CN112508355A

CN112508355A - Block chain-based distributed scheduling system and method for metallurgical energy

Info

Publication number: CN112508355A
Application number: CN202011315362.1A
Authority: CN
Inventors: 吴礼云; 燕飞; 陈素君; 郑狄; 凌晨; 汪国川; 陈恩军; 沙澎; 田东明; 杨天亮; 方磊
Original assignee: Shougang Jingtang United Iron and Steel Co Ltd
Current assignee: Shougang Jingtang United Iron and Steel Co Ltd
Priority date: 2020-11-21
Filing date: 2020-11-21
Publication date: 2021-03-16
Anticipated expiration: 2040-11-21
Also published as: CN112508355B

Abstract

The invention discloses a block chain-based distributed dispatching system and method for metallurgical energy, which comprises the following steps: the energy distribution device and the dispatching control device; the energy distribution device comprises a plurality of energy terminals and a monitoring module in communication connection with the energy terminals; the energy terminal is terminal equipment for exploiting energy; the monitoring module is used for monitoring the working environment of the energy terminals to obtain environment monitoring data, acquiring position data, metallurgical energy stock data and metallurgical energy consumption data of the energy terminals, and sending the environment monitoring data, the position data, the metallurgical energy stock data and the metallurgical energy consumption data to the dispatching control device; the dispatching control device is used for carrying out classification processing on the environment monitoring data, the position data, the metallurgical energy stock data and the metallurgical energy consumption data to obtain classification data, and carrying out dispatching control on the energy terminals. The invention can detect the energy distribution condition and the energy utilization limit and improve the energy dispatching efficiency.

Description

Block chain-based distributed scheduling system and method for metallurgical energy

Technical Field

The invention relates to the technical field of energy scheduling, in particular to a block chain-based distributed scheduling system and method for metallurgical energy.

Background

A Block chain (Block chain) is a serial transaction record (also called a Block) which is cryptographically connected in series and protects contents, and is a novel application mode of computer technologies such as distributed data storage, point-to-point transmission, a consensus mechanism, an encryption algorithm and the like.

The block chain is an important concept of the bitcoin, is essentially a decentralized database, and is used as a bottom-layer technology of the bitcoin, namely a series of data blocks which are generated by correlation by using a cryptographic method, wherein each data block contains information of a batch of bitcoin network transactions for verifying the validity (anti-counterfeiting) of the information and generating a next block.

The energy distribution of the metallurgical industry is in different areas, no rule can be followed, and when the energy of the metallurgical industry is scheduled, the condition of all energy distribution, the state of each energy point and the available limit of the energy point are not known in time under the normal condition, so that a scheduling system is needed to be provided, the energy distribution condition and the available limit of the energy can be detected, and the energy scheduling efficiency is improved.

Disclosure of Invention

The embodiment of the application provides a block chain-based distributed dispatching system and method for metallurgical energy, which can detect the energy distribution condition and the available limit of energy and improve the energy dispatching efficiency.

The invention provides a block chain-based distributed scheduling system for metallurgical energy, which comprises: the energy distribution device and the dispatching control device; the energy distribution device comprises a plurality of energy terminals and a monitoring module in communication connection with the energy terminals; the energy terminal is terminal equipment for exploiting energy;

the monitoring module is used for monitoring the working environments of the energy terminals to obtain environment monitoring data, acquiring position data, metallurgical energy stock data and metallurgical energy consumption data of the energy terminals, and sending the environment monitoring data, the position data, the metallurgical energy stock data and the metallurgical energy consumption data to the dispatching control device;

the dispatching control device is used for receiving dispatching data, classifying the environment monitoring data, the position data, the metallurgical energy stock data and the metallurgical energy consumption data to obtain classified data, and dispatching and controlling the energy terminals according to the classified data and the dispatching data.

