CN112819311A - Resource allocation method and system for linking upstream and downstream enterprises by using third-party data - Google Patents

Abstract

The invention discloses a resource allocation method for linking upstream and downstream enterprises by using third-party data, which comprises the steps of obtaining first weight data of goods provided by a supplier through a transporter, and sending second weight data of the goods to a demander by the transporter; establishing a database according to the first weight data and the second weight data and analyzing in real time to obtain an analysis result; and making a supplier delivery scheme allocation according to the analysis result, and making a demand side unloading scheme allocation according to the analysis result. According to the invention, data of a supplier and a demander are connected in series through data acquisition of a transporter, three-party data is compared in real time through data streams uploaded by the transporter, so that the comparison time of multiple parties can be shortened, a database feeds back the supplier and the demander in real time, the distribution of a delivery scheme of the supplier is made according to the analysis result, the distribution of a loading and unloading scheme of the demander is made according to the analysis result, and cross-system, cross-industry and cross-enterprise link data are used for providing services to multiple parties by using data.

Description

Resource allocation method and system for linking upstream and downstream enterprises by using third-party data

Technical Field

The invention relates to the technical field of internet, in particular to a resource allocation method and a resource allocation system for linking upstream and downstream enterprises by using third-party data.

Background

Data of energy production enterprises, energy using enterprises and energy transportation enterprises at the present stage cannot be intercommunicated, three parties invest in construction projects in a data platform, a sending link and a receiving link and are repeated in multiple points, and the time for obtaining and comparing the data is delayed seriously.

The existing energy production enterprises and energy utilization enterprises respectively have data acquisition and processing systems which are not communicated with each other, and only form data comparison on fixed reconciliation dates, so that the daily transaction condition is lack of understanding.

The number of unit data acquisition platforms is small, the formed database and the applied database scheme are small, and the market effect cannot be formed.

Most of existing solutions of the internet of things are data solutions which are built by enterprises with the enterprises as data service parties in order to meet own requirements, and data use cannot meet service requirements of partners. The three-party invested construction projects are seriously repeated.

Disclosure of Invention

The invention aims to provide a resource allocation method and a resource allocation system for linking upstream and downstream enterprises by using third-party data, which solve the problems that data of energy production enterprises, energy using enterprises and energy transportation enterprises at the present stage cannot be intercommunicated, the three parties are put into construction projects at a data platform and in the processes of sending and receiving, and the time for obtaining and comparing the data by the three parties is seriously lagged.

In a first aspect, an embodiment of the present invention provides a resource allocation method for linking upstream and downstream enterprises by using third-party data, where the third party includes a supplier, a transporter and a demander, and the resource allocation method includes the following steps:

the method comprises the steps that a transporter obtains first weight data of goods provided by a supplier and second weight data of the goods sent to a demander by the transporter; wherein the first and second weight data are confirmed by three parties;

establishing a database according to the first weight data and the second weight data and analyzing in real time to obtain an analysis result;

and making a supplier delivery scheme allocation according to the analysis result, and making a demand side unloading scheme allocation according to the analysis result.

Optionally, the first weight data and the second weight data are data streams scanned by the transportation party by scanning the weight documents of the supply party and the demand party, and the data streams are used for comparing the data of the three parties in real time.

Optionally, the analysis results comprise;

loading information of a transporter arriving at a supplier and order receiving information of the transporter, and making allocation of a delivery scheme of the supplier according to the loading information and the order receiving information;

and the transport party obtains the hauling confirmation information from the supplier and makes allocation of the demand party unloading scheme according to the hauling confirmation information.

Further, the analysis result further includes:

and storing and updating information of a large amount of inventory data, and making the inventory scheme allocation of goods of the demand party according to the storing and updating information.

Further, the analysis result further includes:

the estimated time of arrival of the transporting party at the supplying or requesting party results in preparation for the supplying or requesting party.

In a second aspect, an embodiment of the present invention provides a resource allocation system for linking upstream and downstream enterprises with third-party data, where the resource allocation system includes:

the data acquisition subsystem is used for acquiring first weight data of goods provided by a supplier and second weight data of goods sent to a demander by a transporter; wherein the first and second weight data are confirmed by three parties;

the database subsystem is used for establishing a database according to the first weight data and the second weight data and analyzing in real time to obtain an analysis result;

and the allocation subsystem is used for allocating the delivery scheme of the supplier according to the analysis result and allocating the receiving and unloading scheme of the demand side according to the analysis result.

