CN205987498U - A control system for illumination network - Google Patents

Abstract

The utility model discloses a control system for illumination network. The control system of this illumination network includes: single lamp controlgear for carry out the operation of predetermineeing of predetermineeing the time quantum according to the single lamp of the control of the control command to single lamp execution control, the centralized control ware is connected with single lamp controlgear for the state information of receipt when the operation is predetermine in the execution of single lamp, and monitored control system, be connected with the centralized control ware for according to state information adjustment control command, the centralized control ware is used for providing the data transmission's between monitored control system and the single lamp controlgear channel. Through the utility model discloses, the effect that improves the flexibility of illumination network control has been reached.

Description

Control systems for lighting networks

technical field

The utility model relates to the communication field, in particular to a control system for lighting networks.

Background technique

At present, urban road lighting is an important link related to the vital interests of the general public. It directly reflects the construction level and spiritual outlook of the city. The control and management level of street lights shows the modernization degree of the city. Therefore, ensuring the stable and reliable operation of urban street lights plays an important role in urban security, urban beautification, night traffic and urban civilization construction, and provides an important guarantee for urban people's life and economic activities; and for improving the investment environment and attracting foreign investment, It plays a very important role in promoting economic development.

With the development of my country's economic construction, the acceleration of urbanization and the rapid development of transportation, cities and urban road lighting have made great progress. In response to the increasing energy demand and consumption in the development of urban and urban road lighting, as well as light pollution and other issues, the Ministry of Construction, together with the National Development and Reform Commission, the Ministry of Science and Technology and other departments, vigorously promoted green lighting projects, and achieved significant economic and social benefits. However, on the whole, the green lighting of cities and traffic has just started, and the development is uneven. There are still many problems and weak links. For example, the macro guidance of urban and urban road lighting is not strong enough, and the relevant supporting systems are not perfect. Problems such as low efficiency, high energy consumption, and light pollution are still prominent. The quality and level of lighting has become an important symbol to measure the sustainable development of social modernization and human society progress.

With the popularization of intelligent buildings in China, intelligent lighting control systems are rapidly entering China. The main technologies used in domestic street lighting systems are: centralized energy-saving control in the Taiwan area, which controls the power of the entire lighting line, and cannot control every street light. The actual power of the actual power does not belong to the fine-grained on-demand control, that is, it cannot overcome the power difference of the single lamp at the head end of the line and the end of the line, nor can it guarantee the consistency of the illuminance of the entire line; The power control of a single lamp is carried out independently, which belongs to refined on-demand control, and realizes the single lamp control based on latitude and longitude, but the control strategy is not flexible, and the abnormal scene is not considered enough; the remote control is controlled by the remote control platform, which relies too much on the remote system. In the case of poor communication signals, it is impossible to make a timely control strategy within the effective time; manual abnormal patrol lights, and manual identification methods are used for abnormal street light inspections, so manual detection errors are large, the operation time is long, the investigation is difficult, and the labor cost is high. Large investment, single investigation.

Aiming at the problem of poor flexibility of lighting network control in the related art, no effective solution has been proposed yet.

Utility model content

The main purpose of the present utility model is to provide a control system for a lighting network, so as to at least solve the problem of poor flexibility of lighting network control in the related art.

In order to achieve the above purpose, the utility model provides a control system for lighting network. The control system for the lighting network includes: a single lamp control device, which is used to control the single lamp to perform a preset operation for a preset time period according to a control command for performing control on the single lamp; a centralized controller, connected to the single lamp control device , used to receive status information when a single lamp performs a preset operation; and a monitoring system, connected to a centralized controller, used to adjust control commands according to the status information, and the centralized controller is used to provide communication between the monitoring system and the single lamp control device channel for data transmission.

Further, the centralized controller includes: a WEB application system, used to provide a mobile terminal-based control interface; a WIFI module, connected to the WEB application system, used to establish a wireless connection with the mobile terminal, and the mobile terminal is used to pass through the centralized controller Perform control and debugging on single lamps.

