CN116647970A - Light control system - Google Patents

Abstract

The application relates to the technical field of light control, in particular to a light control system, which comprises: the digital model twin module is used for simulating coal preparation plants, equipment and lamps in reality; the model display module is used for displaying the position of the patrol personnel and the light irradiation range; the personnel positioning module is used for positioning three-dimensional coordinates of the patrolling personnel in real time; the digital model positioning module based on the GIS technology is used for carrying out coordinate positioning on the corners in the coal preparation plant, the four corners of each device and the central point position of each lamp; combining a personnel positioning module with a GIS, wherein the digital model positioning module and the personnel positioning module use a unified coordinate system; the light management module comprises a light control module and a light binding module; the light control module is used for receiving the data of the track prediction module and controlling the light; the track prediction module is used for predicting the action track of the patrol personnel, predicting the patrol area according to the specific position of the patrol personnel and sending the data to the light control module.

Description

Light control system

Technical Field

The application relates to the technical field of light control, in particular to a light control system.

Background

The traditional metal halogen lamps are adopted in the coal mine coal preparation factory, the quantity is large, the lighting effect is poor, the maintenance cost is high, the energy consumption is large, and the on-site lighting system is manually controlled by a dispatching room inspection staff and cannot realize on-demand lighting. And the automation degree of the coal preparation plant is high, the staff at stations is few, the plant area is large, and the lamp can be automatically turned down or turned off when the patrol staff leaves the patrol area, so that the purposes of energy conservation and emission reduction are achieved. In the running process of equipment in a coal preparation plant, the equipment has larger noise, a simple sound control switch is greatly disturbed, and an intelligent light control system needs to be developed, so that the intelligent light control system is an important mode for saving energy and reducing consumption. The light switch is controlled according to the combination of the accurate personnel positioning system and the GIS technology, and the working mode of 'people coming to light and people going to light off' is realized on the premise of ensuring the illumination requirement, so that the energy conservation, consumption reduction, cost reduction and efficiency enhancement of the coal mine are ensured.

Disclosure of Invention

The application provides a lamplight control system for solving the problems of high field illumination maintenance cost and high energy consumption.

In a first aspect, the present application provides a light control system comprising:

the digital model twinning module is used for simulating coal preparation plants, equipment and lamps in reality;

the model display module is used for displaying the position of the patrol personnel and the light irradiation range;

the personnel positioning module is used for positioning three-dimensional coordinates of the patrolling personnel in real time;

the digital model positioning module is based on a GIS technology and is used for carrying out coordinate positioning on eight corners of each factory building space, four corners of each device projected in the vertical direction and the position of each lamp center point in a coal preparation factory, wherein the coordinate positioning is a three-dimensional coordinate;

the digital model positioning module and the personnel positioning module use a unified coordinate system, the accurate personnel positioning system is combined with a GIS technology, and the specific position of the patrol personnel is obtained by comparing the three-dimensional coordinates of the digital model positioning module and the personnel positioning module;

the light management module comprises a light control module and a light binding module; the light control module is used for receiving the data of the track prediction module and controlling light;

the track prediction module is used for collecting data of the digital model positioning module and the personnel positioning module so as to predict action tracks of the patrols, acquiring the patrols of the patrols and real-time speeds of the patrols, predicting the patrols behind the patrols according to specific positions of the patrols, and sending the data to the light control module.

According to one aspect of the application, the light binding module comprises an area management module and an equipment management module;

the region management module is used for carrying out region division on the digital model twin module, marking a region range in the model display module and binding all lamps in the region according to the region division;

the device management module is used for carrying out device division on the digital model twin module, marking the device range in the model display module and binding all lamps in the device according to the device division.

According to one aspect of the application, the light control module has four modes, wherein the first mode is to automatically turn on lamps around the patrol personnel or to adjust the brightness of the lamps around the patrol personnel according to the position of the patrol personnel;

the second mode is that when the patrol personnel are in a certain area, the lamps bound in the area are turned on or the brightness of the lamps is increased;

the third mode is that when the patrolling personnel are in the range of the equipment, the lamp bound by the equipment is turned on or the brightness of the lamp is turned on;

and the fourth mode is to automatically turn off the lamp or reduce the brightness of the lamp after the inspection of the inspection personnel is finished.