Optionally, the first weight data and the second weight data are data streams scanned by the transportation party by scanning the weight documents of the supply party and the demand party, and the data streams are used for comparing the data of the three parties in real time.

The database establishing method comprises the following steps:

the demand side initiates a pull order by using a browser interface;

the transport party receives the order and registers driver information on a browser interface;

a driver confirms and executes an order on a browser interface, and confirms pull information for the first time after obtaining the first weight data from a delivery site;

acquiring the second weight data after the driver pulls the goods to a demand side and uploading the second weight data to a database;

the database is fed back to the demand side and the supply side for real-time data comparison, and the database is recorded after the two sides verify.

Optionally, the data analysis subsystem comprises:

the supplier shipping scheme allocation module is used for outputting loading information of a transporter arriving at a supplier and order receiving information of the transporter, and making supplier shipping scheme allocation according to the loading information and the order receiving information;

the demand side goods stock scheme allocation module is used for outputting the hauling confirmation information obtained by the transport side at the supplier and making demand side loading and unloading scheme allocation according to the hauling confirmation information;

the estimation module is used for outputting the estimation time result of the arrival of the transport party at the supplier or the demander so as to make the supplier or the demander ready;

and the demand side goods inventory allocation module is used for outputting storage updating information of a large amount of inventory data and making demand side goods inventory allocation according to the storage updating information.

Optionally, the resource allocation system is applied to energy production enterprises, energy utilization enterprises and energy transportation enterprises.

Advantageous effects

The invention provides a resource allocation method and a resource allocation system for linking upstream and downstream enterprises by using third-party data, wherein a transporter acquires first weight data of goods provided by a supplier and second weight data of goods sent to a demander by the transporter; establishing a database according to the first weight data and the second weight data and analyzing in real time to obtain an analysis result; and making a supplier delivery scheme allocation according to the analysis result, and making a demand side unloading scheme allocation according to the analysis result. According to the invention, data of a supplier and a demander are connected in series through data acquisition of a transporter, three-party data are compared in real time through data streams uploaded by the transporter, so that the comparison time of multiple parties can be shortened, a database feeds back the supplier and the demander in real time, the distribution of a delivery scheme of the supplier is made according to the analysis result, and the distribution of a loading and unloading scheme of the demander is made according to the analysis result; the invention is cross-system, cross-industry and cross-enterprise link data, and uses data to serve multiple parties.

Drawings

FIG. 1 is a flowchart of a resource deployment method for linking upstream and downstream enterprises with third-party data according to an embodiment of the present invention;

FIG. 2 is a flow chart of a database establishment process according to an embodiment of the present invention;

FIG. 3 is a block diagram of a resource deployment system for linking upstream and downstream enterprises with third-party data according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a data analysis subsystem according to an embodiment of the present invention.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the following embodiments, and it should be understood that the described embodiments are some, but not all, embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The invention aims to provide a resource allocation method and a resource allocation system for linking upstream and downstream enterprises by using third-party data, which solve the problems that data of energy production enterprises (suppliers), energy using enterprises (demanders) and energy transportation enterprises (transporters) at the present stage cannot be intercommunicated, the three parties invest in construction projects at a data platform and in the links of sending and receiving, and the time for obtaining and comparing the data by the three parties is seriously delayed, and the invention is further described by combining the description of the attached drawings with a specific embodiment:

fig. 1 is a flowchart illustrating a resource deployment method for linking upstream and downstream enterprises with third-party data according to an embodiment of the present invention, where as shown in fig. 1, the resource deployment method includes the following steps:

s20, the transporter acquires first weight data of goods provided by the supplier and second weight data of goods sent to the demander by the transporter; wherein the first and second weight data are confirmed by three parties;

s40, establishing a database according to the first weight data and the second weight data, and analyzing in real time to obtain an analysis result;

and S60, making supplier delivery scheme allocation according to the analysis result, and making demand side unloading scheme allocation according to the analysis result.

