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

A material management system and method for an aerial building construction machine for high-rise buildings

Technical Field

The present invention relates to the field of material management of aerial building construction machines, and in particular to a material management system and method for aerial building construction machines used in high-rise buildings.

Background technique

With the rapid development of global urbanization in the past two decades, high-rise buildings have been widely praised and used worldwide for their beautiful design, comfortable environment, and land saving. However, high-rise building construction has a series of problems such as high difficulty, high risk, and complex organization. There is an urgent need for advanced construction equipment to improve the on-site working environment and improve the efficiency of construction. Based on the above needs, aerial building machines (i.e., construction equipment integration platforms) have played a significant role in the construction of many landmark buildings in China with their high equipment integration, factory-like operation, fast construction speed, and guaranteed construction safety. It has greatly improved the mechanization and intelligence level of high-rise building construction and promoted my country's high-rise building construction technology to a new height. During the construction of building machines, the consumption monitoring of urban aerial building machines is currently mainly carried out by monitoring cameras and daily manual statistics. When the consumption situation occurs, each monitoring point reports the material consumption information of different building locations to the central processing unit, which screens the valid data and then hands it over to professional engineers for processing and resolution. The system lacks all-weather real-time monitoring of the material consumption of urban aerial building construction, and is unable to respond quickly to the consumption of aerial building machines, nor can it replenish materials in a timely manner, which slows down the construction speed. In view of this, it is now urgently necessary to design a material management system and method for aerial building machines for high-rise buildings in order to overcome the above-mentioned defects of the existing aerial building machine monitoring system.

Summary of the invention

The present invention provides a material management system and method for an aerial building construction machine for high-rise buildings, which can count the material consumption rate and the material replenishment rate; simultaneously perform consumption monitoring and timing management of a human-machine interaction interface; transmit data in real time; complete statistical tracking and follow-up; realize comprehensive material management and construction optimization of the aerial building construction machine, and provide real-time feedback of the latest and most reliable data of the aerial building construction machine, thereby improving the efficiency and overall level of building construction.

In order to solve the above technical problem, according to one aspect of the present invention, the following technical solution is adopted:

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

The material monitoring device using Zigbee+UWB equipment uses 5G base stations to achieve real-time statistics of material data;

The human-machine interactive interface for controlling material parameters of high-rise buildings manages material consumption using a material consumption speed visualization component and a material replenishment speed visualization component;

The management host of the edge computing gateway is used to receive material monitoring device and human-computer interaction interface management data, and is also used for parameter settings of the human-computer interaction interface and parameter settings of the high-rise building construction platform.

Furthermore, the material monitoring device of the Zigbee+UWB device uses positioning and camera sensing equipment to real-time count the placement data of the material size; collect material type, chemical property stability, and material volume data; real-time count the material consumption speed and fluidity status, collect material-related parameters of different materials, and feed back the consumption parameters and wettability parameters to the edge computing gateway in real time.

Furthermore, the human-computer interaction interface includes a visualization component for material consumption speed and a visualization component for common material replenishment speed, with statistics of various consumption conditions, including material viscosity, material density, material volatility and stability of material chemical properties;

The material consumption speed visualization component controlled by the human-computer interaction interface is limited by the material replenishment speed.

Further, the management host of the edge computing gateway receives positioning data of the material monitoring device using the Zigbee+UWB device, material consumption information of different building locations, and material consumption information of different building locations reported by the human-computer interaction interface for daily management;

Based on these data, the human-computer interaction interface is set up for management according to the specific situation parameters, or the management host of the edge computing gateway is arranged to count the consumption of the confirmed aerial building machine and generate a statistical list at the same time;

At the same time, the edge computing gateway management host will also comprehensively manage the consumption data of the aerial building construction machine to the lifting mechanism management host, so that engineers can see the material consumption information of different construction locations of the aerial building construction machine in real time when using the human-computer interaction interface.

A material management method for an aerial building construction machine for high-rise buildings, the method comprising:

A1. The monitoring device of the Zigbee+UWB device is used to conduct material consumption statistics and control the human-machine interaction interface of the material parameters of high-rise buildings for daily management of the aerial building machine, and the collected data is transmitted to the management host of the edge computing gateway; the parameters of consumption statistics include: material viscosity, material density, material volatility and stability of material chemical properties;

A2. The edge computing gateway performs comprehensive data management, counts material consumption, and confirms consumption through the human-computer interaction interface; the confirmed material consumption is transmitted to the setting terminal;

A3. The edge computing gateway transmits the confirmed material consumption to the lifting mechanism management host, so that engineers can timely understand the status of the aerial building machine, plan a reasonable construction speed, and set the construction platform parameters;

A4. While the aerial building machine is constructing, the edge computing gateway receives the progress data of the material consumption of the aerial building machine, conducts real-time statistics and replenishment of various materials, and optimizes the construction steps of the construction process with serious material consumption.

Furthermore, in A1, in the Zigbee+UWB device system, the tower structure can be monitored by a material replenishment monitoring device, and the data is transmitted in real time by the system, and the material replenishment in the tower structure is regularly transmitted back to the system terminal and the consumption value is monitored.