Preferably, the schedule control apparatus includes:

the dispatching front-end module is used for carrying out classification processing on the environment monitoring data, the position data, the metallurgical energy stock data and the metallurgical energy consumption data to obtain classified data;

the dispatching center module is used for receiving the dispatching data and carrying out dispatching control on the energy terminal according to the classified data and the dispatching data;

and the control port is in communication connection with the energy distribution device and the dispatching front-end module respectively and is used for judging whether the energy distribution device has preset communication authority or not, if so, the control port receives the environment monitoring data, the position data, the metallurgical energy stock data and the metallurgical energy consumption data sent by the energy distribution device and forwards the environment monitoring data, the position data, the metallurgical energy stock data and the metallurgical energy consumption data to the dispatching front-end module.

Preferably, the monitoring module includes:

the positioning unit is used for acquiring the position data of the energy terminal;

the terminal state monitoring unit is used for monitoring the working environment of the energy terminal and the working state of the energy terminal to obtain energy terminal monitoring data, judging whether the energy terminal is in a set working state or not according to the energy terminal monitoring data, and controlling the energy terminal to stop scheduling work if the energy terminal is not in the set working state;

the information collection and storage unit is used for collecting and storing the energy terminal monitoring data and the position data;

and the information feedback unit is used for sending the energy terminal monitoring data and the position data to the dispatching control device.

Preferably, the monitoring module further comprises:

the energy condition monitoring unit is used for monitoring the energy storage of the energy terminal to obtain the energy storage data;

the consumption raw material monitoring unit is used for monitoring the raw material consumption data of the energy terminal to obtain the raw material consumption data of the energy terminal;

and the data summarizing unit is used for receiving the energy stock data and the raw material consumption data, summarizing the energy stock data and the raw material consumption data and then sending the summarized data to the dispatching control device.

Preferably, the terminal state monitoring unit includes:

the safety monitoring unit is used for monitoring the working environment of the energy terminal to obtain the environment monitoring data, judging whether the working environment of the energy terminal meets a set environment state or not according to the environment monitoring data, and controlling the energy terminal to stop dispatching work if the working environment of the energy terminal does not meet the set environment state;

the data monitoring unit is used for monitoring the working state data of the energy terminal to obtain the working state data of the energy terminal, judging whether the energy terminal is in a set working state according to the working state data, and controlling the energy terminal to stop dispatching work if the energy terminal is not in the set working state;

and the product monitoring unit is used for carrying out product testing on the energy terminal to obtain product testing data, judging whether the energy terminal can normally work according to the product testing data, and controlling the energy terminal to stop dispatching work if the energy terminal cannot normally work.

The invention also provides a block chain-based distributed scheduling method for metallurgical energy, which is applied to the scheduling system, and comprises the following steps:

s1, monitoring the working environment of a plurality of energy terminals through a monitoring module to obtain environment monitoring data, acquiring position data, metallurgical energy stock data and metallurgical energy consumption data of the energy terminals, and sending the environment monitoring data, the position data, the metallurgical energy stock data and the metallurgical energy consumption data to a dispatching control device;

and S2, receiving scheduling data through the scheduling control device, classifying the environment monitoring data, the position data, the metallurgical energy stock data and the metallurgical energy consumption data to obtain classified data, and performing scheduling control on the energy terminals according to the classified data and the scheduling data.

Preferably, step S2 includes:

judging whether an energy distribution device has a preset communication authority through a control port, if so, receiving the environment monitoring data, the position data, the metallurgical energy stock data and the metallurgical energy consumption data sent by the energy distribution device, and forwarding the environment monitoring data, the position data, the metallurgical energy stock data and the metallurgical energy consumption data to a dispatching front-end module;

classifying the environment monitoring data, the position data, the metallurgical energy stock data and the metallurgical energy consumption data through a scheduling front-end module to obtain classified data;

and receiving the dispatching data through a dispatching center module, and carrying out dispatching control on the energy terminal according to the classification data and the dispatching data.

Preferably, step S1 includes:

acquiring the position data of the energy terminal through a positioning unit;

monitoring the working environment of the energy terminal and the working state of the energy terminal through a terminal state monitoring unit to obtain energy terminal monitoring data, judging whether the energy terminal is in a set working state or not according to the energy terminal monitoring data, and controlling the energy terminal to stop scheduling work if the energy terminal is not in the set working state;

collecting and storing the energy terminal monitoring data and the position data through an information collecting and storing unit;

and sending the energy terminal monitoring data and the position data to the dispatching control device through an information feedback unit.