The embodiment provides a resource allocation method for linking upstream and downstream enterprises by using third-party data, which comprises the steps of obtaining first weight data of goods provided by a supplier through a transporter, and sending second weight data of the goods to a demander by the transporter; establishing a database according to the first weight data and the second weight data and analyzing in real time to obtain an analysis result; and making a supplier delivery scheme allocation according to the analysis result, and making a demand side unloading scheme allocation according to the analysis result. In the embodiment, data of a supplier and data of a demander are connected in series through data acquisition of a transporter, three-party data are compared in real time through data streams uploaded by the transporter, so that the comparison time of multiple parties can be shortened, a database feeds back the supplier and the demander in real time, the distribution of a delivery scheme of the supplier is made according to an analysis result, the distribution of a loading and unloading scheme of the demander is made according to the analysis result, and cross-system, cross-industry and cross-enterprise link data serve multiple parties through the data.

In some embodiments, the first weight data and the second weight data are data streams scanned by a transporter by scanning weight documents of a supplier and a demander, and three-party data is compared in real time through the data streams; the method has the advantages that real-time account checking is achieved, in the prior art, the existing image acquisition software is multiple in types and mainly used for acquiring license plates, paper data and the like, the technology is mature, and the acquired information and multi-party data are not compared and combined.

In some embodiments, the analysis results comprise;

the unloading information of the transport party reaching the demand party and the order receiving information of the transport party make the distribution of the delivery scheme of the supply party according to the loading information and the order receiving information; and optimizing the transportation resources.

The method comprises the following steps that a transporter obtains pull confirmation information from a supplier, and allocation of a demand side unloading scheme is made according to the pull confirmation information; and estimating the factory time through the hauling confirmation information, and allocating the unloading time of the demand party.

In some embodiments, the analysis results further comprise:

and storing and updating information of a large amount of inventory data, and making the inventory scheme allocation of goods of the demand party according to the storing and updating information.

In some embodiments, the analysis results further comprise:

the estimated time of arrival of the transporting party at the supplying or requesting party results in preparation for the supplying or requesting party.

The following description of the advantageous effects of the present invention is given in a preferred embodiment with reference to specific background:

most of existing solutions of the internet of things are data solutions which are built by enterprises with the enterprises as data service parties in order to meet own requirements, and data use cannot meet service requirements of partners. The three-party invested construction projects are seriously repeated.

Such as: a weighing system is established and data are collected in a coal mine pound room (supplier), a weighing system is established and data are collected in a coal enterprise (demander), and a dispatching platform is established for carrying fleets (transporters). The three-party platforms are not intercommunicated, and the data of the carrying fleet are only used for invoicing and account checking with the driver.

The coal mine enterprise (supplier) and the coal using enterprise (demander) export respective data monthly and then reconcile the data, and then reconcile the reconciled data with a carrying fleet (transporter). Coal consumption units do not know how many vehicles and coal are transported to the enterprises on the way every day, and coal production enterprises do not know how many vehicles are used for coal mining and loading every day. In order to guarantee coal consumption, coal enterprises keep the inventory at 3 days. In order to reduce coal mine safety accidents, production enterprises do not allow too many vehicles to enter a mining area for waiting, and a large number of vehicles queue to two sides of roads outside the mining area to block traffic. The driver stands by in the vehicle at any time in order to queue. The queuing time will often last 1-2 days.

In order to solve the above technical problems, the resource allocation method for linking upstream and downstream enterprises by using third-party data according to the present invention may be adopted.

Specifically, as shown in FIG. 2

1. Database building process

S1, the demand side initiates a pull order by using a browser interface;

s2, the transportation party receives the order and registers the driver information on the browser interface;

s3, the driver confirms the order and executes the order on the browser interface, and confirms the pulling information for the first time after obtaining the first weight data at the delivery site;

s4, acquiring the second weight data after the driver pulls the goods to a demand side, and uploading the second weight data to a database;

and S5, feeding back the database to the demand side and the supply side for real-time data comparison, and recording the database after verification by the two sides.

2. Calculation, analysis and output of the database (the following steps can be carried out simultaneously and not in sequence)

S6, outputting loading information of a transporter arriving at a supplier and order receiving information of the transporter, and making allocation of a delivery scheme of the supplier according to the loading information and the order receiving information; queuing vehicles are reduced by adjusting the plan, and the safety factor in the mine is increased.

S7, outputting the hauling confirmation information obtained by the transport party at the supplier, and making the allocation of the demand party unloading scheme according to the hauling confirmation information; for example, the arrival time may be estimated, and the unloading time may be scheduled.

