CN211831242U - Rhythm illumination self-adaptive control system based on distributed sensing nodes - Google Patents

Abstract

The utility model discloses a rhythm illumination self-adaptation control system based on distributed sensing node, including distributed sensor, LED equipment, high in the clouds server, local host computer and data transmission equipment; when the local host computer is in network connection with the cloud server, the local host computer executes operation according to the instruction data downloaded by the cloud server in real time and/or the instruction data downloaded by the cloud server and stored in the local host computer; and when the local host computer is disconnected from the cloud server through the network, the local host computer executes operation according to the instruction data downloaded and stored to the local host computer by the cloud server. The utility model discloses can control lighting apparatus according to the difference of scene demand, personnel's quantity difference, time difference and the difference of indoor illuminance, colour temperature and build comfortable, accord with the illumination scene of circadian rhythm.

Description

Rhythm illumination self-adaptive control system based on distributed sensing nodes

Technical Field

The utility model belongs to the technical field of the semiconductor illumination, especially indoor intelligent lighting system field relates to the rhythm illumination self-adaptation control system based on distributed sensing node of illumination to human circadian rhythm's regulation and control.

Background

In one day, the natural light color temperature in areas with different latitudes can change to a certain extent along with the increase and decrease of the irradiation angle of the sun and the atmospheric temperature, and people adapt to the adjustment of the natural light color temperature and the illumination for thousands of years, thereby playing a positive role in adjusting the physiology and promoting the production. Meanwhile, the overall color temperature is different under different weather conditions such as cloudy days and sunny days. The color temperature at sunrise is in the range of 2500-3500K, the warm yellow light facing the sun gives a warm feeling to people, and has the function of promoting awakening of each organ of the body; the early morning color temperature is in the range of 4000-4500K, the body is switched from a sleep state to a waking state, and the higher color temperature further promotes the improvement of the human body function, so that the preparation is prepared for the working and the living of one day. The color temperature in the daytime is maintained in the range of 5000-5400K, and the color temperature in cloudy days and high-latitude areas is higher and reaches 6500-8000K. In the evening, the color temperature falls back to 4000-4500K along with the change of the west of the sun and the atmospheric temperature, and people feel warm and comfortable after working for one day; promoting the regulation of human organs and body functions and recovering to a rest state. At sunset, the color temperature further falls back to 2000-3000K, and the person also enters the rest time of one day. In general, the color temperature changes periodically during a day, and the human body functions also change periodically with the color temperature. Waking up in the early morning, performing full work in the morning, performing brief rest in the afternoon to continue energetic work, and entering a rest state in the evening. The color temperature of the warm white light is about 3000K, so that the warm white light brings comfortable and warm feeling to people; the natural white light has a color temperature of about 4000K, is closest to the solar light at noon, and has high color rendering property; the cool white light is about 6000K, and the brighter white light is suitable for the atmosphere of learning and thinking.

At present, the traditional lighting technology is replaced by the semiconductor LED lighting technology widely applied to indoor and office environments, and the defects of the traditional lighting technology are overcome due to the advantages of high energy efficiency, small size and flexible spectrum. Meanwhile, the condition of over-illumination is caused by the non-standard use of a large number of LED semiconductor illumination devices, and the energy-saving efficiency can be further improved through a certain control strategy; indoor personnel lack natural light. Under the condition of long-time exposure to the LED light source, the problems of physiological discomfort, low comfort and low working efficiency of personnel are caused. The problems can be solved by a good and healthy illumination environment which accords with the physiological rhythm of the human body.