Preferably, step S1 further includes:

monitoring the energy storage of the energy terminal through an energy condition monitoring unit to obtain energy storage data;

monitoring the raw material consumption data of the energy terminal through a raw material consumption monitoring unit to obtain the raw material consumption data of the energy terminal;

and receiving the energy stock data and the raw material consumption data through a data summarizing unit, summarizing the energy stock data and the raw material consumption data, and sending the summarized data to the dispatching control device.

Preferably, the monitoring of the working environment of the energy terminal and the working state of the energy terminal by the terminal state monitoring unit to obtain the monitoring data of the energy terminal, and the judgment of whether the energy terminal is in the set working state according to the monitoring data of the energy terminal includes:

monitoring the working environment of the energy terminal through a safety monitoring unit to obtain environment monitoring data, judging whether the working environment of the energy terminal meets a set environment state or not according to the environment monitoring data, and controlling the energy terminal to stop dispatching work if the working environment of the energy terminal does not meet the set environment state;

monitoring the working state data of the energy terminal through a data monitoring unit to obtain the working state data of the energy terminal, judging whether the energy terminal is in a set working state according to the working state data, and controlling the energy terminal to stop scheduling work if the energy terminal is not in the set working state;

and performing product testing on the energy terminal through a product monitoring unit to obtain product testing data, judging whether the energy terminal can normally work according to the product testing data, and controlling the energy terminal to stop dispatching work if the energy terminal cannot normally work.

The implementation of the invention has the following beneficial effects: the dispatching system and the dispatching method provided by the invention are used for monitoring the working environment of a plurality of energy terminals through the monitoring module to obtain environment monitoring data and position data, metallurgical energy stock data and metallurgical energy consumption data of the energy terminals, the dispatching control device classifies the environment monitoring data, the position data, the metallurgical energy stock data and the metallurgical energy consumption data to obtain classified data, and dispatching and controlling the energy terminals according to the classified data and the dispatching data input by a user.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on the drawings without creative efforts.

FIG. 1 is a block chain-based distributed scheduling schematic block diagram of metallurgical energy resources provided by the invention;

FIG. 2 is a functional block diagram of the monitoring module of FIG. 1 provided by the present invention;

FIG. 3 is a schematic block diagram of a terminal status monitoring unit of FIG. 2 according to the present invention;

fig. 4 is a flowchart of a block chain-based distributed scheduling method for metallurgical energy resources provided by the invention.

Detailed Description

In order to make the present application more clearly understood by those skilled in the art to which the present application pertains, the following detailed description of the present application is made with reference to the accompanying drawings by way of specific embodiments.

The invention provides a block chain-based distributed scheduling system for metallurgical energy, as shown in fig. 1, the scheduling system comprises: an energy distribution device 1 and a scheduling control device 2; the energy distribution device 1 comprises a plurality of energy terminals 11 and a monitoring module 12 which is in communication connection with the energy terminals 11; the energy terminal 11 is a terminal device for exploiting energy. In one embodiment, the monitoring module 12 is a single chip.

The monitoring module 12 is configured to monitor the working environments of the plurality of energy terminals 11 to obtain environment monitoring data, obtain position data, metallurgical energy stock data, and metallurgical energy consumption data of the plurality of energy terminals 11, and send the environment monitoring data, the position data, the metallurgical energy stock data, and the metallurgical energy consumption data to the scheduling control device 2.

The scheduling control device 2 is configured to receive scheduling data input by a user, classify the environmental monitoring data, the position data, the metallurgical energy storage data, and the metallurgical energy consumption data to obtain classified data, and perform scheduling control on the plurality of energy terminals 11 according to the classified data and the scheduling data.