Furthermore, in A1, the human-computer interaction interface includes a visualization component for material consumption speed and a visualization component for common material replenishment speed. The human-computer interaction interface controls high-definition digital image transmission and transmits the statistical curve of the human-computer interaction interface back to the material supply end in real time.

Furthermore, in the A1, the human-computer interaction interface uploads data to the system; the ground end of the human-computer interaction interface is divided into a human-computer interaction interface signal transceiver and a ground end computer; the ground end is used to receive the curves counted by the human-computer interaction interface in real time and analyze them through the ground end computer; the ground end computer uses an algorithm model to identify the consumption situation, and transmits the consumption situation in the form of statistical tables, curves, consumption results and construction success rates to the system's supporting database.

Furthermore, in A2, the edge computing gateway will comprehensively manage data from different sources, including data from monitoring devices, types of monitoring devices, construction success rates of monitoring devices, comprehensive management data of aerial building machines in the human-computer interaction interface, and construction success rates at consumption locations counted by the human-computer interaction interface; the edge computing gateway will determine whether consumption has occurred in the aerial building machine based on these data; when the material consumption information at different construction locations comes from the material monitoring device, the system's supporting database will notify the human-computer interaction interface to manage the construction success rate point where the material monitoring device is located to determine the consumption of the aerial building machine.

In A4, the edge computing gateway will call the human-computer interaction interface to follow up the progress when the aerial building construction machine is constructing. After receiving the signal of abnormal consumption of the aerial building construction machine, the human-computer interaction interface will be called to confirm the abnormal source of consumption.

Beneficial effects:

The present invention proposes a material management system for an aerial building construction machine for high-rise buildings, which can count the material consumption rate and material replenishment rate; simultaneously perform consumption monitoring and timing management of the human-computer interaction interface; transmit data in real time; complete statistical tracking and follow-up; realize comprehensive material management and construction optimization of the aerial building construction machine, and provide real-time feedback of the latest and most reliable data of the aerial building construction machine, thereby improving the efficiency and overall level of building construction.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required for use in the embodiments or the description of the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For ordinary technicians in this field, other drawings can be obtained based on these drawings without paying creative work.

FIG. 1 is a block diagram showing a material management system for a high-rise building aerial construction machine according to the present invention.

FIG. 2 is a flowchart of a material management method for an aerial building construction machine for high-rise buildings according to the present invention.

Detailed ways

The preferred embodiments of the present invention are described in detail below with reference to the accompanying drawings.

In order to further understand the present invention, preferred embodiments of the present invention are described below in conjunction with examples. However, it should be understood that these descriptions are only for further illustrating the features and advantages of the present invention, rather than limiting the claims of the present invention.

The description in this section is only for several typical embodiments, and the present invention is not limited to the scope of the embodiments. The same or similar prior art means and some technical features in the embodiments are mutually replaced within the scope of the present invention.

Figure 1 is a block diagram of a material management system for an aerial building construction machine for high-rise buildings in one embodiment of the present invention. The system includes: a material monitoring device using Zigbee+UWB equipment, a human-computer interaction interface for controlling material parameters of high-rise buildings, and a management host of an edge computing gateway.

The material monitoring device using Zigbee+UWB equipment uses 5G base stations to realize real-time statistics of material data; the human-computer interaction interface that controls the material parameters of high-rise buildings uses material consumption speed visualization components and material replenishment speed visualization components to manage material consumption; the management host of the edge computing gateway is used to receive material monitoring device and human-computer interaction interface management data, and is also used for parameter settings of the human-computer interaction interface and parameter settings of the high-rise building construction platform.

In one embodiment of the present invention, a material monitoring device using Zigbee+UWB equipment uses positioning and camera sensing equipment to collect real-time statistics on the placement data of material sizes; collects material types, chemical property stability, and material volume data; real-time statistics on material consumption speed and fluidity conditions, collects material-related parameters of different materials, and feeds back consumption parameters and wettability parameters to the edge computing gateway in real time.

In one embodiment of the present invention, the human-computer interaction interface includes a visualization component for material consumption speed and a visualization component for common material replenishment speed, with statistics of various consumption conditions, including material viscosity, material density, material volatility, and stability of material chemical properties;

The material consumption speed visualization component controlled by the human-computer interaction interface is limited by the material replenishment speed.

In one embodiment of the present invention, the management host of the edge computing gateway receives positioning data of a material monitoring device using a Zigbee+UWB device, material consumption information at different building locations, and material consumption information at different building locations reported by a human-computer interaction interface for daily management;

Based on these data, the human-computer interaction interface is set up for management according to the specific situation parameters, or the management host of the edge computing gateway is arranged to count the consumption of the confirmed aerial building machine and generate a statistical list at the same time;

At the same time, the edge computing gateway management host will also comprehensively manage the consumption data of the aerial building construction machine to the lifting mechanism management host, so that engineers can see the material consumption information of different construction locations of the aerial building construction machine in real time when using the human-computer interaction interface.