The indoor intelligent lighting system adjusts the indoor lighting environment and comprises the conditions of regional illumination, overall illumination, regional color temperature, overall color temperature, regional color and overall color, different lighting indexes are met, and optimal control of energy is achieved through feedback data of the sensor nodes. At present, a conventional indoor lighting system can only realize start-stop control, remote control and local control on LED lighting equipment, the adjusting effect mainly depends on single subjective feeling of a main person who implements control, lighting environment indexes under the whole environment are difficult to meet, and meanwhile, the condition that objective physiological laws are violated exists. Although the traditional indoor lighting system gives consideration to the individual requirements and convenient control of users to a certain extent, the traditional indoor lighting system does not have reasonable control strategies on energy-saving efficiency and adjustment of illumination, color temperature and the like according with human physiological rules.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem, the utility model discloses a rhythm illumination self-adaptation control system based on distributed sensing node, this system can control lighting apparatus according to the difference of scene demand, personnel's quantity is different, the time is different and the difference of indoor illuminance, colour temperature control and build comfortable, accord with the illumination scene of circadian rhythm. Meanwhile, the system can also preset modes according to scene needs, such as: in the morning, the activity of staff needs to be fully excited to improve the working efficiency, an awakening mode is set, and the color temperature of the lamplight is integrally adjusted to be cold white light; at noon, setting the mode to be a noon break mode for a short noon break time, and integrally adjusting the color temperature of the lamplight to be warm white light to promote the rest and relaxation of the staff; in the afternoon, the mode is set to be the sunset mode in the afternoon, the light color temperature is integrally adjusted to be warm light, and the comfortable and warm feeling like a home is created for workers working after one day. If overtime is needed, the mode can be set to be the overtime mode, the color temperature of the lamplight is adjusted to promote the working efficiency of the staff, and the early-end early-return is strived for. Meanwhile, the function of rhythm regulation can be turned off according to the local interaction panel, the brightness and color temperature control of any lamp or all lamps in the area can be directly controlled, and multiple choices are supported.

The utility model discloses a rhythm illumination self-adaptation control system based on distributed sensing node, its main method that realizes the rhythm illumination is: performing mathematical modeling on indoor and outdoor environment parameters (including illuminance, color temperature, temperature and humidity and the like) provided by sensor nodes and natural light stress rhythms based on human physiology, specific use scenes (such as office, entertainment, sleep and the like) and user use experience feedback quantization indexes, and performing dimensionality reduction analysis on system parameters through a PCA (principal component analysis) algorithm to obtain key parameters; and an optimization algorithm is used for optimizing key parameters of the system to form a self-adaptive control algorithm, so that the rhythm curves of the lighting color temperature and the lighting brightness can be learned on line, and the effect is better as the using time of a user is longer.

The utility model discloses a rhythm illumination self-adaptation control system based on distributed sensing node, including distributed sensor, LED equipment, high in the clouds server, local host computer and data transmission equipment, wherein

Cloud server: the system comprises a local host computer, a data processing unit and a data processing unit, wherein the local host computer is used for receiving a request of the local host computer and downloading instruction data;

and/or, the data feedback uploading of the local host is accepted;

the local host computer: the system comprises a cloud server, a server management server and a server management server, wherein the cloud server is used for accessing and requesting the cloud server and acquiring instruction data;

and/or for performing control of the LED device in accordance with the instruction data;

and/or, for performing control of the distributed sensor in accordance with the instruction data;

and/or, for receiving data feedback of the distributed sensor;

and/or the cloud server is used for uploading data according to the instruction execution;

distributed sensor: the system comprises a monitoring system, a monitoring system and a control system, wherein the monitoring system is used for monitoring environment and/or LED equipment and acquiring environment data and/or related data of the LED equipment in a working area; the monitoring can be real-time discontinuous monitoring on the target according to the requirement of the operation instruction, and can also be fixed continuous monitoring on the target.

The LED equipment is used for implementing illumination operation in the working area range according to the instruction of the local host computer so as to realize the control of color temperature, illumination intensity, illumination range and illumination time in the working area;

a data transmission device for data transmission between at least two of the distributed sensor and/or the LED device and/or the cloud server and/or the local host;

when the local host computer is in network connection with the cloud server, the local host computer executes operation according to the instruction data downloaded by the cloud server in real time and/or the instruction data downloaded by the cloud server and stored in the local host computer; when the local host computer is disconnected from the cloud server, the local host computer executes operation according to the instruction data downloaded and stored to the local host computer by the cloud server.

The utility model discloses a rhythm illumination self-adaptation control system's improvement based on distributed sensing node, local host computer is including lighting on/going out control and/or adjustting of the lighteness control and/or colour temperature regulation control to the control of LED equipment according to the instruction.

The utility model discloses a rhythm illumination self-adaptation control system's improvement based on distributed sensing node, distributed sensor include at least one among light sensor, infrared sensor, colour temperature sensor, the temperature sensor. Further preferably, the environmental data collected by the distributed sensor in the working area includes at least one of color temperature, illumination intensity and illumination range.

The utility model discloses an improvement of rhythm illumination adaptive control system based on distributed sensing node, data transmission equipment include gateway and/or router and/or bridge and/or switch and/or concentrator.