Further, the single-lamp control device includes: a first reporting mechanism, configured to report abnormal information indicating abnormal operation of a single lamp, and the status information includes abnormal information.

Further, the single lamp control device further includes: an alarm mechanism, which is used to send out alarm information according to abnormal information, and perform early warning analysis on abnormal information.

Further, the single lamp control device includes: a second reporting mechanism, which is used to report the operation data of the single lamp to the cloud server, and the cloud server is used to perform analysis on the calculation results through a preset analysis model, and the calculation results are provided by the cloud server through preset The algorithm performs calculations on the operating data of a single lamp.

Further, the control system also includes: a brightness sensor, used to collect brightness data representing the brightness around the single lamp; and a background server, connected to the brightness sensor, used to send according to the brightness data to control the execution of the single lamp. Control command for lighting operation or lighting operation.

Further, the single-lamp control device includes: a receiving mechanism for receiving preset information sent by the centralized controller; and an analyzing mechanism connected with the receiving mechanism for analyzing the preset information to obtain control commands.

Further, the centralized controller includes: a first communication mechanism, connected to the receiving mechanism, for transmitting preset information to the receiving mechanism through WPLC/Ethernet.

Further, the single-lamp control device includes: a sending mechanism, configured to send the status information of the single lamp to the centralized controller through the WPLC.

Further, the centralized controller includes: a second communication mechanism, connected to the monitoring system, for receiving control commands issued by the monitoring system and uploading status information of the single lamp through GPRS/CDMA communication.

In an embodiment of the present invention, a control command for controlling a single lamp is obtained, wherein the lighting network includes multiple single lamps; the single lamp is controlled to perform a preset operation for a preset time period according to the control command; and the single lamp is sent The status information when performing preset operations is sent to the centralized controller, wherein the centralized controller is used to forward the status information to the monitoring system, and the monitoring system is used to adjust the control command according to the status information, which solves the problem of poor flexibility of lighting network control in the related art Problems, and then achieve the effect of improving the flexibility of lighting network control.

Description of drawings

The accompanying drawings constituting a part of this application are used to provide a further understanding of the utility model, and the schematic embodiments of the utility model and their descriptions are used to explain the utility model, and do not constitute an improper limitation of the utility model. In the attached picture:

Fig. 1 is a schematic diagram of a control system for a lighting network according to an embodiment of the present invention;

Fig. 2 is a schematic diagram of another control system for a lighting network according to an embodiment of the present invention;

Fig. 3 is a schematic diagram of a lighting scheme based on a time period of a single lamp controller according to an embodiment of the present invention;

Fig. 4 is a schematic diagram of another lighting scheme of a single lamp controller based on a time period according to an embodiment of the present invention;

Fig. 5 is a schematic diagram of another lighting scheme based on a time period of a single lamp controller according to an embodiment of the present invention; and

Fig. 6 is a schematic diagram of quantifying the operating data of a single lamp according to an embodiment of the present invention.

detailed description

It should be noted that, in the case of no conflict, the embodiments in the present application and the features in the embodiments can be combined with each other. The utility model will be described in detail below with reference to the accompanying drawings and in conjunction with the embodiments.

In order to enable those skilled in the art to better understand the solution of the present application, the technical solution in the embodiment of the application will be clearly and completely described below in conjunction with the accompanying drawings in the embodiment of the application. Obviously, the described embodiment is only It is an embodiment of a part of the application, but not all of the embodiments. Based on the embodiments in this application, all other embodiments obtained by persons of ordinary skill in the art without creative efforts shall fall within the scope of protection of this application.

It should be noted that the terms "first" and "second" in the specification and claims of the present application and the above drawings are used to distinguish similar objects, but not necessarily used to describe a specific order or sequence. It should be understood that the data so used may be interchanged under appropriate circumstances for the embodiments of the application described herein. Furthermore, the terms "comprising" and "having", as well as any variations thereof, are intended to cover non-exclusive inclusion, e.g. a system, product or device comprising a series of elements need not be limited to those elements explicitly listed, but may instead Includes other units not expressly listed or inherent to the product or equipment.