S8, outputting the estimated time result of the arrival of the transport party at the supplier or the demander so as to make the supplier or the demander ready;

and S9, outputting storage updating information of a large amount of inventory data, and making inventory allocation of goods of a demand side according to the storage updating information.

Based on the same inventive concept, the embodiment of the present application further provides a resource deployment system for linking upstream and downstream enterprises with third-party data, which can be used to implement the method described in the above embodiments, as described in the following embodiments. Because the principle of solving the problem of the resource allocation system for linking upstream and downstream enterprises by using the third-party data is similar to the resource allocation method for linking upstream and downstream enterprises by using the third-party data, the implementation of the resource allocation system for linking upstream and downstream enterprises by using the third-party data can refer to the implementation of the resource allocation method for linking upstream and downstream enterprises by using the third-party data, and repeated parts are not repeated. As used hereinafter, the terms "system," "subsystem" or "module" may refer to a combination of software and/or hardware that performs a predetermined function. While the system described in the embodiments below is preferably implemented in software, implementations in hardware, or a combination of software and hardware are also possible and contemplated.

Specifically, as shown in fig. 3, the resource allocation system according to the embodiment of the present invention includes:

a data acquisition subsystem 20 for acquiring first weight data of goods provided by a supplier and second weight data of goods delivered by a transporter to a demander; wherein the first and second weight data are confirmed by three parties;

the database subsystem 40 is used for establishing a database according to the first weight data and the second weight data and analyzing in real time to obtain an analysis result;

and the allocating subsystem 60 is used for allocating the delivery scheme of the supplier according to the analysis result and allocating the receiving and unloading scheme of the demand side according to the analysis result.

The embodiment provides a resource allocation system for linking upstream and downstream enterprises by using third-party data, a transporter acquires first weight data of goods provided by a supplier and second weight data of the goods sent to a demander by the transporter through a data acquisition subsystem 20; the database subsystem 40 establishes a database according to the first weight data and the second weight data and analyzes the database in real time to obtain an analysis result; the deploying subsystem 60 deploys the delivery scheme of the supplier according to the analysis result and deploys the unloading scheme of the demand side according to the analysis result. In the embodiment, data of a supplier and data of a demander are connected in series through data acquisition of a transporter, three-party data are compared in real time through data streams uploaded by the transporter, so that the comparison time of multiple parties can be shortened, a database feeds back the supplier and the demander in real time, the distribution of a delivery scheme of the supplier is made according to an analysis result, the distribution of a loading and unloading scheme of the demander is made according to the analysis result, and cross-system, cross-industry and cross-enterprise link data serve multiple parties through the data.

Preferably, the first weight data and the second weight data are data streams scanned by a transporter through scanning weight documents of a supplier and a demander, and the data streams are used for comparing three-party data in real time.

In some embodiments, the database establishing method includes:

s1, the demand side initiates a pull order by using a browser interface;

s2, the transportation party receives the order and registers the driver information on the browser interface;

s3, the driver confirms the order and executes the order on the browser interface, and confirms the pulling information for the first time after obtaining the first weight data at the delivery site;

s4, acquiring the second weight data after the driver pulls the goods to a demand side, and uploading the second weight data to a database;

and S5, feeding back the database to the demand side and the supply side for real-time data comparison, and recording the database after verification by the two sides.

Preferably, the data analysis subsystem 40 comprises:

a supplier shipping scheme allocating module 401, configured to output loading information that a transporter arrives at a supplier and order receiving information of the transporter, and make a supplier shipping scheme allocation according to the loading information and the order receiving information;

a demand party goods inventory scheme allocation module 402, configured to output the pull transport confirmation information obtained by the transport party at the supplier, and make demand party goods inventory scheme allocation according to the storage update information;

an estimation module 403, configured to output an estimated time result of arrival of the transportation party at the supplier or the demander so as to prepare the supplier or the demander;

and the demander goods inventory allocation module 404 is configured to output storage update information of a large amount of inventory data, and make demander goods inventory allocation according to the storage update information.

The resource allocation system is applied to energy production enterprises, energy utilization enterprises and energy transportation enterprises.