More preferably, the rhythm lighting adaptive control system based on the distributed sensing nodes further comprises a switch device, and the switch device is used for conducting lighting and/or extinguishing and/or brightness adjusting control on the LED devices connected with the switch device under the instruction control of the local host. It is further preferred that the switching device comprises an inductive switch or a dimmer switch or a remote control switch or a smart switch or a touch switch or a network switch.

The utility model discloses a rhythm illumination adaptive control system's improvement based on distributed sensing node, LED equipment include white light LED or ruddiness LED or orange light LED or yellow light LED or green glow LED or blue light LED in one or more's combination.

The utility model discloses one of them implementation scheme of scheme does:

the cloud server or the local host computer is used for downloading the instruction to control the lighting equipment;

uploading the environmental parameters of the sensing nodes by using the gateway and the local host to realize environmental parameter monitoring;

the cloud server or the local host is used for downloading corresponding control instructions to control each lighting device under the system to meet the personalized requirements of color temperature and illumination of different indoor areas, and the indoor lighting energy-saving efficiency is further improved;

the physiological comfort of indoor personnel is effectively improved by implementing a circadian rhythm control strategy, the working efficiency of the indoor personnel is integrally improved, and a healthy and green lighting working environment is created. The illumination and color temperature self-adaption and cooperative control of the lighting equipment are realized through the local host in an off-network state, and the indoor lighting requirement is met.

The local host is positioned in the field control room, so that the control of the lighting equipment and the data acquisition of the sensing nodes can be realized in an off-network state, the conditions of manual control and data loss under the condition of network disconnection of a general lighting system are optimized, and a control strategy is more effective. Meanwhile, real-time adaptive control of the lighting equipment is realized according to the change of the environmental parameters of the sensing nodes, and the function of adjusting color temperature and illumination is achieved.

The utility model discloses utilize the exhibition to be equipment/remove end APP/believe little procedure link high in the clouds server can real-time long-range download instruction control lighting apparatus and collect environmental parameter, realize that a key opens the function that stops all/single lighting apparatus, realize whole lighting environment's convenient control and energy-conserving realization.

The utility model discloses an even illuminance or difference illumination in the illumination environment are realized to sensing node's illuminance feedback data cooperative control lighting apparatus, realize energy-conserving optimal control under satisfying the lighting parameter condition.

The utility model discloses a lighting apparatus, sensing node quantity can expand under the system, realize the integrated total accuse of building.

The utility model discloses a system can be through the monitoring of lighting apparatus gateway and take notes lighting apparatus user state, and the use habit that generates the user realizes intelligent control.

Drawings

Fig. 1 is a schematic diagram of an embodiment of a distributed sensing node-based rhythm lighting adaptive control system.

Detailed Description

The present invention will be further explained with reference to the following detailed description, which is to be understood as illustrative only and not as limiting the scope of the invention.

Example 1

In this embodiment, the adaptive rhythm lighting control system based on distributed sensing nodes includes a distributed sensor, an LED device, a cloud server, a local host, and a data transmission device, where

Cloud server: the system comprises a local host, a server and a server, wherein the local host is used for receiving a request of the local host and downloading instruction data;

in a working area, such as indoors, a local host is arranged: the system has the following functions of connecting to a cloud server through the Internet, accessing and requesting the cloud server, and acquiring instruction data by the cloud server; the LED device is used for controlling the LED device according to the instruction data so as to adjust the switch, the illumination intensity, the color temperature and the like of the related LED device; the control device is used for controlling the distributed sensor according to instruction data; for receiving data feedback of the distributed sensor;

distributed sensor: the system comprises a monitoring module, a monitoring module and a control module, wherein the monitoring module is used for monitoring environment and/or LED equipment according to instructions and acquiring environment data and/or related data of the LED equipment in a working area of the monitoring module; the sensor adopts one or more and multifunctional sensors including the following sensors, such as an HA2003 illumination sensor and the like, and an illumination sensor is used for realizing the detection of the illumination intensity and the like of a target area; an infrared sensor for detecting light irradiation or temperature of a target area, such as OHSP-300I; a temperature sensor for detecting the temperature of the target area, such as an NTC temperature sensor; the color temperature sensor is used for detecting the color temperature of the target area; the above examples are merely exemplary, not limiting, and other types of functional sensors are equally suitable; in addition, other types of sensors or sensor combinations can be adopted according to actual requirements when the scheme is implemented.