The embodiment of the utility model provides a control system for a lighting network.

Fig. 1 is a schematic diagram of a control system for a lighting network according to an embodiment of the present invention. As shown in FIG. 1 , the control system for a lighting network includes: a single lamp control device 10 , a centralized controller 20 and a monitoring system 30 .

The single lamp control device 10 is configured to control the single lamp to perform a preset operation for a preset time period according to a control command for performing control on the single lamp.

The single lamp control device 10, that is, the single lamp controller, is used to receive a control command for controlling a single lamp, and has a preset address in the lighting network, and the single lamp is a lighting lamp in the lighting network. Optionally, the single lamp control device 10 remotely controls the single lamp according to the control command. The single-lamp control device 10 controls a single lamp to perform a preset operation for a preset time period according to a control command, and can receive preset information including a control command, analyze the preset information, obtain a control command, and control the single lamp according to the preset operation. The control rules for control control the single lamp in a planned way. For example, in bad weather, due to communication problems between devices, the communication is blocked, but the single lamp control device 10 can still control the single lamp according to the control command to execute the preset time. The preset operation for the segment. Among them, the preset time period is the time period for controlling the single lamp according to the plan, so that the single lamp can work within the effective time, and the preset operation is the operation corresponding to the preset time period, for example, multiple single lamp control The device 10 controls multiple single lamps to perform preset operations within a preset time period, and the multiple single lamp control devices 10 correspond to multiple single lamps one by one, and the multiple single lamps as a whole realize full-on and full-off within a preset time period , Interval lighting, 1/3 lighting, big and small snake lighting and other operations can realize flexible configuration for scenes such as intersections and T-shaped intersections, so as to realize the multi-strategy operation purpose of single-light control, achieve diversified lighting effects, and avoid It eliminates the shortage of centralized energy-saving control in the station area that cannot control the actual power of each single lamp, and also avoids the defects of inflexible single lamp control strategy and insufficient consideration of abnormal scenes.

The centralized controller 20 is connected with the single lamp control device 10, and is used for receiving status information when the single lamp performs a preset operation.

The centralized controller 20 is connected with the single lamp control device 10 and can transmit information to the single lamp control device 10 . During the process of performing preset operations for a single lamp, status information such as operating status will be generated, such as status information of normal operation or status information of operating faults, etc., and the centralized controller 20 receives the status information when a single lamp performs preset operations . Optionally, when the status information is information in an emergency situation, for example, when the power supply fails and cannot supply power normally, the centralized controller 20 actively sends the status information that the power supply fails and cannot supply normal power.

The centralized controller 20 forwards the control command for controlling a single lamp to the single lamp control device 10, and may forward the control command to the single lamp control device 10 corresponding to the preset address according to the preset address. Optionally, the centralized controller 20 transmits information such as preset addresses and control commands to the single lamp controller 10 through wide area power line carrier (WPLC) communication/Ethernet, if the preset address received by the single lamp controller 10 is different from itself corresponding to the address, then the single-lamp controller 10 executes a preset operation within a preset time period according to the received control command.

The monitoring system 30 is connected with the centralized controller 20 and is used to adjust the control command according to the status information.

The monitoring system 30 , that is, the monitoring center, and the single lamp controller 10 perform information transmission through the centralized controller 20 . After the centralized controller 20 receives the status information when the single lamp executes the preset operation, the centralized controller 20 sends the status information to the monitoring system 30, and the monitoring system 30 obtains the operating status of the single lamp in real time according to the status information, and adjusts the control command in time. Then adjust the operating parameters of the single lamp controller 10, such as the time parameters for performing the lighting operation, the time parameters for performing the extinguishing operation, etc. The monitoring system 30 is also used for strategy generation and comprehensive analysis of abnormal data. The centralized controller 20 is used to provide a data transmission channel between the monitoring system 30 and the single lamp control device 10 .

