CN116828675B - Unstructured multimode dynamic intelligent lighting control system - Google Patents

Abstract

The invention discloses an unstructured multimode dynamic intelligent lighting control system, which relates to the field of lighting control and comprises the following components: a solar energy collection module; this unstructured multimode developments intelligent lighting control system carries out the scientific distribution with the electric energy according to the quantity of daylighting lighting module and compensation lighting module through the electric quantity distribution module, set up like this and not only can adjust the illumination luminance of daylighting lighting module and compensation lighting module through the electric energy input of adjusting daylighting lighting module and compensation lighting module, guarantee that the illumination luminance of daylighting lighting module and compensation lighting module is higher than ambient illuminance detection standard, can also increase the illumination time simultaneously under the circumstances of guaranteeing ambient illuminance intensity, through the different quantity of compensation lighting module of lighting control module control, guarantee the regulation of the illumination luminance of daylighting lighting module and compensation lighting module, simultaneously measure the operational environment who detects lighting system with the temperature variation of control lighting lamp group through temperature control module.

Description

Unstructured multimode dynamic intelligent lighting control system

Technical Field

The invention relates to a lighting control technology, in particular to an unstructured multimode dynamic intelligent lighting control system.

Background

When the existing lighting system is used, solar photovoltaic is generally adopted for power supply in order to reduce urban energy consumption, and the solar energy cannot adjust the lighting brightness of the existing lighting device, so that the loss of solar energy is easy to occur because the lighting brightness of the lighting device is higher than the lighting requirement.

Disclosure of Invention

It is an object of the present invention to provide an unstructured multimode dynamic intelligent lighting control system that addresses the above-described deficiencies in the prior art.

In order to achieve the above object, the present invention provides the following technical solutions: an unstructured multimode dynamic intelligent lighting control system comprising:

the solar energy collection module is used for collecting and storing solar energy;

the solar energy conversion module is used for converting solar energy stored by the solar energy collection module into electric energy;

the lighting module is used for efficiently focusing natural light and then introducing a large amount of natural light into a dark environment to realize low-energy consumption lighting and lighting;

the compensating lighting module is used for compensating lighting in a dim environment and increasing the illumination intensity of the dim environment;

the environment illumination detection module is used for detecting the environment illumination of the dim environment under the condition that the lighting illumination module and the plurality of compensation illumination modules are started, and the environment illumination detection standard is input into the environment illumination detection module by staff;

the electric quantity distribution module is used for scientifically distributing the electric energy converted by the solar energy conversion module according to the number of the lighting illumination modules and the number of the compensation illumination modules, and increasing illumination time under the condition of ensuring ambient illumination intensity;

and the illumination control module is used for controlling the compensation illumination module.

Further, the solar energy collection module includes:

the light collecting device is used for carrying out solar energy by adopting a solar photovoltaic panel;

the solar automatic tracking device comprises a fixing device used for fixing, a pitching shaft used for fixing a solar photovoltaic panel, a pitching stepping motor used for driving the pitching shaft to conduct pitching motion, a rotating shaft used for driving the solar photovoltaic panel to rotate and a rotating stepping motor used for driving the rotating shaft to rotate, and the pitching stepping motor and the rotating stepping motor are powered through the solar photovoltaic panel.

Further, the solar energy conversion module includes:

and the controller is used for controlling the solar module to charge and protect the storage battery and automatically controlling the storage battery to supply power and protect.

And the storage battery is used for storing electric energy generated by the solar energy component.

Further, the daylighting lighting module includes:

the light condensing module adopts an optical lens structure for converging solar rays to form a focusing light spot so as to improve sunlight illuminance;

the light source diffusion structure comprises a light diffusion lens and a color filter, wherein the light diffusion lens is used for diffusing an accepted light source, and the color filter is used for converting sunlight into specific fields so as to form various color lights under specific requirements;

the light guide structure is used for cooling high-efficiency converged solar light spots and then transmitting the cooled high-efficiency converged solar light spots into the light source diffusion structure.