In an embodiment, the scheduling control device 2 obtains the metallurgical energy storage data and the metallurgical energy consumption data of the 5 energy terminals 11 in the set area, determines whether the energy provided by the 5 energy terminals 11 to the set area is sufficient, and if the energy is sufficient, determines whether the working environment of the corresponding energy terminal 11 meets the set environmental state, for example, whether the mining environment is safe according to the environment monitoring data of the 5 energy terminals 11, and selects the energy terminal 11 meeting the safety condition for scheduling. The energy source may be a mineral energy source and the energy terminal 11 may be an ore cutter. When the dispatching control is performed on the plurality of energy terminals 11, the energy terminals 11 meeting the requirements can be controlled to work to exploit energy.

The scheduling control device 2 includes: a scheduling front-end module 22, a scheduling center module 23 and a control port 21. The number of the scheduling front end modules 22 may be plural, the number of the scheduling center modules 23 may be plural, and the number of the control ports 21 may be plural. The dispatching front-end module 22 is respectively connected with the control port 21 and the dispatching center module 23 in a communication way.

The scheduling front-end module 22 is configured to perform classification processing, i.e., classification and collection, on the environmental monitoring data, the location data, the metallurgical energy inventory data, and the metallurgical energy consumption data to obtain classified data.

The scheduling center module 23 is configured to receive scheduling data input by a user, and perform scheduling control on the energy terminal 11 according to the classification data and the scheduling data.

In an embodiment, the scheduling center module 23 determines, according to the scheduling data input by the user, the location information of the energy terminal 11 or the communication address of the energy terminal 11 that the user needs to schedule, and determines, according to the location information of the energy terminal 11 or the communication address of the energy terminal 11, whether the metallurgical energy storage data of the energy terminal 11 is greater than the metallurgical energy consumption data and is also greater than or equal to a preset minimum energy storage value, and then controls the energy terminal 11 to perform scheduling work to mine the corresponding metallurgical energy.

In another embodiment, the scheduling data input by the user includes the energy demand, but does not include the specific location information of the energy terminal 11 or the communication address of the energy terminal 11, and the scheduling center module 23 may select, according to the energy demand, the energy terminal 11 that meets the energy demand and is closest to the user demand address from the plurality of energy terminals 11, and control the energy terminal 11 to perform scheduling work to mine the corresponding metallurgical energy. The dispatching center module 23 may determine whether a difference between the metallurgical energy stock data and the metallurgical energy consumption data is greater than or equal to the energy demand, and if so, may determine that the energy terminal 11 satisfies the energy demand. The distance between each energy terminal 11 and the user demand address can be calculated according to the pre-stored address of each energy terminal 11 and the user demand address included in the scheduling data input by the user. The control port 21 is in communication connection with the energy distribution device 1 and the scheduling front-end module 22, and is configured to determine whether the energy distribution device 1 has a preset communication right, and if so, receive the environmental monitoring data, the position data, the metallurgical energy stock data, and the metallurgical energy consumption data sent by the energy distribution device 1, and forward the environmental monitoring data, the position data, the metallurgical energy stock data, and the metallurgical energy consumption data to the scheduling front-end module 22.

In an embodiment, the control port 21 stores a communication address of the energy distribution device 1 capable of communicating with the control port, the communication address of the energy distribution device 1 may be a communication address of the monitoring module 12, and the control port 21 may determine whether the communication address of the monitoring module 12 matches the communication address stored in the control port 21 when determining whether the energy distribution device 1 has the communication right, and if so, determine that the energy distribution device 1 has the preset communication right.

As shown in fig. 2, the monitoring module 12 includes: a positioning unit 121, a terminal state monitoring unit 122, an information collecting and storing unit 123 and an information feedback unit 124.

The positioning unit 121 is used to acquire position data of the energy terminal 11.

The terminal state monitoring unit 122 is configured to monitor a working environment of the energy terminal 11 and a working state of the energy terminal 11, obtain monitoring data of the energy terminal 11, determine whether the energy terminal 11 is in a set working state according to the monitoring data of the energy terminal 11, control the energy terminal 11 to stop scheduling work and send an alarm if the energy terminal 11 is not in the set working state, and allow the energy terminal 11 to perform scheduling work if the energy terminal 11 is in the set working state.

The information collection and storage unit 123 is used to collect and store the energy terminal 11 monitoring data and the location data.

The information feedback unit 124 is configured to send the energy terminal 11 monitoring data and the position data to the dispatch control device 2.

