CN116303751A - Non-process dust removal energy management system based on block chain - Google Patents

Abstract

The application provides a non-process dust removal energy management system based on a block chain, which belongs to the technical field of industrial data management, and the embodiment of the application acquires the energy consumption data of non-process dust removal equipment in real time through a data acquisition system and uploads the energy consumption data to a block chain server; the block chain server classifies the energy consumption data and uploads the classified energy consumption data to the block chain for distributed storage; the user can acquire the energy consumption data of the non-process dust removal equipment to be checked from the blockchain through the non-process dust removal energy management platform according to the requirement. The embodiment of the application is based on the characteristics of non-tampering, traceability and the like of the blockchain technology, so that a manager can acquire historical energy consumption data of the non-process dust removing equipment to be checked at any time, the safety and the accuracy of the energy consumption data are improved, and further effective statistics, analysis and prediction of the energy consumption data of the non-process dust removing equipment are realized.

Description

Non-process dust removal energy management system based on block chain

Technical Field

The application relates to the technical field of industrial data management, in particular to a non-process dust removal energy management system based on a block chain.

Background

In various production workshops of iron and steel enterprises, a large amount of dust is generated in the industrial processing and manufacturing process. In the current environment-friendly solution of iron and steel enterprises, non-process dust removal equipment is usually adopted for dust removal, equipment in a dust removal system, particularly a large-scale dust removal system is often scattered, and a large amount of energy consumption data including electricity consumption, compressed air consumption, water consumption and oxygen consumption are generated in the operation process of the equipment.

Currently, aiming at equipment energy consumption, macroscopic statistics is usually carried out by taking enterprises as units, and specific energy consumption conditions of all the equipment cannot be known; the traditional energy consumption data acquisition scheme is only limited to the acquisition and transmission of equipment parameters, so that not only is the effective statistics and management of the energy consumption data lacking, but also the energy consumption data is at risk of modification in each link, and the supervision result cannot reflect the actual consumption condition of the equipment.

Disclosure of Invention

The utility model provides a non-technology dust removal energy management system based on blockchain, based on characteristics such as blockchain technique is unable to be tampered, traceable for managers can acquire the historical energy consumption data of equipment at any time, have improved monitoring data's security and accuracy, and then realize effective collection, statistics and the prediction to non-technology dust removal equipment's energy consumption data.

In order to solve the problems, the application adopts the following technical scheme:

the embodiment of the application provides a non-process dust removal energy management system based on a block chain, which comprises a data acquisition system, a block chain server and a non-process dust removal energy management platform; wherein,,

the data acquisition system is used for acquiring energy consumption data of non-process dust removal equipment and uploading the energy consumption data to the blockchain server; wherein the energy consumption data includes a plurality of different types of energy usage;

the block chain server is used for classifying the energy consumption data according to the different types in the energy consumption data, and uploading the classified energy consumption data to a block chain for distributed storage;

the non-process dust removal energy management platform is used for sending an energy data viewing request to the blockchain server and acquiring energy consumption data returned by the blockchain server in response to the energy data viewing request.

In an embodiment of the present application, the data acquisition system includes a data acquisition terminal and a data encryption module; wherein,,

the data acquisition terminal is used for acquiring the energy consumption data of the non-process dust removal equipment and sending the energy consumption data to the data encryption module;

the data encryption module is used for encrypting the energy consumption data by adopting a preset private key and uploading the encrypted energy consumption data to the blockchain server.

In an embodiment of the present application, the blockchain server includes a first receiving module, a second receiving module, a classification module, a first storage module, and a search module; wherein,,

the first receiving module is used for receiving the encrypted energy consumption data uploaded by the data encryption module; wherein the energy consumption data comprises corresponding equipment identifications;

the classification module is used for classifying the energy consumption data and adding a corresponding energy type identifier for the energy consumption data;

the first storage module is used for uploading the classified energy consumption data to the block chain for distributed storage;

the second receiving module is used for receiving the energy data viewing request sent by the non-process dust removal energy management platform;

the searching module is used for searching and screening the energy consumption data corresponding to the energy data viewing request from the blockchain according to the energy data viewing request sent by the non-process dust removal energy management platform, and returning the energy consumption data to the non-process dust removal energy management platform.