Further, the lighting control module includes:

the network configuration module is used for scanning, adding and removing the lighting equipment;

the lamp control module comprises a single lamp control module and a group control module, wherein the single lamp control module is used for performing single lamp switching operation and personalized color temperature adjustment operation, and the group control module is used for grouping nodes and performing group control on the groups;

and the temperature control module is used for measuring and controlling the temperature change of the illumination lamp group.

Further, the specific working mode of the network configuration module is as follows:

a1, the equipment sends out a broadcast signal outwards, wherein Unprovisioned Device Beacon is sent out by the non-network-access equipment, and security Beacon is sent out by the network-access equipment, when the starting configuration equipment receives the broadcast message of the non-network-access equipment, the equipment is identified through the UUID value and the MAC address of the equipment, the user starts adding equipment to the network through the starting configuration equipment, and the starting configuration equipment establishes a configuration bearing layer;

a2, when the configuration equipment is started to find out that the equipment to be accessed to the network is Unprovisioned Device, actively sending a configuration invitation packet to the equipment to send out an invitation, wherein the configuration invitation packet only has an extra duration field for determining how long a main element of the equipment uses an attribute Timer to identify itself, if a configuration bearing layer stops, the equipment should set the attribute Timer state of the main element to 0x00 (off), and Unprovisioned Device responds to a configuration capability packet after receiving the invitation and is used for replying which capabilities the equipment itself has;

a3, after the starting configuration equipment knows the capability of the new Device, selecting an encryption algorithm from the configuration capability package sent by the starting configuration equipment to perform public key exchange, if the starting configuration equipment does not support the encryption algorithm provided in the configuration capability package, the starting configuration equipment selects the highest encryption algorithm supported by the starting configuration equipment, and finally the new Device exchanges password hashes with the starting configuration equipment to finish authentication of both sides;

a4, the startup configuration Device has mastered the information and functions of the new Device through the three steps, and performs public key exchange and authentication mode selection with the information and functions, and the startup configuration Device sends a message to the new Device to request the new Device to perform corresponding reaction according to the message, for example: sound, flashing lights or displaying characters on a screen, starting configuration equipment to verify the reaction of the configuration equipment;

and A5, after authentication is completed, the starting configuration Device and the new Device generate a session key by exchanging a private key and a public key, the starting configuration Device sends configuration data encrypted by the session key to the new Device, and the new Device receives and decrypts the configuration data, so that starting configuration is completed, and the new Device is successfully added into the Mesh network to become a node in the Mesh network.

Further, the single lamp control module specifically works in the following manner:

b1, judging whether a corresponding single lamp is connected by a node or not;

b2, if the judgment result in the step B1 is yes, performing operation selection by a user, and if the judgment result in the step B2 is no, performing operation selection after adding a corresponding single lamp node, wherein the operation comprises switch control and color temperature adjustment;

b3, after the operation selection is completed in the step B2, data transmission is carried out;

and B4, the single-lamp node finishes the operation selected in the step B2.

Further, the specific working mode of the group control module is as follows

C1, selecting corresponding equipment and entering a group interface;

c2, judging whether the equipment has a group;

if the judgment result in the step C2 is yes, clicking the group to be controlled, and if the judgment result in the step C2 is no, clicking the group to be controlled after creating the group;

c4, entering a group control interface;

c5, judging whether any node subscribes to the group;

c6, if the judgment result in the step C5 is yes, clicking the subscribing device;

c7, jumping the node selection interface;

c8, judging whether nodes exist in the network;

if the judgment result in the step C8 is yes, selecting a node, if the judgment result in the step C8 is no, firstly clicking a button of the scanning equipment, then entering a scanning equipment interface, then clicking network access equipment, finally judging whether network access is successful or not, and if the judgment result is yes, selecting the node;

c10, successful node subscription;

and C11, completing the group control operation.