Optionally, the monitoring system 30 receives the status information of a single lamp sent by the centralized controller 20, and can selectively adjust the command according to the useful status information, while ignoring the useless status information, for example, for the The fault information of a single lamp is ignored, which avoids the problem of heavy processing burden and reduced processing efficiency caused by the monitoring system 30 adjusting control commands for any state information.

The monitoring system 30 sends preset information including control commands to the centralized controller 20, and the centralized controller 20 forwards the preset information to the single lamp controller 10, and the single lamp controller 10 performs analysis on the preset information to obtain the control command, Execute a preset operation within a preset time period according to the control command.

Optionally, the monitoring system 30 realizes remote communication with the single lamp controller 10 through a general packet radio service (General Packet Radio Service, GPRS) wireless network and WPLC/Ethernet communication technology, to complete the switch control of the single lamp and Monitor information such as abnormal operation, and then realize the maintenance of the lighting strategy of a single lamp, which improves the flexibility of lighting network control.

In this embodiment, the single lamp control device 10 controls the single lamp to perform preset operations for a preset period of time according to the control command for single lamp execution control, and the centralized controller 20 is connected to the single lamp control device 10 to receive the execution time of the single lamp. The status information during preset operation is connected to the centralized controller 20 through the monitoring system 30 to adjust the control command according to the status information, which improves the flexibility of lighting network control.

Optionally, the centralized controller includes: a web page (WEB) application system for providing a mobile terminal-based control interface; a wireless fidelity (Wireless-Fidelity, WIFI for short) module connected to the WEB application system for Establish a wireless connection with the mobile terminal, and the mobile terminal is used to control and debug the single lamp through the centralized controller.

This embodiment can realize the local control of the mobile terminal, that is, install the WEB application system and the WIFI module in the local centralized controller, and the mobile terminal can directly control and debug the single lamp through the local WIFI connection. The control interface for controlling the single lamp can control and operate the single lamp in real time, obtain the running status of the single lamp in real time, and quickly obtain the fault information of the single lamp, so as to quickly maintain the single lamp and avoid the fault caused by the single lamp. Faults cannot be found in time and lead to bad faults, which improves the safety of single lamp operation, avoids the problems of large manual detection errors, long operation time, difficult troubleshooting, large labor costs, and single troubleshooting. Flexibility of single light control.

Optionally, the single-lamp control device includes: a first reporting mechanism, configured to report abnormal information indicating abnormal operation of the single lamp, and the status information includes abnormal information.

The single lamp generates status information during operation, and the status information includes abnormal information that occurs during the operation of the single lamp. The single-lamp control device reports the abnormality information for indicating the abnormal operation of the single lamp through the first reporting mechanism. Optionally, the single-lamp control device sets a preset threshold, and when it detects that the operating data of the single lamp exceeds the preset threshold, it determines that the single lamp is abnormal, and reports the abnormal information indicating the abnormal operation of the single lamp to the centralized controller, The abnormal information is forwarded to the monitoring system through the centralized controller, that is, the abnormal information is reported to the master station. The abnormality information may be information such as: abnormal switch lights, ghost lights, abnormal current and the like.

Optionally, the single lamp control device further includes: an alarm mechanism, configured to issue alarm information based on abnormal information, and perform early warning analysis on abnormal information.

When a single lamp is abnormal during operation, that is, the single lamp is working in an abnormal state, the single lamp control device can send an alarm message according to the abnormal information through the alarm mechanism, thereby prompting the maintenance personnel that there is an error during the operation of the single lamp. At the same time, early warning analysis is carried out on the abnormal information to determine the cause of the abnormality of the single lamp, so as to take corresponding maintenance and repair measures for the single lamp to avoid the abnormality of the single lamp during operation and affect the lighting plan.

Optionally, the single-lamp control device includes: a second reporting mechanism, configured to report the operating data of the single lamp to the cloud server, the cloud server is used to analyze the calculation results through a preset analysis model, and the calculation results are provided by the cloud server through preset The design method is calculated by performing calculations on the operating data of a single lamp.

