CN117852843A - Material management system and method for aerial building machine for high-rise building - Google Patents

Abstract

The invention relates to the field of buildings and discloses a material management system and method of an air building machine for high-rise buildings, wherein the system comprises a material monitoring device utilizing Zigbee and UWB equipment, a man-machine interaction interface for controlling material parameters of the high-rise buildings and a management host of an edge computing gateway; the material monitoring device realizes real-time statistics of material data by using a 5G base station; the man-machine interaction interface controls the material consumption speed visualization component and the material supplementing speed visualization component to manage the material consumption condition; the management host of the edge computing gateway is used for receiving the material monitoring device and the man-machine interaction interface management data, and is also used for setting parameters of the man-machine interaction interface and parameters of a high-rise building construction platform. The invention can count the material consumption speed and the material supplementing speed; meanwhile, the man-machine interaction interface consumption monitoring and timing management are carried out, the latest and most reliable data of the air building machine are fed back in real time, and the building efficiency and the comprehensive level are improved.

Description

Material management system and method for aerial building machine for high-rise building

Technical Field

The invention relates to the field of material management of an aerial building machine, in particular to a material management system and method of an aerial building machine for a high-rise building.

Background

With the rapid development of global town in the past two decades, high-rise buildings are widely promoted and used worldwide by virtue of the advantages of attractive design, comfortable environment, land saving and the like. However, the construction of high-rise buildings has a series of problems of great difficulty, high risk, complex organization and the like, and an advanced construction device is needed to improve the field operation environment and the construction efficiency. Based on the requirements, the aerial building machine (i.e. the construction equipment integrated platform) plays a remarkable role in numerous domestic landmark building constructions by virtue of the characteristics of high equipment integration level, factory-like operation, high construction speed, guaranteed construction safety and the like, greatly improves the mechanization and intelligence levels of high-rise building constructions, and promotes the development of the high-rise building construction technology in China to a new height. In the building process of the building machine, the consumption monitoring of the current urban aerial building machine is mainly performed by a monitoring camera and daily manual statistics. When the consumption condition occurs, the monitoring points report the material consumption information of different building positions to the central processing unit, and the central processing unit screens the effective data and sends the effective data to a professional engineer for processing and solving. The system lacks of all-weather real-time monitoring of urban aerial building material consumption, can not realize quick response to aerial building machine consumption and can not timely supplement materials, and the construction speed is slowed down.

Disclosure of Invention

The invention provides a material management system and a material management method for an air building machine for a high-rise building, which can count material consumption speed and material supplement speed; meanwhile, performing man-machine interaction interface consumption monitoring and timing management; transmitting data in real time; completing statistics tracking and follow-up; the material comprehensive management and construction optimization of the aerial building machine are realized, the latest and most reliable data of the aerial building machine are fed back in real time, and the building efficiency and comprehensive level are improved.

In order to solve the technical problems, according to one aspect of the present invention, the following technical scheme is adopted:

an aerial building machine material management system for a high-rise building, the system comprising: a material monitoring device of Zigbee and UWB equipment, a man-machine interaction interface for controlling material parameters of a high-rise building and a management host of an edge computing gateway are utilized;

the material monitoring device of Zigbee and UWB equipment is used for realizing real-time statistics of material data by using a 5G base station;

the man-machine interaction interface for controlling the material parameters of the high-rise building manages the material consumption condition by using the material consumption speed visualization component and the material supplementing speed visualization component;

the management host of the edge computing gateway is used for receiving the material monitoring device and the man-machine interaction interface management data, and is also used for setting parameters of the man-machine interaction interface and parameters of a high-rise building construction platform.

Further, the material monitoring device of Zigbee+UWB equipment is used for counting the placement data of the material size in real time through the positioning and shooting sensing equipment; collecting material type and chemical property stability, and material volume data; and counting the material consumption speed flowability condition in real time, collecting related parameters of new materials on different materials, and feeding back the consumption condition parameters and the wettability parameters to the edge computing gateway in real time.

Further, the man-machine interaction interface comprises a material consumption speed visualization component and a common material supplement speed visualization component, and statistics of various consumption conditions including material viscosity, material density, material volatility and material chemical property stability are carried out;

the material consumption speed visualization component controlled by the man-machine interaction interface can be limited by the material supplementing speed.