The flowchart and block diagrams in the figures illustrate the architecture, functionality, and operation of possible implementations of systems, methods and computer program products according to various embodiments of the present invention. In this regard, each block in the flowchart or block diagrams may represent a module, segment, or portion of code, which comprises one or more executable instructions for implementing the specified logical function(s). It should also be noted that, in some alternative implementations, the functions noted in the block may occur out of the order noted in the figures. For example, two blocks shown in succession may, in fact, be executed substantially concurrently, or the blocks may sometimes be executed in the reverse order, depending upon the functionality involved. It will also be noted that each block of the block diagrams and/or flowchart illustration, and combinations of blocks in the block diagrams and/or flowchart illustration, can be implemented by special purpose hardware-based systems which perform the specified functions or acts, or combinations of special purpose hardware and computer instructions.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; while the invention has been described in detail and with reference to the foregoing embodiments, it will be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; and the modifications or the substitutions do not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (10)

1. a resource allocation method for linking upstream and downstream enterprises with third-party data, the three parties include a supplier, a transporter and a demander, and it is characterized in that the resource allocation method comprises the following steps: The transporter obtains the first weight data of the goods provided by the supplier, and the second weight data of the transporter sending the goods to the demander; wherein, the first and second weight data are confirmed by three parties; Establish a database according to the first weight data and the second weight data and analyze in real time to obtain analysis results; According to the analysis result, the supply-side shipping plan is deployed, and the demand-side receiving and unloading plan is deployed according to the analysis result. 2 . The resource allocation method according to claim 1 , wherein the first weight data and the second weight data are data streams scanned by the transporter by scanning the weight documents of the supplier and the demander. 3 . The data stream compares three-party data in real time. 3. The resource allocation method according to claim 2, wherein the analysis result comprises: The loading information of the transporter arriving at the supplier and the order receiving information of the transporter, and the supplier's shipping plan deployment is made according to the loading information and the ordering information; According to the pull confirmation information obtained by the transporter from the supplier, the demand-side unloading plan is allocated according to the pull confirmation information. 4. The resource allocation method according to claim 3, wherein the analysis result further comprises: Storage update information of a large amount of inventory data, according to the storage update information, make inventory plan allocation of demand-side goods. 5. The resource allocation method according to claim 3, wherein the analysis result further comprises: The result of the estimated time for the transporter to arrive at the supply or demand side so that the supply or demand side is ready for work. 6. A resource allocation system for linking upstream and downstream enterprises with third-party data, wherein the resource allocation system comprises: The data acquisition subsystem is used to acquire the first weight data of the goods provided by the supplier, and the second weight data of the goods sent by the transporter to the demander; wherein, the first and second weight data are passed through three parties comfirmed; a database subsystem for establishing a database according to the first weight data and the second weight data and performing analysis in real time to obtain analysis results; The deployment subsystem is configured to deploy the supply-side shipping plan according to the analysis result, and prepare the demand-side unloading plan deployment according to the analysis result. 7 . The resource allocation system according to claim 6 , wherein the first weight data and the second weight data are data streams scanned by the transporter by scanning the weight documents of the supplier and the demander. 8 . The data stream compares three-party data in real time. 8. The resource allocation system according to claim 6, wherein the method for establishing the database comprises: The demander uses the browser interface to initiate a pull order; The transporter receives the order and registers the driver information on the browser interface; The driver confirms the order on the browser interface and executes it, and then confirms the shipping information for the first time after obtaining the first weight data at the shipping site; After the driver pulls the goods to the demander, he obtains the second weight data and uploads it to the database; The database is fed back to the demander and the supplier for real-time data comparison, and the database is included after verification by both parties. 9. The resource allocation system according to claim 6, wherein the data analysis subsystem comprises: The supply-side shipping plan deployment module is used to output the loading information of the transporter reaching the supplier and the order-receiving information of the transporter, and make the supply-side shipping plan deployment according to the loading information and the order-taking information; The demand-side goods inventory plan allocation module is used to output the pull confirmation information obtained by the transporter from the supplier, and make the demand-side unloading plan allocation according to the pull confirmation information; The estimation module is used to output the estimated time result of the transporter arriving at the supplier or the demander, so that the supplier or the demander can prepare for the work; The demand-side goods inventory allocation module is used to output storage update information of a large amount of inventory data, and make demand-side goods inventory allocation according to the storage update information. 10 . The resource allocation system according to claim 6 , wherein the resource allocation system is applied to an energy production enterprise, an energy user enterprise, and an energy transportation enterprise. 11 .

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