Compared with the prior art, the unstructured multimode dynamic intelligent lighting control system provided by the invention scientifically distributes electric energy according to the number of lighting modules and compensating lighting modules through the electric quantity distribution module, so that the lighting brightness of the lighting modules and the compensating lighting modules can be adjusted through adjusting the electric energy input of the lighting modules and the compensating lighting modules, the lighting brightness of the lighting modules and the compensating lighting modules is ensured to be higher than an ambient illuminance detection standard, meanwhile, the lighting time can be increased under the condition of ensuring the ambient illuminance intensity, the different numbers of compensating lighting modules are controlled through the lighting control module, the adjustment of the lighting brightness of the lighting modules and the compensating lighting modules is ensured, and meanwhile, the working environment of the lighting system is detected through measuring and controlling the temperature change of the lighting lamp set through the temperature control module.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings may be obtained according to these drawings for a person having ordinary skill in the art.

FIG. 1 is a schematic diagram of an overall path structure according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of a single lamp control flow provided in an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a group control flow provided in an embodiment of the present invention.

Detailed Description

In order to make the technical scheme of the present invention better understood by those skilled in the art, the present invention will be further described in detail with reference to the accompanying drawings.

Referring to fig. 1-3, an unstructured multimode dynamic intelligent lighting control system, comprising:

the solar energy collection module is used for collecting and storing solar energy;

the solar energy conversion module is used for converting solar energy stored by the solar energy collection module into electric energy;

the lighting module is used for efficiently focusing natural light and then introducing a large amount of natural light into a dark environment to realize low-energy consumption lighting and lighting;

the compensating lighting module is used for compensating lighting in a dim environment and increasing the illumination intensity of the dim environment;

the environment illuminance detection module is used for detecting the environment illuminance of the dim environment under the condition that the lighting illumination module and the plurality of compensation illumination modules are started, and the environment illuminance detection standard is input into the environment illuminance detection module by staff;

the electric quantity distribution module is used for scientifically distributing the electric energy converted by the solar energy conversion module according to the number of the lighting illumination modules and the number of the compensation illumination modules, and increasing illumination time under the condition of ensuring the intensity of ambient illumination;

and the illumination control module is used for controlling the compensation illumination module.

The specific working method of the multimode dynamic intelligent lighting control system is as follows: the solar energy stored by the solar energy collecting module is converted into electric energy through the solar energy converting module, the natural light is efficiently focused by the lighting module, a large amount of natural light is introduced into the dark environment to realize low-energy consumption lighting and lighting, meanwhile, the illumination intensity of the dark environment is increased through the compensation lighting module, the illumination intensity of the dark environment is increased, the ambient illumination intensity of the dark environment under the condition that the lighting module and a plurality of compensation lighting modules are started is detected through the ambient illumination detecting module, the ambient illumination detecting standard is input into the ambient illumination detecting module through staff, the electric energy converted by the solar energy converting module is scientifically distributed according to the quantity of the lighting module and the compensation lighting module through the electric energy distributing module, the lighting brightness of the lighting module and the compensation lighting module can be adjusted through the electric energy input of the lighting module and the compensation lighting module, the lighting brightness of the lighting module and the compensation lighting module can be ensured to be higher than the ambient illumination detecting standard, the lighting time can be increased under the condition that the ambient illumination intensity is ensured, the lighting control module is controlled through the lighting control module, the lighting system is controlled through the lighting control module, and the temperature of the compensation module and the lighting module is controlled through the lighting control system.

The solar energy collection module includes:

the light collecting device is used for carrying out solar energy by adopting a solar photovoltaic panel;

the solar automatic tracking device comprises a fixing device used for fixing, a pitching shaft used for fixing a solar photovoltaic panel, a pitching stepping motor used for driving the pitching shaft to conduct pitching motion, a rotating shaft used for driving the solar photovoltaic panel to rotate and a rotating stepping motor used for driving the rotating shaft to rotate, wherein the pitching stepping motor and the rotating stepping motor are powered through the solar photovoltaic panel.

The solar energy collection device is arranged to collect solar energy by adopting the solar photovoltaic panel, and meanwhile, the solar photovoltaic panel is always perpendicular to solar rays, so that automatic tracking of the solar energy photovoltaic panel to the sun is realized, and the maximum illumination intensity received by the solar photovoltaic panel is ensured.