The operating data of the single lamp during the working process, including the operating parameters of the single lamp, is reported to the cloud server through the second reporting mechanism, and the cloud server collects the operating data of the single lamp in real time, and calculates the calculation result of the data within the configuration range through the platform configuration calculation According to the statistics, the single lamp can be controlled and debugged according to the calculation results. The operating data can be the number of centralized controllers in the lighting network, the number of single lamp controllers, the number of centralized controllers in operation, the number of events, the number of installed meters, Number of events processed, also includes weather data, etc. Optionally, the cloud server is a part of the monitoring system.

Optionally, the monitoring system also includes: a brightness sensor and a background server. Among them, the brightness sensor is used to collect the brightness data used to represent the brightness around the single lamp; the background server is connected to the brightness sensor and used to send the information for controlling the single lamp to perform the operation of turning on or off the light according to the brightness data. control commands.

The brightness sensor is used to sense the brightness around the single lamp, and collect brightness data used to represent the brightness around the single lamp. For example, the brightness around a single lamp will change when it is dawn or when the sky is off. The brightness sensor collects brightness data and sends the brightness data to the background server. The background server comprehensively analyzes the brightness data to determine whether the single lamp should be turned on or off. Light operation, etc., send control commands corresponding to light-on operation and light-off operation, and realize sending control commands for controlling a single lamp to perform light-on operation or light-off operation according to brightness data.

Optionally, the single lamp control device includes: a receiving mechanism and an analyzing mechanism. Wherein, the receiving mechanism is used to receive the preset information sent by the centralized controller; the analyzing mechanism is connected to the receiving mechanism and used to analyze the preset information to obtain control commands.

The single-lamp control equipment is connected to the centralized controller, and the centralized controller is connected to the monitoring system. The centralized controller receives the preset information issued by the monitoring system. The preset information includes the address information of the single-lamp controller and the The control command to control the lamp. The centralized controller forwards the preset information to the single-lamp control device corresponding to the preset information according to the address information, the single-lamp control device receives the preset information through the receiving mechanism, analyzes the preset information through the analyzing mechanism, and obtains the control command, and then Execute a preset operation within a preset time period according to the control command.

Optionally, the centralized controller includes: a first communication mechanism, connected to the receiving mechanism, for transmitting preset information to the receiving mechanism through WPLC/Ethernet.

After receiving the preset information issued by the monitoring system, the centralized controller transmits the preset information to the receiving mechanism of the single lamp controller through the first communication mechanism through WPLC/Ethernet. The first communication mechanism can send the preset information to the single lamp control device with the WPLC downlink signal of 25 bits/s.

Optionally, the single lamp control device includes: a sending mechanism, configured to send the state information of the single lamp to the centralized controller through the WPLC.

The single lamp generates status information during operation, and the single lamp control device sends the status information of the single lamp to the centralized controller through the sending mechanism. The sending mechanism can send the status information to the centralized controller with WPLC uplink signal 25bit/s. After the centralized controller receives the status information, it can analyze the status information, and actively send the analyzed information to the monitoring system through the GPRS uplink signal.

Optionally, the centralized controller includes: a second communication mechanism, connected to the monitoring system, for receiving control commands issued by the monitoring system and uploading them through GPRS/code division multiple access (Code Division Multiple Access, referred to as CDMA) communication Status information of a single lamp.

GPRS/CDMA communication mode is adopted between the centralized controller and the monitoring system. The monitoring system sends control commands to the centralized controller, that is, the monitoring system sends communication downlink signals, and the centralized controller communicates to the single lamp through WPLC/Ethernet. The device transmits information such as address information and control commands. The lighting network includes multiple single lamp controllers, each single lamp controller corresponds to address information, and the single lamp controller corresponding to the address information analyzes the information to obtain the control command, and executes the preset time period according to the control command operate. The single lamp controller sends the status information of its own operating status to the centralized controller, and the centralized controller actively sends the status information through the second communication mechanism. The monitoring system adjusts the control command according to the status information, which improves the flexibility of lighting network control.

The control system of the lighting network of the present invention will be described below in combination with preferred embodiments.