Further, the management host of the edge computing gateway receives positioning data of a material monitoring device of Zigbee+UWB equipment, material consumption information of different building positions and material consumption information of different building positions reported by a man-machine interaction interface for daily management;

according to the data, a man-machine interaction interface is set for management according to specific condition parameters, or a management host of an edge computing gateway is arranged to count the confirmed consumption condition of the air building machine, and a statistics list is generated at the same time;

meanwhile, the edge computing gateway management host can also comprehensively manage the data consumed by the air building machine to the crane mechanism management host, so that engineers can see the material consumption information of different building positions of the air building machine in real time when using the man-machine interaction interface.

An aerial building machine material management method for a high-rise building, the method comprising:

a1, carrying out consumption statistics on materials by using a monitoring device of Zigbee and UWB equipment on the materials, carrying out daily management on an air building machine by using a man-machine interaction interface for controlling material parameters of a high-rise building, and transmitting collected data to a management host of an edge computing gateway; parameters of consumption statistics include: material viscosity, material density, material volatility and material chemical property stability;

a2, comprehensively managing data by the edge computing gateway, counting consumption conditions of materials and confirming the consumption conditions by a human-computer interaction interface; transmitting the confirmed material consumption condition to a setting terminal;

a3, the edge computing gateway transmits the confirmed material consumption condition to the crane mechanism management host, so that engineers can know the condition of the aerial building machine in time, plan to have reasonable building speed, and set parameters of a construction platform;

a4, when the aerial building machine is built, the edge computing gateway receives progress data of material consumption of the aerial building machine, performs real-time statistics and supplement of various materials, and optimizes construction steps of a construction flow with serious material consumption.

Further, in the A1, in the zigbee+uwb device system, a new monitoring device may be used for monitoring the tower structure, and the data utilization system performs real-time transmission, and periodically sends the new material in the tower structure back to the system terminal and monitors the consumption value.

Further, in the step A1, the man-machine interaction interface includes a material consumption speed visualization component and a common material supplementing speed visualization component, and the man-machine interaction interface controls the high-definition digital image transmission and transmits the statistical curve of the man-machine interaction interface back to the material supply end in real time.

Further, in the step A1, the man-machine interaction interface uploads data to the system; the man-machine interaction interface ground end is divided into man-machine interaction interface signal receiving and transmitting equipment and a ground end computer; the ground end is used for receiving the curve counted by the human-computer interaction interface in real time and analyzing the curve through a ground end computer; the ground computer adopts an algorithm model to identify the consumption condition and transmits the consumption condition to a database matched with the system in the forms of a statistical table, a curve, a consumption result and a construction success rate.

Further, in the step A2, the edge computing gateway may perform comprehensive management on data from different sources, where the data includes data of the monitoring device, a type of the monitoring device, a construction success rate of the monitoring device, comprehensive management data of an air building machine of the man-machine interaction interface, and a construction success rate of the man-machine interaction interface counted to a consumption position; the edge computing gateway judges whether the air building machine consumes according to the data; when the material consumption information sources of different building positions come from the material monitoring device, the database matched with the system can inform the man-machine interaction interface to the building success rate point where the material monitoring device is positioned for management so as to determine the consumption of the air building machine.

In the step A4, the edge computing gateway invokes the man-machine interaction interface to follow up the progress of the building in the air, and invokes the man-machine interaction interface to confirm the abnormal source of consumption after receiving the abnormal consumption signal of the building in the air.

The beneficial effects are that:

the material management system of the aerial building machine for the high-rise building can count the material consumption speed and the material supplementing speed; meanwhile, performing man-machine interaction interface consumption monitoring and timing management; transmitting data in real time; completing statistics tracking and follow-up; the material comprehensive management and construction optimization of the aerial building machine are realized, the latest and most reliable data of the aerial building machine are fed back in real time, and the building efficiency and comprehensive level are improved.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a block diagram of a material management system of an air building machine for high-rise buildings.

FIG. 2 is a block diagram of a method for managing materials in an air building machine for high-rise buildings.

Detailed Description

Preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

For a further understanding of the present invention, preferred embodiments of the invention are described below in conjunction with the examples, but it should be understood that these descriptions are merely intended to illustrate further features and advantages of the invention, and are not limiting of the claims of the invention.