The solar energy conversion module includes:

and the controller is used for controlling the solar module to carry out charging protection on the storage battery and automatically controlling the storage battery to carry out power supply protection.

And the storage battery is used for storing electric energy generated by the solar energy component.

The daylighting lighting module includes:

the light condensing module adopts an optical lens structure for converging solar rays to form a focusing light spot so as to improve sunlight illuminance;

the light source diffusion structure comprises a light diffusion lens and a color filter, wherein the light diffusion lens is used for diffusing an accepted light source, and the color filter is used for converting sunlight into specific fields and light of various colors under specific requirements;

the light guide structure is used for cooling the high-efficiency converged solar light spots and then transmitting the cooled solar light spots into the light source diffusion structure.

The lighting control module includes:

the network configuration module is used for scanning, adding and removing the lighting equipment;

the lamp control module comprises a single lamp control module and a group control module, wherein the single lamp control module is used for performing single lamp switching operation and personalized color temperature adjustment operation, and the group control module is used for grouping nodes and performing group control on the groups;

and the temperature control module is used for measuring and controlling the temperature change of the illumination lamp group.

The specific working mode of the network configuration module is as follows:

a1, the equipment sends out a broadcast signal outwards, wherein Unprovisioned Device Beacon is sent out by the non-network-access equipment, and security Beacon is sent out by the network-access equipment, when the starting configuration equipment receives the broadcast message of the non-network-access equipment, the equipment is identified through the UUID value and the MAC address of the equipment, the user starts adding equipment to the network through the starting configuration equipment, and the starting configuration equipment establishes a configuration bearing layer;

a2, when the configuration equipment is started to find out that the equipment to be accessed to the network is Unprovisioned Device, actively sending a configuration invitation packet to the equipment to send out an invitation, wherein the configuration invitation packet only has an extra duration field for determining how long a main element of the equipment uses an attribute Timer to identify itself, if a configuration bearing layer stops, the equipment should set the attribute Timer state of the main element to 0x00 (off), and Unprovisioned Device responds to a configuration capability packet after receiving the invitation and is used for replying which capabilities the equipment itself has;

a3, after the starting configuration equipment knows the capability of the new Device, selecting an encryption algorithm from the configuration capability package sent by the starting configuration equipment to perform public key exchange, if the starting configuration equipment does not support the encryption algorithm provided in the configuration capability package, the starting configuration equipment selects the highest encryption algorithm supported by the starting configuration equipment, and finally the new Device exchanges password hashes with the starting configuration equipment to finish authentication of both sides;

a4, the startup configuration Device has mastered the information and functions of the new Device through the three steps, and performs public key exchange and authentication mode selection with the information and functions, and the startup configuration Device sends a message to the new Device to request the new Device to perform corresponding reaction according to the message, for example: sound, flashing lights or displaying characters on a screen, starting configuration equipment to verify the reaction of the configuration equipment;

and A5, after authentication is completed, the starting configuration Device and the new Device generate a session key by exchanging a private key and a public key, the starting configuration Device sends configuration data encrypted by the session key to the new Device, and the new Device receives and decrypts the configuration data, so that starting configuration is completed, and the new Device is successfully added into the Mesh network to become a node in the Mesh network.

The specific working mode of the single lamp control module is as follows:

b1, judging whether a corresponding single lamp is connected by a node or not;

b2, if the judgment result in the step B1 is yes, the user performs operation selection, and if the judgment result in the step B2 is no, the operation selection is performed after adding the corresponding single lamp node, wherein the operation comprises switch control and color temperature adjustment;

b3, after the operation selection is completed in the step B2, data transmission is carried out;

and B4, the single-lamp node finishes the operation selected in the step B2.