Fig. 2 is a schematic diagram of another control system for a lighting network according to an embodiment of the present invention. As shown in Figure 2, the control system of the lighting network includes a monitoring center, two sets of centralized controllers and two sets of single lamp controllers 1, 2, 3 to n.

The monitoring center, that is, the control center management system, adopts GPRS/CDMA communication mode between the monitoring center and the centralized controller, and the monitoring center sends commands to the centralized controller (communication downlink signal), and the centralized controller communicates to The single lamp controller (WPLC downlink signal 25bits/s) transmits information such as addresses and control commands. The single lamp controller analyzes the information and obtains the control commands. According to the control commands, the single lamp is controlled to perform preset operations for a preset time period, such as , two groups of single lamp controller 1, single lamp controller 2, single lamp controller 3 to single lamp controller n corresponding to multiple single lamps are all on, all off, interval on, 1/3, big and small snakes on. The single lights in each station area are divided into multiple logical groups, which can be flexibly configured for various scenarios such as intersections and T-shaped road ends, and realize single-light control and multi-strategy operation. The monitoring center also includes application software, SMS alarm applications, and other applications. system.

The single lamp controller sends information such as the running status of its own preset operation within the preset time period to the centralized controller (WPLC uplink signal 25bits/s). After the centralized controller analyzes the corresponding signal, it actively sends the analyzed information to the monitoring center. information, such as sending information in emergency situations (GPRS uplink signal). The monitoring center selectively processes the information reported by the centralized controller, avoiding the processing of useless information.

In the monitoring center, you can know the operating conditions of the two sets of single lamp controller 1, single lamp controller 2, single lamp controller 3 to single lamp controller n in real time, and adjust the control system of the lighting network and single lamp control in time. The operating parameters of the device. With the help of GPRS wireless network and WPLC/Ethernet communication technology to realize remote communication, complete the switch control of single lamp, the collection of abnormal accident information of lamps and the maintenance function of lighting strategy.

This embodiment adopts diversified lighting, sets the control strategy corresponding to the preset operation locally, introduces a single lamp controller, and realizes the fancy way that each single lamp of the system executes according to the plan through the remote control of the single lamp. Turn on the lights, even if there is a communication problem with the device in bad weather, the single lights corresponding to the two sets of light controller 1, single light controller 2, single light controller 3 to single light controller n can be executed according to the plan When the light is on, the execution effect of the local pre-store is realized.

Abnormalities may occur during the operation of a single lamp, and it is necessary to analyze the abnormal brightness of the single lamp. Lighting abnormality analysis includes two methods: one is to pre-set the preset threshold value for the equipment including a single lamp, compare the data monitored by the equipment since its operation with the preset threshold value, obtain the comparison result, and determine the value based on the comparison result. Whether the operating state of the single lamp is abnormal, if it is determined that the operating state of the single lamp is abnormal, report the abnormal state to the monitoring center, and the monitoring center adjusts the control command according to the abnormal state. The second is abnormal monitoring of cloud big data analysis. A single lamp reports data in real time, and the remote cloud platform collects device operation data in real time. Through platform configuration calculations, the calculation results of data within the configuration range are calculated. In order to achieve the purpose of analyzing the abnormality of the equipment.

The local control of the mobile terminal is to install the WEB application system and WIFI module in the local concentrator. The mobile device is connected through the local WIFI to directly control and debug the device, avoiding large errors in manual detection, long operation time, difficult investigation, and manpower. The cost is large, and a single problem is checked.

The control system for the lighting network in this embodiment collects the surrounding lights of two sets of single lamp controller 1, single lamp controller 2, single lamp controller 3 to single lamp controller n corresponding to the single lamp through the brightness sensor. Brightness data for brightness. And through the comprehensive analysis of the background server, the strategy of turning on/off the lights corresponding to the two groups of single-lamp controller 1, single-lamp controller 2, single-lamp controller 3 to single-lamp controller n is obtained, to achieve It has the effect of improving the flexibility of lighting network control.