The description of this section is intended to be illustrative of only a few exemplary embodiments and the invention is not to be limited in scope by the description of the embodiments. It is also within the scope of the description and claims of the invention to interchange some of the technical features of the embodiments with other technical features of the same or similar prior art.

FIG. 1 is a block diagram of a material management system for an air building machine for high-rise buildings according to an embodiment of the present invention, the system includes: and the management host of the edge computing gateway utilizes a material monitoring device of Zigbee and UWB equipment and a man-machine interaction interface for controlling material parameters of a high-rise building.

The material monitoring device of Zigbee and UWB equipment is used for realizing real-time statistics of material data by using a 5G base station; the man-machine interaction interface for controlling the material parameters of the high-rise building manages the material consumption condition by using the material consumption speed visualization component and the material supplementing speed visualization component; the management host of the edge computing gateway is used for receiving the material monitoring device and the man-machine interaction interface management data, and is also used for setting parameters of the man-machine interaction interface and parameters of a high-rise building construction platform.

In an embodiment of the invention, a material monitoring device of Zigbee+UWB equipment is utilized to count the placement data of the material size in real time through positioning and shooting sensing equipment; collecting material type and chemical property stability, and material volume data; and counting the material consumption speed flowability condition in real time, collecting related parameters of new materials on different materials, and feeding back the consumption condition parameters and the wettability parameters to the edge computing gateway in real time.

In an embodiment of the present invention, the man-machine interaction interface includes a material consumption speed visualization component and a common material replenishment speed visualization component, and statistics of various consumption conditions includes material viscosity, material density, material volatility and material chemical property stability;

the material consumption speed visualization component controlled by the man-machine interaction interface can be limited by the material supplementing speed.

In an embodiment of the present invention, the management host of the edge computing gateway receives positioning data of a material monitoring device using zigbee+uwb devices, material consumption information of different building locations, and material consumption information of different building locations reported by a man-machine interaction interface for daily management;

according to the data, a man-machine interaction interface is set for management according to specific condition parameters, or a management host of an edge computing gateway is arranged to count the confirmed consumption condition of the air building machine, and a statistics list is generated at the same time;

meanwhile, the edge computing gateway management host can also comprehensively manage the data consumed by the air building machine to the crane mechanism management host, so that engineers can see the material consumption information of different building positions of the air building machine in real time when using the man-machine interaction interface.

Fig. 2 is a flow chart of a material management method of an air building machine for a high-rise building according to an embodiment of the invention, which includes:

a1, carrying out consumption statistics on materials by using a monitoring device of Zigbee and UWB equipment on the materials, carrying out daily management on an air building machine by using a man-machine interaction interface for controlling material parameters of a high-rise building, and transmitting collected data to a management host of an edge computing gateway. Parameters of consumption statistics include: material viscosity, material density, material volatility, material chemical property stability and the like.

In the A1, in the Zigbee+UWB equipment system, a new monitoring device is used for monitoring materials in the tower structure, the data is transmitted in real time by using the system, and the materials in the tower structure are transmitted back to the system terminal at regular time and consumption values are monitored.

In the A1, the duration of the man-machine interaction interface can reach more than 30 minutes when the equipment is controlled, the cruising range can reach 5 kilometers at the most, and the man-machine interaction interface comprises a material consumption speed visualization component and a common material supplementing speed visualization component. The high-definition digital image transmission is also controlled on the man-machine interaction interface, and the curve counted by the man-machine interaction interface can be transmitted back to the material supply end in real time.

In the A1, the principle of uploading data to the system by the man-machine interaction interface is as follows: the man-machine interaction interface ground end is divided into man-machine interaction interface signal receiving and transmitting equipment and a ground end computer. The ground terminal is used for receiving the curve counted by the man-machine interaction interface in real time and analyzing the curve through a ground terminal computer. The ground computer adopts a high-efficiency algorithm to identify the consumption condition and transmits the consumption condition to a database matched with the system in the forms of a statistical table, a curve, a consumption result and a construction success rate.

And A2, comprehensively managing data by the edge computing gateway, counting the consumption condition of materials, and confirming the consumption condition by the man-machine interaction interface. And transmitting the confirmed material consumption condition to the individual user and the relevant air building machine.