According to one aspect of the application, the personnel positioning module comprises a wireless coding transmitter, a data acquisition control device, a data transmission network, a ground center software system and a server, wherein the wireless coding transmitter is used for transmitting a radio frequency signal representing the identity information of the patrolling personnel;

the acquisition control equipment is used for receiving the data of the wireless coding transmitter and uploading the data to the ground center software system through the data transmission network;

the personnel positioning module further comprises a receiving and processing module, wherein the receiving and processing module is used for analyzing and processing the position information of the patrol personnel, and analyzing, deciding the starting and stopping of the lamplight and adjusting the brightness according to the position information.

According to one aspect of the application, the model display module is further used for displaying the number of people and any person position in real time;

the model display module also displays information such as the number and the use amount of the integral lighting lamps, the states of the lamps, the field distribution and the like, and counts the power consumption;

in the model display module, the area with light illumination is light-colored, and the area without light illumination is dark-colored, and the model display module is used for checking real-time recording data and historical recording data of the camera.

According to one aspect of the application, the personnel positioning module comprises a wireless coding transmitter, a data acquisition control device, a data transmission network, a ground center software system and a server, wherein the wireless coding transmitter is used for transmitting a radio frequency signal representing the identity information of the patrolling personnel;

the acquisition control equipment is used for receiving the data of the wireless coding transmitter and uploading the data to the ground center software system through the data transmission network.

According to one aspect of the application, the system further comprises a personnel information management module, wherein the personnel information management module is used for managing and setting personnel information in real time, modifying and storing information such as names and the like, and tracing, inquiring, classifying, counting and storing the activity tracks of the patrolling personnel.

According to one aspect of the application, the system further comprises a hierarchical management and alarm module, wherein the hierarchical management and alarm module is used for multi-level login, multi-level control and monitoring of lamps, and if a certain lamp is offline, the hierarchical management and alarm module automatically performs audible and visual alarm and uploads lamp position information.

In order to solve the above problems, the present application further provides an electronic device, which is characterized by comprising a processor, a memory, and a computer program stored in the memory and capable of running on the processor, wherein the computer program when executed by the processor implements a light control system as described above.

In order to solve the above-mentioned problems, the present application further provides a computer readable storage medium, wherein the computer readable storage medium stores a computer program, and the computer program when executed by a processor implements a light control system as described above.

In order to solve the problems of high field illumination maintenance cost and large energy consumption, the application has the following advantages:

the application provides g a light control system, wherein three-dimensional coordinates of a patrol person are obtained in real time through a person accurate positioning system, the three-dimensional coordinates of the patrol person are combined with a three-dimensional model of a factory building by utilizing a GIS technology, a specific floor and a specific region where the patrol person is located are obtained, the light of the region where the patrol person is located is controlled to be turned on through the control system, and the light is turned off after the patrol person leaves, so that automation and intellectualization of light control are realized, energy consumption is reduced, and energy saving and economic benefits of a coal preparation factory are improved.

Drawings

Fig. 1 shows a flow chart of a light control system.

Detailed Description

The disclosure will now be discussed with reference to several exemplary embodiments. It should be understood that these embodiments are discussed only to enable those of ordinary skill in the art to better understand and thus practice the present disclosure, and are not meant to imply any limitation on the scope of the present disclosure.

As used herein, the term "comprising" and variants thereof are to be interpreted as meaning "including but not limited to" open-ended terms. The term "based on" is to be interpreted as "based at least in part on". The terms "one embodiment" and "an embodiment" are to be interpreted as "at least one embodiment. The term "another embodiment" is to be interpreted as "at least one other embodiment".