In an embodiment of the present application, the first storage module includes a blockchain unit, an obtaining unit, an updating unit, and a consensus unit; wherein,,

the block chain unit is used for acquiring a block chain formed by a plurality of storage blocks; the storage block comprises a block head and a block body, wherein the block body comprises a merkel tree, and the block head comprises a tree root of the merkel tree and a hash pointer of a preamble storage block;

the obtaining unit is used for obtaining the classified energy consumption data and writing hash values corresponding to the energy consumption data of the same class into child nodes of the same subtree in the merkel tree;

the updating unit is used for acquiring current energy consumption data according to a first preset time interval and generating a corresponding current hash value according to the current energy consumption data; writing the current hash value into a corresponding child node to replace the original hash value of the child node, and obtaining an updated Meeker tree;

and the consensus unit writes the updated tree root of the Meicher tree and the hash pointer of the corresponding preamble storage block into the corresponding block head, and broadcasts the block head to other blocks in the block chain to realize consensus and obtain the updated block chain.

In an embodiment of the application, the non-process dust removal energy management platform comprises a query module, a second storage module, a report management module and a display module; wherein,,

the query module is used for sending an energy data viewing request to the blockchain server and acquiring energy consumption data returned by the blockchain server in response to the energy data viewing request;

the second storage module is used for storing the energy consumption data;

the report management module is used for counting the energy consumption data and automatically generating a corresponding data report according to the user requirement;

the display module is used for displaying the real-time state, parameters and the energy consumption data of the non-process dust removing equipment through a display screen.

In an embodiment of the present application, the report management module automatically generates a data report at intervals of a second preset time interval, and stores the data report in the second storage module.

In an embodiment of the present application, the non-process dust removal energy management platform further includes a trend prediction module;

the trend prediction module is used for predicting the energy consumption data from the current moment to the future moment according to the historical energy consumption data of the historical moment and the current moment input by a user, wherein the difference value between the future moment and the current moment and the difference value between the current moment and the historical moment are the same.

In an embodiment of the present application, the energy consumption data includes one or more of an amount of electricity, an amount of compressed air, an amount of water, and an amount of oxygen of the non-process dust removing apparatus.

Compared with the prior art, the application has the following advantages:

according to the non-process dust removal energy management system based on the blockchain, energy consumption data of non-process dust removal equipment are collected in real time through the data collection system, and the energy consumption data are uploaded to the blockchain server; the block chain server classifies the energy consumption data and uploads the classified energy consumption data to the block chain for distributed storage; the user can acquire the energy consumption data of the non-process dust removal equipment to be checked from the blockchain through the non-process dust removal energy management platform according to the requirement. The embodiment of the application is based on the characteristics of non-tampering, traceability and the like of the blockchain technology, so that a manager can acquire historical energy consumption data of the non-process dust removing equipment to be checked at any time, the safety and the accuracy of the energy consumption data are improved, and further effective statistics, analysis and prediction of the energy consumption data of the non-process dust removing equipment are realized.

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 schematic structural diagram of a non-process dust removal energy management system based on a blockchain in an embodiment of the present application.

Reference numerals: 1-a data acquisition system; 2-a blockchain server; 3-a non-process dust removal energy management platform.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1, there is shown a non-process dust removal energy management system based on a blockchain of the present application, the system comprising a data acquisition system 1, a blockchain server 2 and a non-process dust removal energy management platform 3; wherein:

the data acquisition system 1 is used for acquiring the energy consumption data of the non-process dust removal equipment in real time and uploading the energy consumption data to the blockchain server 2; wherein the energy consumption data includes a plurality of different types of energy usage. Specifically, the energy consumption data may include one or more of an amount of electricity used, an amount of compressed air used, an amount of water used, and an amount of oxygen used by the non-process dust removing apparatus.

In this embodiment, the data acquisition system 1 may be configured based on a wireless sensor network, where the network includes a plurality of sink nodes (including a power consumption sink node, a compressed air consumption sink node, a water consumption sink node, and an oxygen consumption sink node), and different sink nodes are connected to a plurality of sensor sub-nodes, where the sensor sub-nodes are composed of different types of sensors and are respectively configured to acquire data energy consumption data including power consumption, compressed air consumption, water consumption, and oxygen consumption of the non-process dust collecting device. And the sensor nodes of the same type are connected with the same sink node, so that each sink node can collect the single type of energy consumption data of all corresponding devices, and the data collection efficiency and the subsequent data processing efficiency of the wireless sensor network are improved.

And the blockchain server 2 is used for classifying the energy consumption data according to different types in the energy consumption data and uploading the classified energy consumption data to a blockchain for distributed storage.