In the step A2, the edge computing gateway may perform integrated management on data from different sources, where the data includes data of the monitoring device, a type of the monitoring device, a building success rate of the monitoring device, integrated management data of an air building machine of the man-machine interaction interface, and a building success rate of the man-machine interaction interface counted to a consumption position. The edge computing gateway judges whether the air building machine consumes according to the data, when the material consumption information sources of different building positions come from the material monitoring device, the database matched with the system can inform the man-machine interaction interface to the building success rate point where the material monitoring device is located to manage so as to determine the consumption of the air building machine.

A3, the edge computing gateway transmits the confirmed material consumption condition to the crane mechanism management host, so that engineers can know the condition of the aerial building machine in time, the reasonable building speed is planned, and meanwhile, the parameters of the construction platform are set.

A4, when the aerial building machine is built, the edge computing gateway receives progress data of material consumption of the aerial building machine, performs real-time statistics and supplement of various materials, and optimizes construction steps of a construction flow with serious material consumption.

In the step A4, the edge computing gateway invokes the man-machine interaction interface to follow up the progress of the building in the air, and invokes the man-machine interaction interface to confirm the source of the consumption abnormality after receiving the signal of the consumption abnormality of the building in the air.

Receiving data, pictures, curves and the like sent back by Zigbee+UWB equipment, a monitoring device and a human-computer interaction interface; analyzing the data by an algorithm; collecting the material consumption information of different building positions; judging whether further judging the consumption type is needed; managing the man-machine interaction interface to the consumption place; analyzing a real-time curve transmitted back by a man-machine interaction interface through an algorithm; confirming the consumption type; updating the progress data of the related consumption process; receiving the construction progress fed back by a constructor; receiving the feedback material updating progress; the man-machine interaction interface confirms the material update condition;

after the statistical table is transmitted back to the ground end, the computer performs target analysis on the statistical table through a high-efficiency algorithm, and stores the obtained result in a database end matched with the system for subsequent processing, and the method specifically comprises the following steps of:

and the database matched with the system receives the consumption material curve transmitted back by the man-machine interaction interface.

And processing the statistical table by using a computer to obtain a processing result of the curve.

And storing the data obtained by the processing in the steps in a database terminal matched with the system, and waiting for forwarding to each material management port.

The monitoring device of the air building machine section periodically measures and receives data, the monitoring device periodically gathers the received data to a Zigbee and UWB equipment base station, and the Zigbee and UWB equipment base station transmits the received data back to a database matched with the system for subsequent processing, and the specific steps comprise:

the monitoring device of the aerial building machine section measures and receives data at fixed time.

The monitoring device transmits the received data to the Zigbee and UWB equipment base station at regular time.

And the Zigbee and UWB equipment base station is responsible for transmitting the data collected in the steps back to a database matched with the system for subsequent processing.

The invention can effectively count the consumption of the aerial building machine and can rapidly count the consumption of the aerial building machine, thereby improving the material management efficiency.

In summary, the material management system of the air building machine for the high-rise building provided by the invention can count the material consumption speed and the material supplementing speed; meanwhile, performing man-machine interaction interface consumption monitoring and timing management; transmitting data in real time; completing statistics tracking and follow-up; the material comprehensive management and construction optimization of the aerial building machine are realized, the latest and most reliable data of the aerial building machine are fed back in real time, and the building efficiency and comprehensive level are improved.

The description and applications of the present invention herein are illustrative and are not intended to limit the scope of the invention to the embodiments described above. Variations and modifications of the embodiments disclosed herein are possible, and alternatives and equivalents of the various components of the embodiments are known to those of ordinary skill in the art. It will be clear to those skilled in the art that the present invention may be embodied in other forms, structures, arrangements, proportions, and with other assemblies, materials, and components, without departing from the spirit or essential characteristics thereof. Other variations and modifications of the embodiments disclosed herein may be made without departing from the scope and spirit of the invention.

Claims (9)

1. An aerial building machine material management system for high-rise building, characterized in that the system includes: a material monitoring device of Zigbee+UWB equipment, a man-machine interaction interface for controlling material parameters of a high-rise building, and a management host of an edge computing gateway;

the material monitoring device of the Zigbee and UWB equipment utilizes a 5G base station to realize real-time statistics of material data;

the man-machine interaction interface controls the material consumption speed visualization component and the material supplement speed visualization component to manage material consumption conditions;

the management host of the edge computing gateway is used for receiving the material monitoring device and the man-machine interaction interface management data, and is also used for setting parameters of the man-machine interaction interface and parameters of a high-rise building construction platform.