The LED equipment is arranged in a working area, namely, the LED equipment is arranged in a white light LED lamp or lamp group, a yellow light LED lamp or lamp group, a red light LED lamp or lamp group, an orange light LED lamp or lamp group, a green light LED lamp or lamp group, a blue light LED lamp or lamp group and the like, and each lamp or lamp group implements lighting operation in the working area according to the requirements or the requirements of control instructions and the control instructions sent by a local host, so as to realize the control of color temperature, illumination intensity, illumination range and illumination time in the working area;

the data transmission equipment, such as a router, connects the distributed sensor, the LED equipment and the local host to form a local area network, so that data transmission among at least two of the distributed sensor, the LED equipment and the local host is realized;

in this embodiment, when the local host operates, the local host always maintains network connection with the cloud server, and then loads the instruction data downloaded by the cloud server in real time to the operating system to execute related operations; at this time, the relevant instruction data may be updated in real time.

Example 2

In this embodiment, the adaptive rhythm lighting control system based on distributed sensing nodes includes a distributed sensor, an LED device, a cloud server, a local host, and a data transmission device, where

Cloud server: the system comprises a local host, a server and a server, wherein the local host is used for receiving a request of the local host and downloading instruction data;

in a working area, such as indoors, a local host, such as a mobile phone or a computer, is provided, and a computer client or an app client running the system technology is loaded: the system has the following functions of connecting to a cloud server through the Internet, accessing and requesting the cloud server, and acquiring instruction data by the cloud server; the LED device is used for controlling the LED device according to the instruction data so as to adjust the switch, the illumination intensity, the color temperature and the like of the related LED device; the control device is used for controlling the distributed sensor according to instruction data; for receiving data feedback of the distributed sensor;

distributed sensor: the system comprises a monitoring system, a monitoring system and a control system, wherein the monitoring system is used for monitoring environment and/or LED equipment according to instructions and acquiring environment data and/or related data of the LED equipment in a working area of the monitoring system; the sensor adopts one or more and multifunctional sensors including the following sensors, such as an HA2003 illumination sensor and the like, and an illumination sensor is used for realizing the detection of the illumination intensity and the like of a target area; an infrared sensor for detecting light irradiation or temperature of a target area, such as OHSP-300I; a temperature sensor for detecting the temperature of the target area, such as an NTC temperature sensor; the above examples are merely exemplary, not limiting, and other types of functional sensors are equally suitable; in addition, other types of sensors or sensor combinations can be adopted according to actual requirements when the scheme is implemented;

the LED equipment is arranged in a working area, namely is arranged in a white light LED lamp or lamp group, a yellow light LED lamp or lamp group, a red light LED lamp or lamp group, an orange light LED lamp or lamp group, a green light LED lamp or lamp group and a blue light LED lamp or lamp group, and each lamp or lamp group implements lighting operation in the working area according to the requirements or the requirements of control instructions and the control instructions sent by a local host machine so as to realize the control of color temperature, illumination intensity, illumination range and illumination time in the working area;

the data transmission equipment, such as a router, connects the distributed sensor, the LED equipment and the local host to form a local area network, so that data transmission among at least two of the distributed sensor, the LED equipment and the local host is realized;

the local host acquires network connection with the cloud server at the beginning stage of work, downloads relevant operation instructions and loads the instructions to the operating system, then disconnects the network connection with the cloud server, and executes operation in an off-line state according to the instruction data downloaded and stored to the local by the cloud server.

Example 3

In this embodiment, the adaptive rhythm lighting control system based on distributed sensing nodes includes a distributed sensor, an LED device, a cloud server, a local host, and a data transmission device, where