In this embodiment, the same type of data can be stored in the same node in the blockchain by sorting the energy consumption data and uploading the sorted data to the blockchain. Because the updating rule of the same type of energy consumption data is basically the same, when the data is updated, only the corresponding node needs to be updated, so that the calculation cost and the storage cost of the whole blockchain can be effectively reduced, and the storage pressure of the blockchain server 2 can be effectively reduced. Meanwhile, based on the characteristics of non-tampering, traceability and the like of the block chain technology, the energy consumption data is guaranteed to be tracked, and the safety and the accuracy of the energy consumption data are improved.

The non-process dust removal energy management platform 3 is used for sending an energy data viewing request to the blockchain server 2 and acquiring energy consumption data returned by the blockchain server 2 in response to the energy data viewing request.

In this embodiment, in order to facilitate the user's inquiry, the non-technical dust-removing energy management platform 3 may set different inquiry directories, such as an electricity consumption inquiry directory, a compressed air consumption inquiry directory, a water consumption inquiry directory and an oxygen consumption inquiry directory, and after the user logs in the non-technical dust-removing energy management platform 3, the user may enter the corresponding directory to check the corresponding device data by clicking the corresponding virtual button.

In this embodiment, each directory is divided into a plurality of subdirectories according to the area or plant in which the device is located. In one example, the electricity consumption amount catalog and the compressed air consumption amount catalog respectively comprise a steelmaking subdirectory, a blast furnace catalog, a coking subdirectory, a sintering subdirectory, a raw material subdirectory, a lime subdirectory, a pellet subdirectory and a slag treatment subdirectory; the water consumption catalog comprises an industrial water subdirectory, a production fire water subdirectory and a living water subdirectory; in the oxygen usage inventory, a slag treatment sub-inventory is included. And each sub-directory is internally provided with corresponding non-technical dust removing equipment.

In this embodiment, the user can view the energy consumption data of all the non-technical dust removing devices in the subdirectory area by clicking the virtual button corresponding to a subdirectory. For ease of administration, the user may also add and delete devices by clicking on a virtual edit button.

In this embodiment, no matter the enterprise user or the environmental protection supervisory department can access the process dust removal energy management platform, obtain the historical energy consumption data of the non-process dust removal equipment to be checked, and generate corresponding statistical data or analysis report form through the process dust removal energy management platform, so that the energy management is not limited to macroscopic analysis, but can realize the specific energy consumption condition of each equipment, thereby being beneficial to monitoring and tracing the energy consumption data of the non-process dust removal equipment in real time and improving the objectivity and accuracy of the energy management.

In one possible embodiment, the data acquisition system 1 comprises a data acquisition terminal and a data encryption module; wherein:

the data acquisition terminal is used for acquiring the energy consumption data of the non-process dust removal equipment and sending the energy consumption data to the data encryption module.

The data encryption module is used for encrypting the energy consumption data by adopting a preset private key and uploading the encrypted energy consumption data to the blockchain server 2.

In the embodiment, the private key is adopted to encrypt the energy consumption data, so that the confidentiality and the security of the data can be ensured, namely, only the owner of the private key can acquire the energy consumption data, further, other enterprises or users are prevented from acquiring the energy consumption data of the enterprise, the data uploading stage is prevented from being forged or tampered by other people, and the integrity and the authenticatable of the data are effectively ensured.

In one possible embodiment, the blockchain server 2 includes a first receiving module, a second receiving module, a classification module, a first storage module, and a search module; wherein:

the first receiving module is used for receiving the encrypted energy consumption data uploaded by the data encryption module and analyzing the encrypted energy consumption data so as to facilitate subsequent data processing; wherein the energy consumption data comprises a corresponding device identification. Specifically, the device identifier may include a workshop identifier, a device type and a device number of the device, so that detailed information of the target device can be quickly obtained in a data query stage.

The classification module is used for classifying the energy consumption data and adding corresponding energy type identifiers for the energy consumption data.

And the first storage module is used for uploading the classified energy consumption data to the blockchain for distributed storage.

The second receiving module is used for receiving the energy data viewing request sent by the non-process dust removal energy management platform 3.

The searching module is used for searching and screening the energy consumption data corresponding to the energy data viewing request from the blockchain according to the energy data viewing request sent by the non-process dust removal energy management platform 3, and returning the energy consumption data to the non-process dust removal energy management platform 3.