The group control module specifically works in the following manner

C1, selecting corresponding equipment and entering a group interface;

c2, judging whether the equipment has a group;

if the judgment result in the step C2 is yes, clicking the group to be controlled, and if the judgment result in the step C2 is no, clicking the group to be controlled after creating the group;

c4, entering a group control interface;

c5, judging whether any node subscribes to the group;

c6, if the judgment result in the step C5 is yes, clicking the subscribing device;

c7, jumping the node selection interface;

c8, judging whether nodes exist in the network;

if the judgment result in the step C8 is yes, selecting a node, if the judgment result in the step C8 is no, firstly clicking a button of the scanning equipment, then entering a scanning equipment interface, then clicking network access equipment, finally judging whether network access is successful or not, and if the judgment result is yes, selecting the node;

c10, successful node subscription;

and C11, completing the group control operation.

Working principle: when the solar energy collection system is used, solar energy stored by the solar energy collection module is collected and stored by the solar energy conversion module and converted into electric energy, the lighting module is used for efficiently focusing natural light and then largely introducing the natural light into the dark environment to realize low-energy consumption lighting and lighting, meanwhile, the illumination intensity of the dark environment is increased by the compensation lighting module, the illumination intensity of the dark environment is increased, the ambient illumination intensity is detected by the ambient illumination detection module under the condition that the lighting module and a plurality of compensation lighting modules are started, the ambient illumination detection standard is input into the ambient illumination detection module by staff, electric energy converted by the solar energy conversion module is scientifically distributed according to the quantity of the lighting modules and the compensation lighting modules by the electric quantity distribution module, so that the lighting brightness of the lighting modules and the compensation lighting modules can be adjusted by adjusting the electric energy input of the lighting modules and the compensation lighting modules, the illumination time is increased under the condition that the ambient illumination intensity is higher than the ambient illumination detection standard, the ambient illumination control module is controlled by the lighting control module, and the temperature of the compensation lighting modules and the compensation lighting module are controlled by the lighting control module is controlled by the lighting control module, and the temperature of the compensation system is controlled by the lighting module to change the illumination module.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that modifications may be made to the described embodiments in various different ways without departing from the spirit and scope of the invention. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive of the scope of the invention, which is defined by the appended claims.

Claims (4)

1. An unstructured multimode dynamic intelligent lighting control system, comprising:

the solar energy collection module is used for collecting and storing solar energy;

the solar energy conversion module is used for converting solar energy stored by the solar energy collection module into electric energy;

the lighting module is used for efficiently focusing natural light and then introducing a large amount of natural light into a dark environment to realize low-energy consumption lighting and lighting;

the compensating lighting module is used for compensating lighting in a dim environment and increasing the illumination intensity of the dim environment;

the environment illumination detection module is used for detecting the environment illumination of the dim environment under the condition that the lighting illumination module and the plurality of compensation illumination modules are started, and the environment illumination detection standard is input into the environment illumination detection module by staff;

the electric quantity distribution module is used for scientifically distributing the electric energy converted by the solar energy conversion module according to the number of the lighting illumination modules and the number of the compensation illumination modules, and increasing illumination time under the condition of ensuring ambient illumination intensity;

the illumination control module is used for controlling the compensation illumination module;

the lighting control module includes:

the network configuration module is used for scanning, adding and removing the lighting equipment;

the lamp control module comprises a single lamp control module and a group control module, wherein the single lamp control module is used for performing single lamp switching operation and personalized color temperature adjustment operation, and the group control module is used for grouping nodes and performing group control on the groups;

the temperature control module is used for measuring and controlling the temperature change of the lighting lamp group;

the network configuration module specifically works in the following manner:

a1, the equipment sends out a broadcast signal outwards, wherein Unprovisioned Device Beacon is sent out by the non-network-access equipment, and security Beacon is sent out by the network-access equipment, when the starting configuration equipment receives the broadcast message of the non-network-access equipment, the equipment is identified through the UUID value and the MAC address of the equipment, the user starts adding equipment to the network through the starting configuration equipment, and the starting configuration equipment establishes a configuration bearing layer;

a2, when the configuration equipment is started to find out that the equipment to be accessed to the network is Unprovisioned Device, actively sending a configuration invitation packet to the equipment to send out an invitation, wherein the configuration invitation packet only has an extra duration field for determining how long a main element of the equipment uses an attribute Timer to identify itself, if a configuration bearing layer stops, the equipment should set the attribute Timer state of the main element to 0x00 (off), and Unprovisioned Device responds to a configuration capability packet after receiving the invitation and is used for replying which capabilities the equipment itself has;