Cloud server: the system comprises a local host, a server and a server, wherein the local host is used for receiving a request of the local host and downloading instruction data; the system is used for receiving data feedback uploading of the local host and performing cloud storage or updating on related feedback data;

in a working area, such as indoors, a local host, such as a mobile phone or a computer, is provided, and a computer client or an app client running the system technology is loaded: the system has the following functions of connecting to a cloud server through the Internet, accessing and requesting the cloud server, and acquiring instruction data by the cloud server; the LED device is used for controlling the LED device according to the instruction data so as to adjust the switch, the illumination intensity, the color temperature and the like of the related LED device; the control device is used for controlling the distributed sensor according to instruction data; for receiving data feedback of the distributed sensor; the cloud server is used for uploading data to the cloud server according to instruction execution;

distributed sensor: the system comprises a monitoring module, a monitoring module and a control module, wherein the monitoring module is used for monitoring environment and/or LED equipment according to instructions and acquiring environment data and/or related data of the LED equipment in a working area of the monitoring module; the sensor adopts one or more and multifunctional sensors including the following sensors, such as an HA2003 illumination sensor and the like, and an illumination sensor is used for realizing the detection of the illumination intensity and the like of a target area; an infrared sensor for detecting light irradiation or temperature of a target area, such as OHSP-3001; a temperature sensor for detecting the temperature of the target area, such as an NTC temperature sensor; the above examples are merely exemplary, not limiting, and other types of functional sensors are equally suitable; in addition, other types of sensors or sensor combinations can be adopted according to actual requirements when the scheme is implemented;

the LED equipment is arranged in a working area, namely is arranged in a white light LED lamp or lamp group, a yellow light LED lamp or lamp group, a red light LED lamp or lamp group, an orange light LED lamp or lamp group, a green light LED lamp or lamp group and a blue light LED lamp or lamp group, and each lamp or lamp group implements lighting operation in the working area according to the requirements or the requirements of control instructions and the control instructions sent by a local host machine so as to realize the control of color temperature, illumination intensity, illumination range and illumination time in the working area;

the data transmission equipment, such as a gateway, connects the distributed sensor, the LED equipment and the local host to form a local area network, so that data transmission among at least two of the distributed sensor, the LED equipment and the local host is realized;

similarly, the implementation of the technical scheme of the embodiment can also implement feedback under the condition that the host is always connected with the cloud server through the network; or after the host downloads and loads the relevant instruction data, the host disconnects the contact with the cloud server and disconnects the network to implement locally.

Example 4

As shown in fig. 1, the continuous representation between the structures may have data transmission or control connection relationship, and the dashed structure represents the system structure part that is not necessarily composed, such as the sensor is directly plugged into the local computer without using additional equipment for auxiliary connection; the LED lamp is directly regulated and controlled by an instruction through a built-in driving device.

In this embodiment, the adaptive rhythm lighting control system based on distributed sensing nodes includes a distributed sensor, an LED device, a cloud server, a local host, and a data transmission device, where

Cloud server: the system comprises a local host, a server and a server, wherein the local host is used for receiving a request of the local host and downloading instruction data; the system is used for receiving data feedback uploading of the local host and performing cloud storage or updating on related feedback data;

in a working area, such as indoors, a plurality of local hosts are arranged, local networks are formed among the hosts through switches or among the hosts to exchange and transmit data, such as mobile phones or computers and the like, computer clients or app clients which operate the system technology are loaded, and the local hosts or app clients have the following functions: one of the backup machines is used as an access backup machine, is connected to the cloud server through the Internet, accesses and requests the cloud server, and obtains instruction data from the cloud server; the other one is used as an execution operating machine which acquires the instruction data downloaded by the access backup machine, and after the instruction data is loaded, the other one executes the control of the LED equipment according to the instruction data so as to adjust the switch, the illumination intensity, the color temperature and the like of the related LED equipment; the other one is used as a monitoring host computer for executing the control of the distributed sensor and receiving the data of the distributed sensor, and then feeding the related data back to the execution operation machine for the execution of the program; the other one is used as an uploading host and is used for uploading, feeding back and updating data to the cloud server according to the execution operation and other related data acquired by the execution operation machine;

distributed sensor: the system comprises a monitoring module, a monitoring module and a control module, wherein the monitoring module is used for monitoring environment and/or LED equipment according to instructions and acquiring environment data and/or related data of the LED equipment in a working area of the monitoring module; the sensor adopts one or more and multifunctional sensors including the following sensors, such as an HA2003 illumination sensor and the like, and an illumination sensor is used for realizing the detection of the illumination intensity and the like of a target area; an infrared sensor for detecting light irradiation or temperature of a target area, such as OHSP-3001; a temperature sensor for detecting the temperature of the target area, such as an NTC temperature sensor; the above examples are merely exemplary, not limiting, and other types of functional sensors are equally suitable; in addition, other types of sensors or sensor combinations can be adopted according to actual requirements when the scheme is implemented;