Fig. 3 is a schematic diagram of a time-segment-based lighting scheme of a single lamp controller according to an embodiment of the present invention. As shown in FIG. 3 , the time-segment-based lighting schemes of the single lamp controller include scheme 1 and scheme 3-test. For the time period from 16:00 to 22:00, the single light controller controls the corresponding single light to perform the operation of turning on or off the light according to scheme 1, and the main light 1 can be fully turned on; for 22:00 to 08:00 During the period of time, the single lamp controller controls the corresponding single lamp to perform the operation of turning on or off the light according to the scheme 3-test. The effect of the flexibility of lighting network control.

Fig. 4 is a schematic diagram of another time-segment-based lighting scheme of a single lamp controller according to an embodiment of the present utility model. As shown in Figure 4, this embodiment is used to test the monitoring center, including background C test physical concentrator and java test. Among them, the background C tests the physical concentrator, and the control duration can be set to 15 minutes. The node 1 loop includes the action of opening and closing the loop, and the node 2 includes the action of opening and closing the loop. Execute the release operation and call test operation; java test, the control duration can be set to 15 minutes, the node 2 loop includes the action of opening and closing the loop, and the node 2 includes the action of opening and closing the loop, and can also perform the operation of turning on the lights and turning off the lights Light operation, release operation, call test operation, among which, call test refers to obtain the status information of a single light, so as to achieve the effect of flexibility in lighting network control.

Fig. 5 is a schematic diagram of another time-segment-based lighting scheme of a single lamp controller according to an embodiment of the present utility model. As shown in Figure 5, the control of street lamps includes common control, custom control and individual control. Among them, the number of street lamps in one group is 4, the number of lamp heads is 8, and the control time is set to 15 minutes. For commonly used controls, include A plan and B plan. Among them, scheme A turns on the main light and turns off the auxiliary lights, scheme B turns on the auxiliary lights and turns off the main light, and the energy saving rate reaches 80%. After receiving the touch signal of the "execute" button, the corresponding scheme is executed, thereby achieving the effect of flexibility in lighting network control.

Fig. 6 is a schematic diagram of quantifying the operating data of a single lamp according to an embodiment of the present invention. As shown in Figure 6, the operation data of a single lamp is quantified using a big data analysis platform to display the operation overview of the lighting network and the online overview of the centralized controller. Select the management area, for example, Beijing, the number of centralized controllers is 2, the number of single lamp controllers is 86, the number of centralized controllers is 2, the number of events is 0, and the number of installed meters is 2, and the number of processed events is 0. It also displays today's weather, for example, today is sunny, the temperature is 8-4 degrees Celsius, the north wind is 3-4, the latitude and longitude is 114.49|38.05, the sunrise time is 7:12, the sunset time is 17:59, etc. Controller online overview, including the overview of data 1 to data 5 of the centralized controller.

The preset operations performed by the single lamp controller in this embodiment during the preset time period are lighting schemes and plans based on time periods, including daily schemes and plans, holiday schemes and plans. The types of lighting schemes include all-on, all-off, interval-on, 1/3-on, big and small snake-on, etc. of multiple single lights. The single lights in each station area are divided into multiple logical groups, which can be flexibly configured for various scenes such as intersections and T-shaped road ends, and the control operation is simple and fast, thus realizing the multi-strategy operation of single light control.

This embodiment conducts abnormal analysis and statistics on street lamps, uses a big data analysis platform to quantify the single lamp data collected in real time, analyzes the abnormal state of the lamp head of the street lamp by establishing an effective data model, and timely reports the abnormal state of the street lamp. Early warning analysis plays a good guiding role in manual light patrol, shortens the light patrol time, reduces the light patrol process, and effectively saves costs.

This embodiment also realizes light-sensing intelligent light on/off, collects brightness data for representing the surroundings of a single light through the brightness sensor, and then comprehensively analyzes the brightness data through the background to obtain a light on/off strategy.