The monitoring module 12 further comprises: an energy condition monitoring unit 125, a consumed raw material monitoring unit 126 and a data summarizing unit 127.

The energy condition monitoring unit 125 is configured to monitor the energy storage of the energy terminal 11 to obtain energy storage data.

The consumed raw material monitoring unit 126 is configured to monitor raw material consumption data of the energy terminal 11, and obtain raw material consumption data of the energy terminal 11.

The data collecting unit 127 is configured to receive the energy storage data and the material consumption data, collect the energy storage data and the material consumption data, and send the collected data to the dispatch control device 2.

As shown in fig. 3, the terminal state monitoring unit 122 includes: safety monitoring unit 1221, data monitoring unit 1222, product monitoring unit 1223.

The safety monitoring unit 1221 is configured to monitor the working environment of the energy terminal 11, obtain environment monitoring data, and determine whether the working environment of the energy terminal 11 meets a set environmental state according to the environment monitoring data, if not, control the energy terminal 11 to stop scheduling work and send an alarm, if yes, allow the energy terminal 11 to perform scheduling work, and avoid loss caused by the energy terminal 11 working in a severe environment.

The data monitoring unit 1222 is configured to monitor the operating state data of the energy terminal 11, obtain the operating state data of the energy terminal 11, determine whether the energy terminal 11 is in a set operating state according to the operating state data, if not, control the energy terminal 11 to stop scheduling operation and send an alarm, and if so, allow the energy terminal 11 to perform scheduling operation.

The product monitoring unit 1223 is configured to perform product testing on the energy terminal 11 to obtain product test data, and determine whether the energy terminal 11 can normally operate according to the product test data, if not, control the energy terminal 11 to stop scheduling operation and send an alarm, and if so, allow the energy terminal 11 to perform scheduling operation.

The invention also provides a block chain-based distributed scheduling method for metallurgical energy, which is applied to the scheduling system, and as shown in fig. 4, the scheduling method comprises the following steps:

s1, monitoring the working environment of the plurality of energy terminals 11 through the monitoring module 12 to obtain environment monitoring data, and obtaining position data, metallurgical energy stock data, and metallurgical energy consumption data of the plurality of energy terminals 11, and sending the environment monitoring data, the position data, the metallurgical energy stock data, and the metallurgical energy consumption data to the dispatch control device 2;

and S2, receiving scheduling data input by a user through the scheduling control device 2, classifying the environmental monitoring data, the position data, the metallurgical energy stock data and the metallurgical energy consumption data to obtain classified data, and performing scheduling control on the energy terminals 11 according to the classified data and the scheduling data.

Step S2 includes:

judging whether the energy distribution device 1 has a preset communication authority through the control port 21, if so, receiving environment monitoring data, position data, metallurgical energy stock data and metallurgical energy consumption data sent by the energy distribution device 1, and forwarding the environment monitoring data, the position data, the metallurgical energy stock data and the metallurgical energy consumption data to the dispatching front-end module 22;

the environmental monitoring data, the position data, the metallurgical energy stock data and the metallurgical energy consumption data are classified through the scheduling front-end module 22 to obtain classified data;

and receiving scheduling data input by a user through the scheduling center module 23, and performing scheduling control on the energy terminal 11 according to the classification data and the scheduling data.

Step S1 includes:

acquiring position data of the energy terminal 11 through the positioning unit 121;

monitoring the working environment of the energy terminal 11 and the working state of the energy terminal 11 by the terminal state monitoring unit 122 to obtain monitoring data of the energy terminal 11, and judging whether the energy terminal 11 is in a set working state according to the monitoring data of the energy terminal 11, if not, controlling the energy terminal 11 to stop scheduling work and give an alarm, and if so, allowing the energy terminal 11 to perform scheduling work;

the monitoring data and the position data of the energy terminal 11 are collected and stored by the information collecting and storing unit 123;

the information feedback unit 124 transmits the monitoring data and the position data of the energy terminal 11 to the dispatch control unit 2.