In this embodiment, after the user logs in the non-process dust removal energy management platform 3, the user can directly locate a specific non-process dust removal device by inputting a corresponding device identifier, in addition to checking the energy consumption data of the corresponding non-process dust removal device by entering a corresponding subdirectory area.

In one possible implementation, the first storage module includes a blockchain unit, an acquisition unit, an update unit, a consensus unit; wherein:

a block chain unit for acquiring a block chain composed of a plurality of memory blocks; the storage block comprises a block head and a block body, the block body comprises a merkel tree, and the block head comprises a tree root of the merkel tree and a hash pointer of the preamble storage block.

In this embodiment, the nodes of the blockchain will consist of several memory blocks, each including a block header and a block body. Wherein the storage area block includes a merkel tree storing energy consumption data; the memory block head stores the information such as the tree root of the merkel tree, the hash pointer of the preamble memory block, and the time stamp. The tree root of the mekel tree is the block hash value of the storage block, which is also called the hash value of the storage block, and is placed in the storage block header for data verification, the hash pointer of the preceding storage block is used for pointing to the hash value of the previous storage block, and the storage blocks are sequentially connected to form the blockchain in the embodiment through the front-to-back pointing relation of the hash pointer of the preceding storage block. The Hash (Hash) is a function of mapping data with any length into data with a fixed length, and the data with the fixed length is the finally obtained Hash value.

In this embodiment, the merkel tree is also called a hash tree, and is divided into two parts, namely a binary tree and a transaction sequence, where the transaction sequence is used as a child node of the whole merkel tree and corresponds to the child node of the binary tree part one by one, and in this embodiment, the merkel tree is used for storing energy consumption data. And the binary tree part takes the hash value of the energy consumption data from the value of the child node, and the father node of the tree is the hash value of the combination of the two child nodes. The characteristic of the Meeker tree is that any change to the bottom node is transferred to the father node, up to the tree root, and the changed leaf node is easy to locate, so that the Meeker tree is especially suitable for quick, effective and safe verification of the existence and integrity of data. The use of the merkel tree increases the difficulty of data tampering, and can realize effective recording of time sequence changes of the energy consumption data.

The obtaining unit is used for obtaining the classified energy consumption data and writing the hash value corresponding to the energy consumption data of the same class into the child nodes of the same subtree in the merkel tree.

It should be noted that, the subtree is taken as one tree branch of the merkel tree, and a pair of child nodes under the same subtree corresponds to the same parent node, that is, two child nodes plus the corresponding parent node can be regarded as a subtree with a minimum unit. The existing distributed storage scheme based on the blockchain does not consider the updating rule of the data, but is randomly distributed to the child nodes for storage, and each time of data updating, the change on a path from a parent node corresponding to the child node to a tree root is caused. In one example, two paths change if two data in different subtrees are updated at the same time.

In this embodiment, the update rules of the same type of energy consumption data are basically the same, so when the hash values corresponding to the same type of energy consumption data are written into the child nodes of the same subtree in the merkel tree, the method means that when the energy consumption data are updated at the same time, only the change from the parent node corresponding to the child node to the tree root is caused, and further the change of multiple paths caused by the storage of the energy consumption data under different subtrees is avoided, so that the hash calculation times and the corresponding storage cost can be effectively reduced, and meanwhile, the storage pressure of the blockchain server 2 is effectively reduced.

The updating unit is used for acquiring current energy consumption data according to a first preset time interval and generating a corresponding current hash value according to the current energy consumption data; and writing the current hash value into the corresponding child node to replace the original hash value of the child node, and obtaining the updated Meeker tree.

In this embodiment, it should be noted that the first preset time interval may be actually set according to the energy consumption of different types, for example, the power consumption may be set to be collected once every half an hour, and the water consumption may be set to be collected once every 24 hours. The first preset time interval is not specifically limited, and the first preset time interval is set according to actual needs.

And the consensus unit writes the updated tree root of the Meicher tree and the hash pointer of the corresponding preamble storage block into the corresponding block header, and broadcasts the block header to other blocks in the block chain to realize consensus and obtain the updated block chain.

In this embodiment, after the merkel tree is updated, broadcasting is performed by writing the updated tree root of the merkel tree and the hash pointer of the corresponding preamble block into the corresponding block header, so as to inform the latest energy consumption data of other blocks, thereby realizing consensus and obtaining the updated block chain.