The light control system has more application scenes, for example, the coal preparation plant has larger occupied area, the lamp needs are larger, more energy is required to be consumed if the light control system is started overnight, and the cost of the coal preparation plant is increased. Meanwhile, in order to ensure the fire safety of the coal preparation plant, patrol personnel are required to patrol in the coal preparation plant, however, the patrol personnel are required to manually turn on or off the light to reach the position of the lamp switch for operation after each patrol of a certain area, so that the time of the patrol personnel is wasted, the starting time of the lamp is increased, resources are wasted, and the cost is increased. Moreover, the patrol personnel need to personally test whether the lamp is damaged or not, and a unified checking system is not provided, so that the patrol efficiency is low, and the lamp is difficult to maintain. Therefore, in order to solve the problems of high field illumination maintenance cost and large energy consumption, the application provides a light control system:

in this embodiment, as shown in fig. 1, the light control system may include a digital model twinning module, a model display module, a person positioning module, a digital model positioning module, a light management module, and a trajectory prediction module.

The digital model twin module can be used for simulating a coal preparation plant model, an equipment model and an intelligent lamp model in reality. The coal preparation plant model can be constructed according to a specific structure of a plant space, wherein the plant space can comprise a dense medium workshop, a main car washing workshop and a drying workshop. The factory building structure is completely presented, so that the inspection personnel can conveniently inquire the factory building state, and the inspection personnel can be prevented from missing individual inspection spaces and equipment. The digital twin module building technology is not limited, and can be a building information model technology or an urban information model, and the specific technology is not limited.

The personnel positioning module can be used for positioning three-dimensional coordinates of the patrolling personnel in real time. And the real-time positioning of the patrol personnel is sent to the track prediction module, so that the patrol position of the patrol personnel can be conveniently checked, and accidents of the patrol personnel in the independent patrol process are prevented.

The digital model positioning module can be used for carrying out coordinate positioning on eight corners of each factory building space, four corners of each device projected in the vertical direction and the position of the central point of each lamp in the coal preparation factory. Since the building often has a multi-layer structure, the coordinate positioning is preferably a three-dimensional coordinate in order to more accurately represent the spatial positions of the equipment, the building and the lamps. The digital model positioning module may send the coordinate positioning to the trajectory prediction module.

The digital model positioning module and the personnel positioning module use a unified coordinate system, and the specific positions of the patrolling personnel can be obtained by comparing the three-dimensional coordinates of the digital model positioning module and the personnel positioning module. The floor where the patrol personnel are located is obtained by comparing the z coordinate of the position where the personnel are located with the z coordinate of each floor, and the specific area is respectively compared with the x coordinate and the y coordinate of each factory building by the x coordinate and the y coordinate of the position where the patrol personnel are located, so that the factory building where the personnel are located and the specific area of the factory building are obtained.

The model display module can be used for displaying the model constructed by the digital model twin module, and the position of the patrol personnel in the factory building is also provided with a light adjustment area, so that the state of the position of the patrol personnel can be displayed more conveniently and rapidly, and when accidents occur, other patrol personnel can quickly position the position of the patrol personnel for supporting. Further, the range in x meters around the patrolling personnel is a light adjusting area, and the brightness of the lamps in the range needs to be adjusted. x is 5 meters by default. The specific value of x is not limited and can be freely set according to practical situations.

The track prediction module can be used for collecting data of the digital model positioning module and the personnel positioning module so as to predict the action track of the patrol personnel, obtain the patrol track of the patrol personnel and the real-time speed of the patrol personnel, infer the patrol area behind the patrol personnel according to the specific position of the patrol personnel and send the data to the light control module, thereby adjusting the light and providing effective illumination for the patrol personnel. When the real-time positioning of the patrol personnel obtained by the track prediction module from the personnel positioning module stays in place for too long, an alarm can be sent to the digital model twinning module, and the real-time position of the patrol personnel is marked by using special colors or symbols in the digital model twinning module.