the LED equipment is arranged in a working area, namely is arranged in a white light LED lamp or lamp group, a yellow light LED lamp or lamp group, a red light LED lamp or lamp group, an orange light LED lamp or lamp group, a green light LED lamp or lamp group and a blue light LED lamp or lamp group, and each lamp or lamp group implements lighting operation in the working area according to the requirements or the requirements of control instructions and the control instructions sent by a local host machine so as to realize the control of color temperature, illumination intensity, illumination range and illumination time in the working area;

the data transmission equipment, such as a switch, connects the distributed sensor, the LED equipment and the local host to form a local area network, so that data transmission among at least two of the distributed sensor, the LED equipment and the local host is realized;

similarly, the implementation of the technical scheme of the embodiment can also implement feedback under the condition that the host is always connected with the cloud server through the network; or after the host downloads and loads the relevant instruction data, the host disconnects the contact with the cloud server and disconnects the network to implement locally.

Including but not limited to the above embodiments, the control of the LED device may be performed by using a switch device, which performs lighting and/or extinguishing and/or brightness adjustment control on the LED device connected to the switch device under the instruction control of the local host. The switching device may include, without limitation, a switch as described below: the inductive switch, such as an infrared inductive switch, can be used for starting the lamp group in the relevant area when sensing personnel to enter, and feeding back information to the local host to start the system to operate, such as FOTEK Taiwan Yangming A3T-3 MX; the dimming switch can control the brightness of different requirements of the light brightness, such as Philips luminance meter LPS100/00 and the like; the remote control switch is used for sending an instruction to the local unit by an operator so as to adjust the working state of the LED equipment in the target area; the intelligent switch is used for intelligently adjusting the working state of the LED equipment in the target area according to the instruction under the control of the instruction sent by the local unit; the touch switch is used for sending an instruction to the local unit through the touch of an operator so as to start the system or start the equipment in the relevant area to work; and the network switch is used for implementing network connection with a local unit or a mobile phone of an operator through a network, and further intelligently adjusting the working state of the LED equipment in the target area according to the instruction under the control of sending the instruction by the local unit according to the network instruction. The above examples are merely exemplary, not limiting, and other types of function switches are equally applicable; in addition, other types of switches or combination switches can be adopted according to actual requirements when the scheme is implemented.

The data transmission and connection can be realized by directly adopting cable connection among all devices, for example, the sensors are plugged into a local host computer through data lines, or the connection can be realized through a switch, a hub, a network bridge, a gateway, a router and the like.

The utility model discloses the system operation principle of scheme relates to distributed sensing node, sensor gateway, switch drive, switch gateway, LED drive, LED gateway, local host computer, high in the clouds server, LED equipment are constituteed.

The cloud server downloads the control instruction to the local host and distributes the control instruction to each gateway through the local host.

And downloading a control instruction through the gateway to control corresponding equipment under each system.

Uploading the environmental parameters of the sensing nodes through the sensor gateway.

The local host can realize a local self-adaption/circadian rhythm lighting control strategy, and can also realize remote control through a cloud server.

Example 5 is:

in one office building in the Hai lake district of Beijing, 100 square meters of indoor offices are selected as demonstration areas, and a 50 square large office, office I, and two small offices, office II and office III, which are 20 square and 30 square respectively, are arranged in total. A control computer is disposed in the demonstration area and is connected with the subsystems of each office for controlling and operating the lighting system. Office I, office II and office III all establish only independent router, illumination sensor HA2003, temperature sensor NTC temperature sensor, colour temperature sensor Intersil ISL29125, infrared sensor OHSP-300I, LED banks and be used for controlling the intelligence switch of banks respectively, and the banks comprises a plurality of white light LED lamps, yellow light LED lamp, and all indoor facilities are all installed in corresponding indoor area according to fitment design, user demand. The illumination sensor HA2003, the temperature sensor NTC temperature sensor, the color temperature sensor Intersil ISL29125, the infrared sensor OHSP-300I and the intelligent switch are in communication connection with a control computer through a router, and the lamp bank is electrically connected with the intelligent switch and then connected to the mains supply. In the morning and at work hours, the control computer starts the lamp set to adjust the indoor color temperature to a proper range, such as about 6000K, according to a preset program so as to meet the working requirement. Of course, when drawing, the color temperature is adjusted to about 4000K by manually adjusting the corresponding switch in a partial area. The noon break time is adjusted to about 3000K. In addition, in abnormal starting time, when the infrared sensor detects that a person enters, the intelligent switch also controls the lamp set in the relevant area to work and adjusts the lamp set to a proper color temperature range. Compared with the comparison example which adopts a conventional LED lamp illumination mode and has no adjustment all day long, the embodiment saves energy within one year by 15-20% compared with the comparison example, improves the working efficiency of human workers by about 10-15% under the same condition, and calculates the average output value of human.