2. An air building machine material management system for high-rise buildings according to claim 1, wherein: the material monitoring device of the Zigbee+UWB equipment counts the placement data of the material size in real time through the positioning and shooting sensing equipment; collecting material type and chemical property stability, and material volume data; and counting the material consumption speed flowability condition in real time, collecting related parameters of new materials on different materials, and feeding back the consumption condition parameters and the wettability parameters to the edge computing gateway in real time.

3. An air building machine material management system for high-rise buildings according to claim 1, wherein:

the man-machine interaction interface comprises a material consumption speed visualization component and a common material supplementing speed visualization component, and statistics of various consumption conditions including material viscosity, material density, material volatility and material chemical property stability are carried out;

the material consumption speed visualization component controlled by the man-machine interaction interface can be limited by the material supplementing speed.

4. An air building machine material management system for high-rise buildings according to claim 1, wherein:

the management host of the edge computing gateway receives positioning data of a material monitoring device by utilizing Zigbee+UWB equipment, material consumption information of different building positions and material consumption information of different building positions reported by a man-machine interaction interface for daily management;

according to the data, a man-machine interaction interface is set for management according to specific condition parameters, or a management host of an edge computing gateway is arranged to count the confirmed consumption condition of the air building machine, and a statistics list is generated at the same time;

meanwhile, the edge computing gateway management host can also comprehensively manage the data consumed by the air building machine to the crane mechanism management host, so that engineers can see the material consumption information of different building positions of the air building machine in real time when using the man-machine interaction interface.

5. The material management method of the aerial building machine for the high-rise building is characterized by comprising the following steps of:

a1, carrying out consumption statistics on materials by using a monitoring device of Zigbee and UWB equipment on the materials, carrying out daily management on an air building machine by using a man-machine interaction interface for controlling material parameters of a high-rise building, and transmitting collected data to a management host of an edge computing gateway; parameters of consumption statistics include: material viscosity, material density, material volatility and material chemical property stability;

a2, comprehensively managing data by the edge computing gateway, counting consumption conditions of materials and confirming the consumption conditions by a human-computer interaction interface; transmitting the confirmed material consumption condition to a setting terminal;

a3, the edge computing gateway transmits the confirmed material consumption condition to the crane mechanism management host, so that engineers can know the condition of the aerial building machine in time, plan to have reasonable building speed, and set parameters of a construction platform;

a4, when the aerial building machine is built, the edge computing gateway receives progress data of material consumption of the aerial building machine, performs real-time statistics and supplement of various materials, and optimizes construction steps of a construction flow with serious material consumption.

6. The method for managing materials of the air building machine for high-rise buildings according to claim 5, wherein the method comprises the following steps: in the Zigbee and UWB equipment system, a new monitoring device is used for monitoring the tower structure by using materials, the data utilization system transmits the data in real time, and the materials in the tower structure are transmitted back to the system terminal at regular time and consumption values are monitored.

7. The method for managing materials of the air building machine for high-rise buildings according to claim 5, wherein the method comprises the following steps: the man-machine interaction interface comprises a material consumption speed visualization component and a common material supplementing speed visualization component, and controls high-definition digital image transmission to transmit a statistical curve of the man-machine interaction interface back to a material supply end in real time.

8. The method for managing materials of the air building machine for high-rise buildings according to claim 5, wherein the method comprises the following steps: the man-machine interaction interface uploads data to the system; the man-machine interaction interface ground end is divided into man-machine interaction interface signal receiving and transmitting equipment and a ground end computer; the ground end is used for receiving the curve counted by the human-computer interaction interface in real time and analyzing the curve through a ground end computer; the ground computer adopts an algorithm model to identify the consumption condition and transmits the consumption condition to a database matched with the system in the forms of a statistical table, a curve, a consumption result and a construction success rate.

9. The method for managing materials of the air building machine for high-rise buildings according to claim 5, wherein the method comprises the following steps: the edge computing gateway comprehensively manages data from different sources, and judges whether the air building machine consumes according to the data; when the material consumption information sources of different building positions come from the material monitoring device, the database matched with the system can inform the man-machine interaction interface to the building success rate point where the material monitoring device is positioned for management so as to determine the consumption of the air building machine.