Further, the model display module can be combined with the predicted track obtained by the track prediction module, can predict the time when the patrolling personnel reach the light adjustment area, and sends the result to the light management module. And is set to assume that the patrolling personnel is about to reach the light adjustment area when the patrolling personnel will reach the area after y minutes. The value range of y is not limited, the default value is 3 minutes, and the user can set according to specific conditions.

The light management module can comprise a light control module and a light binding module, wherein the light control module is used for receiving the data of the track prediction module and controlling light.

According to other embodiments of the present application, the digital model twinning module may also be selectively amplified and labeled. The selection mode can be clicking on a computer screen through a mouse, or keyboard operation selection, and the specific operation mode is not limited. After the patrol personnel patrol the equipment and the space, the electronic equipment can check whether the missing space and the missing equipment exist or not, and the electronic equipment can be marked after the patrol is completed, so that repeated patrol or missing patrol is prevented, and the patrol efficiency of the patrol personnel is improved. The marking method can be to change the colors of the space and the equipment after inspection, or to add corresponding characters, and the specific mode is not limited here.

Further, the light binding module may include an area management module and a device management module. The region management module can be used for carrying out region division on the digital model twin module and marking out a region range in the model display module, and all lamps in the region are bound according to the region division. And a plurality of lamps can be bound in one area. When the patrolling personnel reach the regional scope, all lamps in the regional scope are lighted, and illumination is provided for the patrolling personnel.

In order to facilitate inspection of equipment by inspection staff, the equipment management module can be used for carrying out equipment division on the digital model twin module and marking the equipment range in the model display module, and all lamps in the equipment are bound according to the equipment division. When the patrolling personnel reach the equipment range, the lamps bound in the range are all lighted. Therefore, in the binding process of the lamps, one device and one region can correspond to a plurality of lamps, and the same lamp can be bound by the plurality of devices and the region.

The user may select one or more of the above-described management modules for application, without limitation.

The lamp can be turned on, turned off, adjusted to lower the brightness, adjusted to raise the brightness and other adjusting modes.

Further, to save energy, the light control module may have four modes:

the first mode is to automatically start the lamps around the inspector or to increase the brightness of the lamps around the inspector according to the position of the inspector. Other locations not reached by the patrolling personnel, the light fixture may remain low or off.

The second mode is that when the patrol personnel are in a certain area, the lamps bound in the area are turned on or the brightness of the lamps is regulated. When the individual space in the factory building is relatively open and no important equipment needs to be checked, the lamp can be bound with a certain space area. When the patrol personnel arrives or is predicted to arrive in the area according to the track, the brightness of the binding lamps in the area is adjusted to be high or closed, so that the patrol personnel can conveniently carry out simple patrol, the time of the patrol personnel is saved, and the patrol efficiency is improved.

The third mode is that when the patrolling personnel are in the range of the equipment, the lamp bound by the equipment is turned on or the brightness of the lamp is turned on. Often be provided with comparatively noble equipment in the factory building, when the inspection personnel reach equipment scope or predict when will reaching equipment scope according to the orbit, the lamps and lanterns luminance that this equipment bound is adjusted up or is opened in order to make things convenient for the inspection personnel to inspect equipment.

The fourth mode is to automatically turn off the lamp or reduce the brightness of the lamp after the inspection of the inspector is finished, namely, the lamp is not in the light adjusting range or the inspector leaves the equipment range and the area range.

According to the four modes, the purposes of lighting by people and turning off by people of the light control system can be achieved, automatic management of light is achieved, and the effect of saving energy is achieved.

Further, the personnel positioning module may include a personnel accurate positioning system, and the accurate positioning system may include a wireless code transmitter, a data acquisition control device, a data transmission network, a ground center software system and a server, for accurately positioning and identifying the patrol personnel.

The wireless coding transmitter is used for transmitting radio frequency signals representing the identity information of the patrol personnel, identifying and recording the position of the information of the patrol personnel, and the light control system can transmit an alarm when irrelevant personnel enter a factory building and no radio frequency signals of relevant registration information exist.

The acquisition control device may be configured to receive the data from the wireless code transmitter and upload the data to the ground-based central software system via the data transmission network.