FIG2 is a flow chart of a material management method for a high-rise building aerial building machine in one embodiment of the present invention, comprising:

A1. The monitoring device of Zigbee+UWB equipment is used to count the material consumption and control the material parameters of high-rise buildings. The human-machine interface is used for daily management of aerial building machines, and the collected data is transmitted to the management host of the edge computing gateway. The parameters of consumption statistics include: material viscosity, material density, material volatility, and the stability of material chemical properties.

In A1, in the Zigbee+UWB device system, the tower structure can be monitored by a material replenishment monitoring device, and the data is transmitted in real time by the system. The material replenishment in the tower structure is regularly transmitted back to the system terminal and the consumption value is monitored.

In the A1, the human-machine interface can last for more than 30 minutes when controlling equipment, and the cruising range can reach up to 5 kilometers. The human-machine interface includes a visualization component for material consumption speed and a visualization component for ordinary material replenishment speed. The human-machine interface also controls high-definition digital image transmission, which can transmit the curve of the human-machine interface statistics back to the material supply end in real time.

In A1, the principle of uploading data from the human-machine interface to the system is as follows: the ground end of the human-machine interface is divided into a human-machine interface signal transceiver and a ground end computer. The ground end is used to receive the curves counted by the human-machine interface in real time and analyze them through the ground end computer. The ground end computer uses an efficient algorithm to identify the consumption situation and transmits the consumption situation in the form of statistical tables, curves, consumption results and construction success rates to the system's supporting database.

A2. The edge computing gateway performs comprehensive data management, counts material consumption, and confirms consumption through the human-machine interface. The confirmed material consumption is transmitted to individual users and related aerial building machines.

In A2, the edge computing gateway will comprehensively manage data from different sources, including data from monitoring devices, monitoring device types, construction success rates of monitoring devices, comprehensive management data of aerial building machines in the human-machine interface, and construction success rates of consumption locations in the human-machine interface. The edge computing gateway will determine whether the aerial building machine has consumed based on these data. When the material consumption information source of different building locations comes from the material monitoring device, the system's supporting database will notify the human-machine interface to manage the construction success rate point where the material monitoring device is located to determine the consumption of the aerial building machine.

A3. The edge computing gateway transmits the confirmed material consumption to the lifting mechanism management host, so that engineers can timely understand the status of the aerial building machine, plan a reasonable construction speed, and set the construction platform parameters.

A4. While the aerial building machine is constructing, the edge computing gateway receives the progress data of the material consumption of the aerial building machine, conducts real-time statistics and replenishment of various materials, and optimizes the construction steps of the construction process with serious material consumption.

In A4, the edge computing gateway will call the human-computer interaction interface to follow up the progress when the aerial building construction machine is constructing. After receiving the signal of abnormal consumption of the aerial building construction machine, it will also call the human-computer interaction interface to confirm the source of the abnormal consumption.

Receive data, pictures, curves and other data sent back by Zigbee+UWB devices, monitoring devices and human-computer interaction interfaces; analyze data through algorithms; collect material consumption information at different building locations; determine whether it is necessary to further determine the type of consumption; dispatch the human-computer interaction interface to the location where consumption occurs for management; analyze the real-time curves sent back by the human-computer interaction interface through algorithms; confirm the type of consumption; update the progress data of related consumption processing; accept the construction progress feedback from the construction party; accept the feedback on the material update progress; confirm the material update status through the human-computer interaction interface;

After the statistical table is transmitted back to the ground end, the computer uses an efficient algorithm to perform target analysis on the statistical table and stores the results in the system's supporting database for subsequent processing. The specific steps include:

The database end of the system receives the consumption material curve transmitted back by the human-computer interaction interface.

The statistical table is processed by computer to obtain the processing results of the curve.

The data obtained from the above steps are stored in the system's supporting database, waiting to be forwarded to each material management port.

The aerial building section monitoring device regularly measures and receives data. The monitoring device regularly summarizes the received data to the Zigbee+UWB device base station, which then transmits it back to the system's supporting database for subsequent processing. The specific steps include:

The aerial building machine section monitoring device measures and receives data at regular intervals.

The monitoring device transmits the received data to the Zigbee+UWB device base station at a regular interval.

The Zigbee+UWB device base station is responsible for transmitting the data collected in the above steps back to the system's supporting database for subsequent processing.

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

In summary, the present invention proposes a material management system for aerial building machines for high-rise buildings, which can count the material consumption rate and material replenishment rate; simultaneously perform consumption monitoring and timing management of the human-computer interaction interface; transmit data in real time; complete statistical tracking and follow-up; realize the comprehensive material management and construction optimization of the aerial building machine, and provide real-time feedback on the latest and most reliable data of the aerial building machine, thereby improving the efficiency and overall level of building construction.

The description and application of the present invention here are illustrative and are not intended to limit the scope of the present invention to the above-described embodiments. The deformation and changes of the embodiments disclosed here are possible, and the replacement of the embodiments and the various components equivalent to those of ordinary skill in the art are well known. It should be clear to those skilled in the art that the present invention can be realized in other forms, structures, arrangements, proportions, and with other components, materials and parts without departing from the spirit or essential characteristics of the present invention. Other deformations and changes can be made to the embodiments disclosed here without departing from the scope and spirit of the present 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.