The embodiments shown in Figures 3 to 6 can be controlled locally based on the mobile terminal. The local control terminal has a built-in WEB server, and the hardware product has a WIFI wireless transmission module. Ordinary smart terminals can be used locally to realize temporary control of the lighting network and on-site troubleshooting , on-site debugging, and parameter configuration and other functions, so that the local control and debugging work can be completed smoothly, making the local control and debugging more convenient, and it can also be used without a network. The big data analysis platform quickly processes and analyzes the collected data through various analysis models, which can play a good guiding role in manual light patrol, shorten the light patrol time, reduce the light patrol process, and greatly save labor costs.

The embodiments shown in Figure 3 to Figure 6 realize the lighting scheme and plan based on the time period, the single lamp controller controls the operation of a single lamp with multiple strategies, the local control terminal has a built-in WEB server, and the hardware product has a WIFI wireless transmission module. It has the function of alarming and early warning analysis of abnormal state of street lamps and the function of light-sensing intelligent on/off lights, which achieves the effect of improving the flexibility of lighting network control.

The above descriptions are only preferred embodiments of the utility model, and are not intended to limit the utility model. For those skilled in the art, the utility model can have various modifications and changes. Any modification, equivalent replacement, improvement, etc. made within the spirit and principles of the present utility model shall be included in the protection scope of the present utility model.

Claims (10)

1. a kind of control system for lighting mains is it is characterised in that include：

Single lamp control equipment, for controlling described single lamp to execute preset time period according to the control command that the execution of single lamp is controlled Predetermined registration operation；

Centralized Controller, is connected with described single lamp control equipment, for receiving when described single lamp executes described predetermined registration operation Status information；And

Monitoring system, is connected with described Centralized Controller, for adjusting described control command according to described status information, described Centralized Controller is used for providing the channel of the data transfer between described monitoring system and described single lamp control equipment.

2. control system according to claim 1 is it is characterised in that described Centralized Controller includes：

WEB application system, for providing the operation and control interface based on mobile terminal；

WIFI module, is connected with described WEB application system, is wirelessly connected for setting up with described mobile terminal, described movement Terminal is used for by described Centralized Controller, described single lamp being executed and controls and debug.

3. control system according to claim 1 is it is characterised in that described single lamp control equipment includes：

First reports mechanism, and for reporting the abnormal information for indicating described single lamp operation exception, described status information includes Described abnormal information.

4. control system according to claim 3 is it is characterised in that described single lamp control equipment also includes：

Alarm mechanism, for according to described abnormal information alert, and carries out early warning analysis to described abnormal information.

5. control system according to claim 1 is it is characterised in that described single lamp control equipment includes：

Second reports mechanism, and for reporting the service data of described single lamp to Cloud Server, described Cloud Server is used for by pre- If analysis model executes analysis to result of calculation, described result of calculation passes through preset algorithm to described single lamp by described Cloud Server Service data execution be calculated.

6. control system according to claim 1 is it is characterised in that described control system also includes：

Brightness impression device, for collection for representing the brightness data of single lamp surrounding brightness；And

Background server, is connected with described brightness impression device, for being sent for controlling described list according to described brightness data Lamp executes the control command of bright light operation or operation of turning off the light.

7. control system according to claim 1 is it is characterised in that described single lamp control equipment includes：

Receiving mechanism, for receiving the presupposed information that described Centralized Controller sends；And

Analytical mechanism, is connected with described receiving mechanism, for executing parsing to described presupposed information, obtains described control and orders Order.

8. control system according to claim 7 is it is characterised in that described Centralized Controller includes：

First communication means, are connected with described receiving mechanism, for transmitting institute by WPLC/ Ethernet to described receiving mechanism State presupposed information.

9. control system according to claim 1 is it is characterised in that described single lamp control equipment includes：

Transmitting mechanism, for sending the status information of described single lamp by WPLC to described Centralized Controller.

10. control system according to claim 1 is it is characterised in that described Centralized Controller includes：

Second communication means, are connected with described monitoring system, for by under monitoring system described in GPRS/CDMA communications reception The control command sent out and the status information uploading described single lamp.