a3, after the starting configuration equipment knows the capability of the new Device, selecting an encryption algorithm from the configuration capability package sent by the starting configuration equipment to perform public key exchange, if the starting configuration equipment does not support the encryption algorithm provided in the configuration capability package, the starting configuration equipment selects the highest encryption algorithm supported by the starting configuration equipment, and finally the new Device exchanges password hashes with the starting configuration equipment to finish authentication of both sides;

a4, the startup configuration Device has mastered the information and functions of the new Device through the three steps, and performs public key exchange and authentication mode selection with the information and functions, and the startup configuration Device sends a message to the new Device to request the new Device to perform corresponding reaction according to the message, for example: sound, flashing lights or displaying characters on a screen, starting configuration equipment to verify the reaction of the configuration equipment;

a5, after authentication is completed, the starting configuration Device and the new Device generate a session key by exchanging a private key and a public key, the starting configuration Device sends configuration data encrypted by the session key to the new Device, and the new Device receives and decrypts the configuration data, so that starting configuration is completed, and the new Device is successfully added into the Mesh network to become a node in the Mesh network;

the single lamp control module specifically works in the following manner:

b1, judging whether a corresponding single lamp is connected by a node or not;

b2, if the judgment result in the step B1 is yes, performing operation selection by a user, and if the judgment result in the step B2 is no, performing operation selection after adding a corresponding single lamp node, wherein the operation comprises switch control and color temperature adjustment;

b3, after the operation selection is completed in the step B2, data transmission is carried out;

b4, the single-lamp node finishes the operation selected in the step B2;

the group control module specifically works in the following manner:

c1, selecting corresponding equipment and entering a group interface;

c2, judging whether the equipment has a group;

if the judgment result in the step C2 is yes, clicking the group to be controlled, and if the judgment result in the step C2 is no, clicking the group to be controlled after creating the group;

c4, entering a group control interface;

c5, judging whether any node subscribes to the group;

c6, if the judgment result in the step C5 is yes, clicking the subscribing device;

c7, jumping the node selection interface;

c8, judging whether nodes exist in the network;

if the judgment result in the step C8 is yes, selecting a node, if the judgment result in the step C8 is no, firstly clicking a button of the scanning equipment, then entering a scanning equipment interface, then clicking network access equipment, finally judging whether network access is successful or not, and if the judgment result is yes, selecting the node;

c10, successful node subscription;

and C11, completing the group control operation.

2. The unstructured multimode dynamic intelligent lighting control system of claim 1, wherein the solar collection module comprises:

the light collecting device is used for carrying out solar energy by adopting a solar photovoltaic panel;

the solar automatic tracking device comprises a fixing device used for fixing, a pitching shaft used for fixing a solar photovoltaic panel, a pitching stepping motor used for driving the pitching shaft to conduct pitching motion, a rotating shaft used for driving the solar photovoltaic panel to rotate and a rotating stepping motor used for driving the rotating shaft to rotate, and the pitching stepping motor and the rotating stepping motor are powered through the solar photovoltaic panel.

3. The unstructured multimode dynamic intelligent lighting control system of claim 2, wherein the solar conversion module comprises:

the controller is used for controlling the solar module to charge and protect the storage battery and automatically controlling the storage battery to supply power and protect;

and the storage battery is used for storing electric energy generated by the solar energy component.

4. The unstructured multimode dynamic intelligent lighting control system of claim 3, wherein the daylighting lighting module comprises:

the light condensing structure adopts an optical lens structure for converging solar rays to form a focusing light spot so as to improve sunlight illuminance;

the light source diffusion structure comprises a light diffusion lens and a color filter, wherein the light diffusion lens is used for diffusing an accepted light source, and the color filter is used for converting sunlight into specific fields so as to form various color lights under specific requirements;

the light guide structure is used for cooling high-efficiency converged solar light spots and then transmitting the cooled high-efficiency converged solar light spots into the light source diffusion structure.