Step S1 further includes:

monitoring the energy storage of the energy terminal 11 by the energy condition monitoring unit 125 to obtain energy storage data;

monitoring the raw material consumption data of the energy terminal 11 by the consumed raw material monitoring unit 126 to obtain the raw material consumption data of the energy terminal 11;

the data aggregating unit 127 receives the energy storage data and the material consumption data, aggregates the energy storage data and the material consumption data, and transmits the aggregated data to the dispatch control device 2.

The terminal state monitoring unit 122 monitors the working environment of the energy terminal 11 and the working state of the energy terminal 11 to obtain the monitoring data of the energy terminal 11, and determines whether the energy terminal 11 is in the set working state according to the monitoring data of the energy terminal 11, including:

monitoring the working environment of the energy terminal 11 through the safety monitoring unit 1221 to obtain environment monitoring data, and judging whether the working environment of the energy terminal 11 meets a set environment state according to the environment monitoring data, if not, controlling the energy terminal 11 to stop scheduling work and give an alarm, and if so, allowing the energy terminal 11 to perform scheduling work;

the data monitoring unit 1222 monitors the working state data of the energy terminal 11 to obtain the working state data of the energy terminal 11, and determines whether the energy terminal 11 is in a set working state according to the working state data, if not, the energy terminal 11 is controlled to stop scheduling work and send an alarm, and if so, the energy terminal 11 is allowed to perform scheduling work;

the product monitoring unit 1223 is used for performing product testing on the energy terminal 11 to obtain product testing data, and judging whether the energy terminal 11 can normally work according to the product testing data, if not, controlling the energy terminal 11 to stop scheduling work and send an alarm, and if so, allowing the energy terminal 11 to perform scheduling work.

In summary, the scheduling system and method provided by the present invention are configured to monitor the working environments of the plurality of energy terminals 11 through the monitoring module 12 to obtain environment monitoring data, and obtain position data, metallurgical energy stock data, and metallurgical energy consumption data of the plurality of energy terminals 11, the scheduling control device 2 classifies the environment monitoring data, the position data, the metallurgical energy stock data, and the metallurgical energy consumption data to obtain classification data, and performs scheduling control on the plurality of energy terminals 11 according to the classification data and the scheduling data input by the user, so that energy stock at the corresponding positions of the energy terminals 11 can be considered, excessive energy exploitation is avoided, and the limit available for energy is exceeded.

While preferred embodiments of the present invention have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. Therefore, it is intended that the appended claims be interpreted as including preferred embodiments and all such alterations and modifications as fall within the scope of the invention.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the invention. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims

1. A distributed dispatching system for metallurgical energy based on block chains is characterized by comprising: the energy distribution device and the dispatching control device; the energy distribution device comprises a plurality of energy terminals and a monitoring module in communication connection with the energy terminals; the energy terminal is terminal equipment for exploiting energy;

2. The distributed block chain-based metallurgical energy dispatching system of claim 1, wherein the dispatching control device comprises:

3. The distributed block chain-based scheduling system for metallurgical energy according to claim 1, wherein the monitoring module comprises:

4. The distributed block chain-based scheduling system for metallurgical energy according to claim 3, wherein the monitoring module further comprises:

5. The distributed block chain-based scheduling system for metallurgical energy according to claim 3, wherein the terminal state monitoring unit comprises:

6. A block chain-based distributed scheduling method for metallurgical energy resources is applied to the scheduling system of any one of claims 1 to 5, and comprises the following steps:

7. The distributed dispatching method for block chain-based metallurgical energy resources of claim 6, wherein the step S2 comprises:

8. The distributed dispatching method for block chain-based metallurgical energy resources of claim 6, wherein the step S1 comprises:

acquiring the position data of the energy terminal through a positioning unit;

9. The distributed dispatching method for block chain-based metallurgical energy resources of claim 8, wherein the step S1 further comprises:

10. The distributed dispatching method for metallurgical energy based on the block chain according to claim 8, wherein the monitoring of the working environment of the energy terminal and the working state of the energy terminal by the terminal state monitoring unit to obtain energy terminal monitoring data, and the judging of whether the energy terminal is in the set working state according to the energy terminal monitoring data comprises: