjustment is realized by arranging a corresponding connecting mechanism to penetrate through the shell and be coaxial with the rotary shaft of the reflection type photoelectric sensor, the raised structure facilitates the angle adjustment of the reflection type photoelectric sensor by using a tool.

Furthermore, two installation grooves are formed in the sensor installation seat, rotating shafts of the reflection type photoelectric sensors installed in the two installation grooves are located on the same straight line, and the light deviation angle of the two reflection type photoelectric sensors is 90-120 degrees. Compared with the arrangement of a plurality of mobile induction modules, the wiring harness material adopted by the reflective photoelectric sensor is reduced, and the installation and maintenance cost is reduced. The mobile induction module can be arranged at a 90-degree bend of a single channel, and just provides signal feedback for lamp groups at two ends of the bend.

Further, the base passes through the bolt fastening and predetermines the inslot at the wall body, top cap and base joint.

Furthermore, at least three arc-shaped slide rails are arranged on the inner wall of the base at equal central angles on the same horizontal plane, one ends of the arc-shaped slide rails extend outwards along the direction vertical to the wall surface to form vertical extending parts, and the outer wall of the top cover is provided with a convex block matched with the arc-shaped slide rails for limiting; when the top cap is buckled inwards to the base, the convex block enters from the opening of the vertical extension part of the arc-shaped slide rail and rotates the top cap to realize clamping fixation after falling into the arc-shaped slide rail.

Furthermore, the system also comprises a remote controller connected with the switch controller, the remote controller is connected with a wireless receiving and transmitting module A, the one or more mobile induction modules are connected with a wireless receiving and transmitting module B arranged in the remote controller, and the wireless receiving and transmitting module B is in wireless communication connection with the wireless receiving and transmitting module A to perform signal feedback.

Furthermore, the system also comprises a dimming controller, the power supply port of the dimming controller and the switch controller is connected with the air switch, and the signal control port of the dimming controller is connected with a control panel arranged on the air switch.

Further, the switch controller and the motion sensing module are connected by adopting an RS232 serial bus standard.

The lighting system of the utility model is simple and reliable, and can effectively detect the moving object passing through the channel in the corresponding space through the specially designed mobile induction module, thereby feeding back the signal to the switch controller to control the lamp bank in the corresponding area to be switched on and off; the system can be flexibly set, and different numbers of mobile induction modules are arranged according to actual space requirements, so that a better control effect is achieved. And simultaneously, the utility model provides a removal response module of a plurality of integrated reflection photoelectric sensors, through a plurality of adjustable turned angle's of integration on the single-point reflection photoelectric sensor to from single fixed point to whole passageway or the radial many infrared detection pencil that distribute in space, and through same bus connection on-off controller, perhaps carry out wireless connection through same B wireless transceiver module, thereby reduce cost improves the integrated level.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained from the drawings without inventive effort.

Fig. 1 is a system framework diagram of the mobile sensing module connected to a switch controller in a wired manner according to the present application; in the figure, two wires are a neutral wire and a live wire, and D1 and D2 are both lamp sets, wherein D2 is a lamp set of a resistive load;

fig. 2 is a system framework diagram of the mobile sensing module wirelessly connected to the switch controller in the present application;

fig. 3 is a schematic view illustrating an overall assembly of the mobile induction module provided with two mounting slots according to the present application;

fig. 4 is a schematic view illustrating an overall disassembly of the mobile sensing module provided with two mounting slots according to the present application;

fig. 5 is a schematic view illustrating the whole disassembly of the mobile sensing module provided with a mounting groove.

Icon: the system comprises a 1-air switch, a 2-switch controller, a 3-mobile induction module, a 4-reflection type photoelectric sensor, a 5-shell, a 501-top cover, a 502-base, a 503-sensor installation seat, a 504-installation groove, a 505-arc sliding rail, a 506-lug, a 6-transparent cover plate, a 7-remote controller, an 8-A wireless transceiver module, a 9-B wireless transceiver module, a 10-dimming controller and a 11-control panel.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. The components of the embodiments of the present application, generally described and illustrated in the figures herein, can be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present application, presented in the accompanying drawings, is not intended to limit the scope of the claimed application, but is merely representative of selected embodiments of the application. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

In the description of the present application, it should be noted that if the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are used for indicating the orientation or positional relationship based on the orientation or positional relationship shown in the drawings or the orientation or positional relationship which is usually placed when the product of the application is used, the description is only for convenience and simplicity, and the indication or suggestion that the referred device or element must have a specific orientation, be constructed in a specific orientation and be operated, and thus, should not be construed as limiting the present application. Furthermore, the appearances of the terms "first," "second," and the like in the description herein are only used for distinguishing between similar elements and are not intended to be construed as indicating or implying relative importance.

Furthermore, the terms "horizontal", "vertical" and the like when used in the description of the present application do not require that the components be absolutely horizontal or overhanging, but may be slightly inclined. For example, "horizontal" merely means that the direction is more horizontal than "vertical" and does not mean that the structure must be perfectly horizontal, but may be slightly inclined.

In the description of the present application, it should also be noted that, unless otherwise explicitly stated or limited, the terms "disposed," "mounted," "connected," and "connected" should be interpreted broadly, e.g., as being fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present application can be understood in a specific case by those of ordinary skill in the art.

Example 1:

the embodiment is an intelligent lighting system, which is a general name of a series of devices for lighting control by adopting the intelligent lighting control system, and is a lighting control system which utilizes advanced electromagnetic voltage regulation and electronic induction technology, takes public lighting unified grid intelligence as a platform, monitors and tracks power supply in real time, automatically and smoothly adjusts the voltage and current amplitude of a circuit, improves extra power consumption caused by unbalanced load in a lighting circuit, improves power factors, reduces the working temperature of lamps and lines and achieves the purpose of optimizing power supply. As shown in fig. 1 and 5, the lighting system for performing induction control on a moving object in the present embodiment includes a lamp set, an air switch 1, and a switch controller 2 connected to the air switch 1 and used for controlling the lamp set to illuminate, where the air switch 1 is connected to a power bus, the switch controller 2 is connected to a mobile induction module 3, and at least one reflective photoelectric sensor 4 is disposed in the mobile induction module 3, and senses the object within a rated distance, and performs signal feedback so that the switch controller 2 controls the lamp set to be switched on and off.

The switch controller 2 in this embodiment is provided with a special signal interface for connecting the mobile sensing module 3, and the passing signal of the object at a specific position can be detected by the provided reflective photoelectric sensor 4. The reflective photoelectric sensor 4 is a photoelectric sensor in which a transmitter and a receiver are installed in the same device, a reflector is installed in front of the device, and the photoelectric control function is achieved by using the reflection principle. That is, the device is provided with a light source and a light receiving device, light emitted by the light source is reflected by the object to be measured and received by the photosensitive element, and the light is processed by the relevant circuit to obtain the required information. The device can be used for detecting the change of ground light and shade and color and detecting whether an approaching object exists or not.

The mobile induction module 3 is arranged on a wall body on one side, a corresponding reflector is arranged on a wall body on the other side, and the reflector is parallel to the emitting end face of the corresponding reflection type photoelectric sensor 4 in the mobile induction module 3, so that a better reflection effect is ensured.

When no moving object passes through the detection position in the whole room, the optical signals received by all the reflective photoelectric sensors 4 are kept constant (it is worth to say that the constant is relatively large signal change generated when the moving object is directly blocked or reflected at other angles, the change is small, and corresponding environmental interference can be eliminated through a set filtering algorithm so as to keep a stable state; so-called environmental interference, for example, the influence generated when a part of optical path is blocked due to floating dust in the air on the optical path between the reflective photoelectric sensors 4 and the reflecting plate, while the existing reflective photoelectric sensors 4 can automatically filter).

Once a person or a large moving object moves and blocks the light path, so that the variation of the received reflected light signal is large, a feedback signal is generated and sent to the switch controller 2 to control the preset lamp set to be turned on. In practical use, a person skilled in the art can perform different control modes by presetting the program of the switch controller 2. For example, feedback signals generated by the movement sensing modules 3 at different positions can be used to control lighting lamps at corresponding positions.

Moreover, each motion sensing module 3 will generate different feedback signals, for example, the reflected light signal has a large instantaneous change, and it can be considered that there is a moving object passing through the position of the motion sensing module 3. However, if the reflected light signal may change suddenly and remain for a certain time before being recovered, it may be determined that a moving object has moved to the area and blocked for a certain time before moving, and it may also be determined that a moving object has entered the corresponding area. In both cases, the same feedback signal can be determined, and the switch controller 2 controls the lamp sources in the corresponding region to illuminate, or certainly, the on-time of single feedback can be set, and the illumination time is reset or superimposed when the feedback signal is received again. Alternatively, the reflected light signal is continuously maintained after once changing and is not restored to the initial potential within a preset time, and it can be determined that only an object is moved to a corresponding position and continuously fixed, and then automatically turned off after reaching the preset time.

The above-mentioned several lighting modes are all the use modes of matching by using the system of the present embodiment, and the corresponding settings are all in the switch controller 2, and the switch controller 2 and the reflective photoelectric sensor 4 both adopt the existing structures, and those skilled in the art can preset the programs according to the actual requirements, so the principle and structure of the single device thereof will not be described in detail.