In one possible implementation, the non-process dust removal energy management platform 3 comprises a query module, a second storage module, a report management module and a display module; wherein,,

and the query module is used for sending an energy data viewing request to the blockchain server 2 and acquiring energy consumption data returned by the blockchain server 2 in response to the energy data viewing request. It should be noted that, the query module may perform manual query by a user, or may perform automatic query by setting a preset query time through the platform.

In this embodiment, after the user logs in the non-process dust removal energy management platform 3, the user can check the energy consumption data of the corresponding non-process dust removal equipment by entering the corresponding subdirectory area, and can also continuously and individually query by inputting the corresponding equipment identifier, for example, "steelmaking" is input in the shop identifier, "refining secondary dust removal device" is input in the equipment type, and "2#" is input in the equipment number, and then the non-process dust removal energy management platform 3 directly acquires the energy consumption data of the 2# refining secondary dust removal device in the steelmaking shop from the blockchain server 2.

And the second storage module is used for storing the energy consumption data. In this embodiment, by storing the energy consumption data locally, the queried energy consumption data can be directly invoked in the data analysis stage, so that data loss or repeated query is avoided.

The report management module is used for counting the energy consumption data and automatically generating a corresponding data report according to the user requirements; as one preferable scheme, the report management module automatically generates a data report at intervals of a second preset time interval and stores the data report in the second storage module.

In this embodiment, the report management module may automatically generate a report required by the user, such as a monthly electricity consumption statistics table, an electricity consumption cost report, and the like, according to a preset generation rule by reading the data in the second storage module.

The embodiment further needs to be explained, after the user logs in the non-process dust removal energy management platform 3 and can be authenticated again, the user can manually input data by clicking the edit virtual button to calibrate the energy consumption data, and after the calibration, a calibration record is left, wherein the calibration record comprises the input calibration value and the calibrated value, so that the modification record is traceable.

And the display module is used for displaying the real-time state, parameters and energy consumption data of the non-process dust removing equipment through a display screen.

In the present embodiment, the real-time status, parameters, and energy consumption data of the non-process dust removing apparatus may be displayed on the display screen in the form of a statistical chart or a table. In one example, a graph may be used to show a real-time plot of the power usage per hour of the target non-process dust removal device, with a histogram being used to show the aggregate of the current accumulated power usage. It should be noted that, the displayed content may be switched according to the user's need, for example, when the query condition is a single device, the energy consumption data graph of the device is displayed; and when the query condition is a workshop or an area, displaying an energy consumption data graph of all devices in the workshop or the area.

In one possible embodiment, the non-process dust removal energy management platform 3 further comprises a trend prediction module.

Specifically, the trend prediction module is used for predicting the energy consumption data from the current time to the future time according to the historical energy consumption data of the historical time and the current time input by a user, wherein the difference value between the future time and the current time and the difference value between the current time and the historical time are the same.

In this embodiment, on the basis of displaying the graph of the energy consumption data, the corresponding energy consumption trend may also be predicted by the history data. In one example, if the length of time required for the user output to predict is ten days, a straight line from ten days before to the current time is drawn according to the historical energy consumption data of ten days before the current time, and the straight line is extended to a time scale corresponding to ten days in the future, so that trend prediction of the energy consumption data is realized.

It will be apparent to those skilled in the art that embodiments of the present invention may be provided as a method, apparatus, or computer program product. Accordingly, embodiments of the present invention may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, embodiments of the invention may take the form of a computer program product on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, etc.) having computer-usable program code embodied therein.

Embodiments of the present invention are described with reference to flowchart illustrations and/or block diagrams of methods, terminal devices (systems), and computer program products according to embodiments of the invention. It will be understood that each flow and/or block of the flowchart illustrations and/or block diagrams, and combinations of flows and/or blocks in the flowchart illustrations and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing terminal device to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing terminal device, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be stored in a computer-readable memory that can direct a computer or other programmable data processing apparatus to function in a particular manner, such that the instructions stored in the computer-readable memory produce an article of manufacture including instruction means which implement the function specified in the flowchart flow or flows and/or block diagram block or blocks.

These computer program instructions may also be loaded onto a computer or other programmable data processing apparatus to cause a series of operational steps to be performed on the computer or other programmable apparatus to produce a computer implemented process such that the instructions which execute on the computer or other programmable apparatus provide steps for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

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. It is therefore intended that the following claims be interpreted as including the preferred embodiment and all such alterations and modifications as fall within the scope of the embodiments of the invention.

Finally, it is further noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or terminal that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or terminal. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article or terminal device comprising the element.