The embodiment of the present invention is directed to the technical scope of the present invention, wherein the middle point value of the technical scope of the present invention is not exhaustive, and the remote control system is also within the scope of the present invention to form a new technical solution for equivalent replacement of a single or multiple technical features in the technical solution of the embodiment to the cloud system/server; in the embodiments of the present invention, all the parameters in the same embodiment are only an example (i.e. a feasible solution) of the technical solution, and there is no strict matching and limiting relationship between the parameters, wherein the parameters can be replaced with each other without violating the axiom and the requirements of the present invention, except for the specific statement.

The technical means disclosed by the scheme of the utility model is not limited to the technical means disclosed by the technical means, but also comprises the technical scheme formed by the arbitrary combination of the technical characteristics. The above is a detailed implementation manner of the present invention, and it should be noted that, for those skilled in the art, a plurality of improvements and decorations can be made without departing from the principle of the present invention, and these improvements and decorations are also considered as the protection scope of the present invention.

Claims (8)

1. The utility model provides a rhythm illumination self-adaptation control system based on distributed sensing node, includes distributed sensor, LED equipment, high in the clouds server, local host computer and data transmission equipment, its characterized in that:

the cloud server is used for receiving a request of the local host and downloading instruction data;

and/or, the data feedback uploading of the local host is accepted;

the local host is used for accessing and requesting the cloud server and acquiring instruction data by the cloud server;

and/or for performing control of the LED device in accordance with the instruction data;

and/or, for performing control of the distributed sensor in accordance with the instruction data;

and/or, for receiving data feedback of the distributed sensor;

and/or the cloud server is used for uploading data according to the instruction execution;

the distributed sensor is used for monitoring the environment and/or the LED equipment and acquiring environment data and/or related data of the LED equipment in a working area of the distributed sensor;

the LED equipment is used for implementing illumination operation in the working area range according to the instruction of the local host computer so as to realize the control of color temperature, illumination intensity, illumination range and illumination time in the working area;

the data transmission equipment is used for data transmission between at least two of the distributed sensor and/or the LED equipment and/or the cloud server and/or the local host;

the local host computer is in network connection with the cloud server and is used for executing operation on instruction data downloaded by the cloud server in real time and/or instruction data downloaded by the cloud server and stored in the local host computer; the local host computer is disconnected with the cloud server through the network and used for downloading and storing the instruction data to the local host computer through the cloud server to execute operation.

2. The distributed sensing node based adaptive control system for rhythmic lighting according to claim 1, wherein the local host controls the LED devices according to instructions, including lighting/extinguishing control and/or dimming control and/or color temperature adjustment control.

3. The distributed sensing node based rhythmic lighting adaptive control system of claim 1, wherein the distributed sensor includes at least one of an illumination sensor, a color temperature sensor, an infrared sensor, and a temperature sensor.

4. The adaptive rhythmic lighting control system according to claim 3, wherein the environment data collected by the distributed sensor in the working area includes at least one of color temperature, illumination intensity and illumination range.

5. The distributed sensing node based rhythm lighting adaptive control system according to claim 1, wherein the data transmission device comprises a gateway and/or a router and/or a bridge and/or a switch and/or a hub.

6. The distributed sensing node based rhythm lighting adaptive control system according to any one of claims 1-5, wherein the distributed sensing node based rhythm lighting adaptive control system further comprises a switch device for controlling on and/or off and/or brightness adjustment of the LED devices connected to the switch device under the instruction control of the local host.

7. The distributed sensing node based adaptive control system for rhythmic lighting according to claim 6, wherein the switching device comprises an inductive switch, a dimming switch, a remote control switch, a smart switch, a touch switch, or a network switch.

8. The adaptive rhythm illumination control system based on distributed sensing nodes according to claim 1, wherein the LED devices comprise one or more combinations of white LEDs or red LEDs or orange LEDs or yellow LEDs or green LEDs or blue LEDs.

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