The mobile induction module 3 comprises a split type shell 5, and a transparent cover plate 6 for transmitting the light of the reflective photoelectric sensor 4 is arranged on the shell 5; the reflective photoelectric sensor 4 is arranged in the shell 5 and is rotatably connected with the shell 5. The housing 5 is of a pre-buried structure and comprises a top cover 501 and a base 502 buried in a preset groove of a wall body, wherein the outer side of the top cover 501 protrudes outwards to form a sensor installation seat 503, at least one installation groove 504 is arranged on the sensor installation seat 503, the reflective photoelectric sensor 4 is arranged in the installation groove 504, and the transparent cover plate 6 is arranged at an opening of the installation groove 504.

The outward protrusion of the sensor mounting seat 503 can have a larger angle adjustment range, and at the same time, the occupied space inside the whole housing 5 is reduced, so that a cable can be arranged for signal transmission and power supply. The mounting groove 504 is a groove structure cut on the convex sensor mounting seat 503, which is similar to a hinged ear seat structure and can facilitate the rotation connection of the reflective photoelectric sensor 4, and because the general angle adjustment is performed by disposing a corresponding connection mechanism to penetrate through the housing 5 and to be coaxial with the rotation axis of the reflective photoelectric sensor 4, the convex structure facilitates the angle adjustment of the reflective photoelectric sensor 4 by using a tool.

The base 502 is fixed in a wall preset groove through bolts, and the top cover 501 is clamped with the base 502. As shown in the figure, the whole housing 5 is a cylindrical structure, and an opening is formed on an arc-shaped surface on one side of the base 502, so that the cable can be conveniently laid.

As shown in fig. 4, the reflective photoelectric sensor 4 is a flat cuboid structure, the side surface where the long side is located is a light-transmitting end surface of the receiver and the emitter, and the outer convex surface of the sensor mounting seat 503 is a cambered surface structure. Two side faces of the reflective photoelectric sensor 4 are provided with cylindrical protrusions, the inner wall of the mounting groove 504 is provided with a cylindrical inner recess which is inserted and matched with the cylindrical protrusions for limiting, and one side of the inner recess penetrates through the cylindrical inner recess to form a hole. When the reflective photoelectric sensor 4 is installed in the installation groove 504, the cylindrical protrusion on one side corresponds to the through hole, and the end surface of the cylindrical protrusion is recessed inwards to form an inner hexagonal groove, so that an inner hexagonal wrench is inserted into the outer hole to rotationally adjust the reflective photoelectric sensor 4.

Example 2:

the present embodiment is optimized and limited based on the above embodiment 1, as shown in fig. 3 and fig. 4, two installation grooves 504 are provided on the sensor installation seat 503, the rotation axes of the reflective photoelectric sensors 4 installed in the two installation grooves 504 are on the same straight line, and the deviation angle of the light of the two reflective photoelectric sensors 4 is 90-120 °.

The base 502 is fixed in a wall preset groove through bolts, and the top cover 501 is clamped with the base 502. As shown in the figure, the whole housing 5 is a cylindrical structure, and an opening is formed on an arc-shaped surface on one side of the base 502, so that the cable can be conveniently laid.

At least three arc-shaped slide rails 505 are arranged on the inner wall of the base 502 at equal central angles on the same horizontal plane, one ends of the arc-shaped slide rails 505 extend outwards along the direction perpendicular to the wall surface to form vertical extension parts, and the outer wall of the top cover 501 is provided with a convex block 506 which is matched with the arc-shaped slide rails 505 for limiting; when the top cover 501 is buckled into the base 502, the lug 506 enters from the opening of the vertical extension of the arc-shaped slide rail 505 and rotates the top cover 501 to realize clamping fixation after falling into the arc-shaped slide rail 505.

As shown in fig. 3, the arc-shaped slide rail 505 protrudes from top to bottom near the inner end to form a clamping block, and when the edge of the top cover 501 is attached to the end surface of the base 502, the top cover 501 is rotated to allow the three protrusions 506 to pass through the clamping block, thereby achieving a clamping position. When the product is designed, the top 501 can be rotated in a variety of ways so that the top 501 can be completely submerged in the base 502 and flush with the opening of the base 502. For example, in the mode shown in the figure, at least two sinking grooves which are symmetrical with respect to the center of the outer end face of the top cover 501 are formed in the outer end face of the top cover 501, and the flat screwdriver is inserted into a single sinking groove and then is hit to push the top cover 501 to rotate towards one side, so that the mounting or dismounting purpose is achieved.

Example 3:

in this embodiment, optimization and limitation are performed on the basis of the foregoing embodiment 1 or embodiment 2, as shown in fig. 2, the system further includes a remote controller 7 connected to the switch controller 2, the remote controller 7 is connected to an a wireless transceiver module 8, the one or more mobile induction modules 3 are connected to an B wireless transceiver module 9, and signal feedback is performed through wireless communication connection between the B wireless transceiver module 9 and the a wireless transceiver module 8. The whole system further comprises a dimming controller 10, wherein the power supply port of the dimming controller 10 and the power supply port of the switch controller 2 are connected with the air switch 1, and the signal control port of the dimming controller is connected with a control panel 11. The switch controller 2 and the mobile induction module 3 are connected by adopting RS232 serial bus standard.

The switch controller 2 in the embodiment adopts an intelligent controller with the model number of BW-6S, and is provided with a 4-key test and manual programming, an 3/6 loop output relay, 1 manual switch and an RS-232 communication interface; the remote controller 7 adopts an Ethernet soft logic controller with the model number Remo DAQ-9828, which is provided with 10/100 Base-T Ethernet interfaces and 8I/O slots and can support up to 128 local I/O points, a built-in Modbus/RTUServer and an RS-232 interface. The working voltage of the reflective photoelectric sensor 4 is 12-24VDC, the reaction time is 0.5ms, and the detection distance is 5 m. In fig. 2, the wireless transceiver module a 9 and the wireless transceiver module B10 are both wifi signals.

The above description is only a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.

Claims (9)

1. A lighting system for induction control of moving objects, comprising a lamp bank, an air switch (1) and a switch controller (2) connected to the air switch (1) for controlling the lighting of the lamp bank, the air switch (1) being connected to a power bus, characterized in that:

the switch controller (2) is connected with a movable induction module (3), at least one reflective photoelectric sensor (4) is arranged in the movable induction module (3) to sense an object in a rated distance, and the object is subjected to signal feedback to enable the switch controller (2) to control the lamp bank to be switched on and off.

2. The lighting system for performing the induction control of the moving object as set forth in claim 1, wherein: the mobile induction module (3) comprises a split type shell (5), and a transparent cover plate (6) for transmitting light of the reflection type photoelectric sensor (4) is arranged on the shell (5); the reflective photoelectric sensor (4) is arranged in the shell (5) and is rotationally connected with the shell (5).

3. The lighting system for performing the induction control of the moving object as set forth in claim 2, wherein: the shell (5) is of a pre-buried structure and comprises a top cover (501) and a base (502) buried in a preset groove of a wall body, the outer side of the top cover (501) protrudes outwards to form a sensor mounting seat (503), at least one mounting groove (504) is formed in the sensor mounting seat (503), the reflection type photoelectric sensor (4) is arranged in the mounting groove (504), and the transparent cover plate (6) is arranged at an opening of the mounting groove (504).

4. The lighting system for performing the induction control of the moving object as set forth in claim 3, wherein: the sensor mounting seat (503) is provided with two mounting grooves (504), the rotating shafts of the reflective photoelectric sensors (4) mounted in the two mounting grooves (504) are positioned on the same straight line, and the light deviation angle of the two reflective photoelectric sensors (4) is 90-120 degrees.

5. The lighting system for performing the induction control of the moving object as set forth in claim 3, wherein: the base (502) is fixed in a wall preset groove through bolts, and the top cover (501) is connected with the base (502) in a clamping mode.

6. The lighting system for performing the induction control of the moving object as set forth in claim 5, wherein: at least three arc-shaped sliding rails (505) are arranged on the inner wall of the base (502) at equal central angles on the same horizontal plane, one ends of the arc-shaped sliding rails (505) extend outwards along the direction perpendicular to the wall surface to form a vertical extending part, and the outer wall of the top cover (501) is provided with a convex block (506) which is matched with the arc-shaped sliding rails (505) for limiting; when the top cover (501) is buckled into the base (502), the lug (506) enters from the opening of the vertical extension part of the arc-shaped slide rail (505) and rotates the top cover (501) to realize clamping fixation after falling into the arc-shaped slide rail (505).

7. A lighting system for performing induction control of a moving object according to any one of claims 1 to 6, wherein: the system further comprises a remote controller (7) connected with the switch controller (2), the remote controller (7) is connected with an A wireless transceiving module (8), the one or more mobile induction modules (3) are connected with a B wireless transceiving module (9) which is arranged, and signal feedback is carried out through the B wireless transceiving module (9) and the A wireless transceiving module (8) in a wireless communication connection mode.

8. A lighting system for performing induction control of a moving object according to any one of claims 1 to 6, wherein: the system also comprises a dimming controller (10), wherein the power supply port of the dimming controller (10) and the power supply port of the switch controller (2) are connected with the air switch (1), and the signal control port of the dimming controller is connected with a control panel (11).

9. A lighting system for performing induction control of a moving object according to any one of claims 1 to 6, wherein: the switch controller (2) is connected with the mobile induction module (3) by adopting an RS232 serial bus standard.

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