The non-process dust removal energy management system based on the blockchain provided by the invention is described in detail, and specific examples are applied to illustrate the principle and the implementation mode of the invention, and the description of the examples is only used for helping to understand the method and the core idea of the invention; meanwhile, as those skilled in the art will have variations in the specific embodiments and application scope in accordance with the ideas of the present invention, the present description should not be construed as limiting the present invention in view of the above.

Claims (8)

1. The non-process dust removal energy management system based on the block chain is characterized by comprising a data acquisition system, a block chain server and a non-process dust removal energy management platform; wherein,,

the data acquisition system is used for acquiring energy consumption data of non-process dust removal equipment and uploading the energy consumption data to the blockchain server; wherein the energy consumption data includes a plurality of different types of energy usage;

the block chain server is used for classifying the energy consumption data according to the different types in the energy consumption data, and uploading the classified energy consumption data to a block chain for distributed storage;

the non-process dust removal energy management platform is used for sending an energy data viewing request to the blockchain server and acquiring energy consumption data returned by the blockchain server in response to the energy data viewing request.

2. The system of claim 1, wherein the data acquisition system comprises a data acquisition terminal and a data encryption module; wherein,,

the data acquisition terminal is used for acquiring the energy consumption data of the non-process dust removal equipment and sending the energy consumption data to the data encryption module;

the data encryption module is used for encrypting the energy consumption data by adopting a preset private key and uploading the encrypted energy consumption data to the blockchain server.

3. The system of claim 2, wherein the blockchain server includes a first receiving module, a second receiving module, a classification module, a first storage module, and a search module; wherein,,

the first receiving module is used for receiving the encrypted energy consumption data uploaded by the data encryption module; wherein the energy consumption data comprises corresponding equipment identifications;

the classification module is used for classifying the energy consumption data and adding a corresponding energy type identifier for the energy consumption data;

the first storage module is used for uploading the classified energy consumption data to the block chain for distributed storage;

the second receiving module is used for receiving the energy data viewing request sent by the non-process dust removal energy management platform;

the searching module is used for searching and screening the energy consumption data corresponding to the energy data viewing request from the blockchain according to the energy data viewing request sent by the non-process dust removal energy management platform, and returning the energy consumption data to the non-process dust removal energy management platform.

4. The system of claim 3, wherein the first storage module comprises a blockchain unit, an acquisition unit, an update unit, a consensus unit; wherein,,

the block chain unit is used for acquiring a block chain formed by a plurality of storage blocks; the storage block comprises a block head and a block body, wherein the block body comprises a merkel tree, and the block head comprises a tree root of the merkel tree and a hash pointer of a preamble storage block;

the obtaining unit is used for obtaining the classified energy consumption data and writing hash values corresponding to the energy consumption data of the same class into child nodes of the same subtree in the merkel tree;

the updating unit is used for acquiring current energy consumption data according to a first preset time interval and generating a corresponding current hash value according to the current energy consumption data; writing the current hash value into a corresponding child node to replace the original hash value of the child node, and obtaining an updated Meeker tree;

and the consensus unit writes the updated tree root of the Meicher tree and the hash pointer of the corresponding preamble storage block into the corresponding block head, and broadcasts the block head to other blocks in the block chain to realize consensus and obtain the updated block chain.

5. The system of claim 1, wherein the non-process dust removal energy management platform comprises a query module, a second storage module, a report management module, and a display module; wherein,,

the query module is used for sending an energy data viewing request to the blockchain server and acquiring energy consumption data returned by the blockchain server in response to the energy data viewing request;

the second storage module is used for storing the energy consumption data;

the report management module is used for counting the energy consumption data and automatically generating a corresponding data report according to the user requirement;

the display module is used for displaying the real-time state, parameters and the energy consumption data of the non-process dust removing equipment through a display screen.

6. The system of claim 5, wherein the report management module automatically generates a data report at a second predetermined time interval and stores the data report to the second storage module.

7. The system of claim 5, wherein the non-process dust removal energy management platform further comprises a trend prediction module;

the trend prediction module is used for predicting the energy consumption data from the current moment to the future moment according to the historical energy consumption data of the historical moment and the current moment input by a user, wherein the difference value between the future moment and the current moment and the difference value between the current moment and the historical moment are the same.

8. The system of any of claims 1-7, wherein the energy consumption data comprises one or more of a power usage, a compressed air usage, a water usage, and an oxygen usage of the non-process dust removal device.

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