The personnel positioning module can also comprise a receiving and processing module, wherein the receiving and processing module can be used for analyzing and processing the position information of the patrol personnel, and analyzing, deciding the starting and stopping of the lamplight and adjusting the brightness according to the position information.

Further, the model display module can also be used for displaying the number of people and any person position in real time. The personnel in the factory building are conveniently checked, and when irrelevant personnel enter the factory building, the current position of the personnel is reminded. When accidents happen, the position of the person giving the alarm can be quickly searched, and the situation that the delay dangerous case causes more serious is prevented.

The model display module also displays information such as the number and the usage amount of the whole lighting lamps, the state and the on-site distribution of the lamps and counts the electricity consumption. The state of the lamp can comprise overhaul information and operation conditions of the lamp. Based on the state of the lamp and the statistics of the electricity consumption, whether the lamp has abnormal conditions, namely the problems of damage, aging and the like can be obtained. When the lamp has abnormal conditions, the model display module can send out an alarm and display the coordinate position of the lamp in an abnormal state.

In the model display module, the areas with or without lamplight irradiation can be set to be different colors, so that the areas are convenient to check and distinguish, and the positions of the patrol personnel are rapidly resolved. For example, areas illuminated with light may be shown as light and areas not illuminated with light may be shown as dark. Further, the model display module can also be used for viewing real-time recorded data and historical recorded data of the camera.

Furthermore, the light control system can also comprise a personnel information management module, wherein the personnel information management module is used for managing and setting personnel information in real time, modifying and storing information such as names and the like, tracing inquiry and classified statistical storage of the activity track of the patrol personnel, and convenient calling and inquiry.

The hierarchical management and alarm module can be used for multi-level login, multi-level control and lamp monitoring, and if a certain lamp is offline, the hierarchical management and alarm module automatically performs audible and visual alarm and uploads lamp position information. Hierarchical control and hierarchical supervision can be realized, and the system records each operation so as to ensure stable and safe operation of the system; the system can realize remote control of the lamps, comprises unified starting and stopping of the lamps or control of a single lamp, and can call parameters such as the running state of the lamps in real time to realize real-time monitoring. And meanwhile, the personnel information such as personnel name, departments, job positions, numbers and the like can be managed and set in real time. The detailed information can be classified, counted and stored, event inquiry and accident tracing are carried out according to time, and related data are transmitted to management departments at all levels, so that important basis is provided for command decision.

In order to achieve the above object, the present application further provides an electronic device, which is characterized by comprising a processor, a memory, and a computer program stored in the memory and executable on the processor, wherein the computer program, when executed by the processor, implements a light control system as described above.

To achieve the above object, the present application further provides a computer readable storage medium, wherein the computer readable storage medium stores a computer program, and the computer program when executed by a processor implements a light control system as described above.

The application has the beneficial effects that: according to the application, the three-dimensional coordinates of the patrol personnel are obtained in real time, the three-dimensional coordinates of the patrol personnel are combined with the three-dimensional model of the factory building, the specific floor and the area where the patrol personnel are located are obtained, the light of the area where the patrol personnel are located is controlled to be turned on through the control system, and the light is turned off after the patrol personnel leave, so that the automation and the intellectualization of the light control are realized, the energy consumption is reduced, and the energy saving economic benefit of the coal preparation factory is improved.

It will be understood by those of ordinary skill in the art that the foregoing embodiments are specific examples of implementing the present disclosure, and that various changes in form and details may be made therein without departing from the spirit and scope of the present disclosure.

Claims (10)

1. A light control system, comprising:

the digital model twinning module is used for simulating coal preparation plants, equipment and lamps in reality;

the model display module is used for displaying the position of the patrol personnel and the light irradiation range;

the personnel positioning module is based on an accurate personnel positioning system and is used for positioning three-dimensional coordinates of patrol personnel in real time;

the digital model positioning module is based on a GIS technology and is used for carrying out coordinate positioning on eight corners of each factory building space, four corners of each device projected in the vertical direction and the position of each lamp center point in a coal preparation factory, wherein the coordinate positioning is a three-dimensional coordinate;

the digital model positioning module and the personnel positioning module use a unified coordinate system, and the three-dimensional coordinates of the digital model positioning module and the personnel positioning module are compared and analyzed through a GIS technology to obtain the specific position of the patrol personnel;

the light management module comprises a light control module and a light binding module; the light control module is used for receiving the data of the track prediction module and controlling light;

the track prediction module is used for collecting data of the digital model positioning module and the personnel positioning module so as to predict action tracks of the patrols, acquiring the patrols of the patrols and real-time speeds of the patrols, predicting the patrols behind the patrols according to specific positions of the patrols, and sending the data to the light control module.

2. The light control system of claim 1, wherein the light binding module comprises a zone management module and a device management module;

the region management module is used for carrying out region division on the digital model twin module, marking a region range in the model display module and binding all lamps in the region according to the region division;

the device management module is used for carrying out device division on the digital model twin module, marking the device range in the model display module and binding all lamps in the device according to the device division.

3. A light control system as defined in claim 1, wherein,

the light control module is provided with four modes, wherein the first mode is to automatically start lamps around the patrol personnel or to adjust the brightness of the lamps around the patrol personnel according to the position of the patrol personnel;

the second mode is that when the patrol personnel are in a certain area, the lamps bound in the area are turned on or the brightness of the lamps is increased;

the third mode is that when the patrolling personnel are in the range of the equipment, the lamp bound by the equipment is turned on or the brightness of the lamp is turned on;

and the fourth mode is to automatically turn off the lamp or reduce the brightness of the lamp after the inspection of the inspection personnel is finished.

4. A light control system as recited in claim 1 wherein said personnel location module comprises a wireless code transmitter, a data acquisition control device, a data transmission network, a ground-centric software system, and a server, said wireless code transmitter for transmitting radio frequency signals representative of the identity of the patrolling personnel;

the acquisition control equipment is used for receiving the data of the wireless coding transmitter and uploading the data to the ground center software system through the data transmission network;

the personnel positioning module further comprises a receiving and processing module, wherein the receiving and processing module is used for analyzing and processing the position information of the patrol personnel, and analyzing, deciding the starting and stopping of the lamplight and adjusting the brightness according to the position information.

5. A light control system as recited in claim 1 wherein said model display module is further configured to display the number of people and any person location in real time;

the model display module also displays information such as the number and the use amount of the integral lighting lamps, the states of the lamps, the field distribution and the like, and counts the power consumption;

in the model display module, the area with light illumination is light-colored, and the area without light illumination is dark-colored, and the model display module is used for checking real-time recording data and historical recording data of the camera.

6. A light control system as recited in claim 1 wherein said personnel location module comprises a wireless code transmitter, a data acquisition control device, a data transmission network, a ground-centric software system, and a server, said wireless code transmitter for transmitting radio frequency signals representative of the identity of the patrolling personnel;

the acquisition control equipment is used for receiving the data of the wireless coding transmitter and uploading the data to the ground center software system through the data transmission network.

7. The light control system of claim 1, further comprising a personnel information management module, wherein the personnel information management module manages and sets personnel information in real time, modifies and stores information such as names, and performs tracing inquiry and classified statistical storage on the activity track of the patrolling personnel.

8. The light control system of claim 1, further comprising a hierarchical management and alarm module for multi-level logging, multi-level operation and monitoring of the light fixtures, wherein if a light fixture is displayed offline, the hierarchical management and alarm module automatically performs audible and visual alarm and uploads light fixture location information.

9. An electronic device comprising a processor, a memory and a computer program stored on the memory and executable on the processor, the computer program implementing a light control system as claimed in any one of claims 1-8 when executed by the processor.

10. A computer readable storage medium, characterized in that the computer readable storage medium has stored thereon a computer program which, when executed by a processor, implements a light control system according to any of claims 1 to 8.