CN116248712A - Method, device, storage medium, electronic equipment and system for processing data of oiling machine - Google Patents

Abstract

The invention discloses a method, a device, a storage medium, electronic equipment and a system for processing data of an oiling machine, and relates to the technical field of oiling machines. Wherein the method is applied to a hub including at least one first data acquisition channel, each first data acquisition channel for connection with a communications module of a fuel dispenser, the method comprising: acquiring original data sent by at least one oiling machine through a first data acquisition channel; determining a data analysis protocol corresponding to each first data acquisition channel according to the preconfigured hub channel information; analyzing the original data sent by each oiling machine based on the data analysis protocol corresponding to each first data acquisition channel to obtain the operation data and the gun state data of each oiling machine. The method can be used for simultaneously butting oiling machines of various types and types, can improve the data acquisition efficiency of the oiling machine, and can reduce the digital reconstruction cost of the oiling machine due to the simple connection mode.

Description

Method, device, storage medium, electronic equipment and system for processing data of oiling machine

Technical Field

The invention relates to the technical field of oiling machines, in particular to a method, a device, a storage medium, electronic equipment and a system for processing data of an oiling machine.

Background

Along with the continuous promotion of the digital construction of the gas station, the digital transformation work of the data acquisition of the oiling machine, the control of the oil gun and the like is also continuously increased. In the prior art, the oil filling machine is mainly connected with the hub, and the collected data are analyzed and the oil gun is controlled through the hub.

However, the manufacturers and models of fuel dispensers in many fuel stations today are different, and the existing hubs are usually only capable of docking with fuel dispensers of a single model, so that the cost of digitally retrofitting fuel dispensers is very high and the circuit arrangement is very complex.

Disclosure of Invention

In view of this, the application provides a method, a device, a storage medium, an electronic device and a system for processing data of a fuel dispenser, and aims to solve the technical problems of single model and complex circuit arrangement of a hub docking fuel dispenser.

According to a first aspect of the present invention there is provided a fuel dispenser data processing method for use with a hub, the hub including at least one first data acquisition channel, each for connection to a communications module of a fuel dispenser, the method comprising:

Acquiring original data sent by at least one oiling machine through the first data acquisition channel;

determining a data analysis protocol corresponding to each first data acquisition channel according to preconfigured hub channel information;

analyzing the original data sent by each oiling machine based on the data analysis protocol corresponding to each first data acquisition channel to obtain the operation data and the oil gun state data of each oiling machine.

According to a second aspect of the present invention there is provided a fuel dispenser data processing apparatus, the apparatus comprising:

the data acquisition module is used for acquiring the original data sent by at least one oiling machine through the first data acquisition channel;

the protocol determining module is used for determining a data analysis protocol corresponding to each first data acquisition channel according to the preconfigured hub channel information;

the data analysis module is used for analyzing the original data sent by each oiling machine based on the data analysis protocol corresponding to each first data acquisition channel to obtain the operation data and the gun state data of each oiling machine.

According to a third aspect of the present invention, there is provided a storage medium having stored thereon a computer program which when executed by a processor implements the fuel dispenser data processing method described above.

According to a fourth aspect of the present invention there is provided a computer device comprising a memory, a processor and a computer program stored on the memory and executable on the processor, the processor implementing the fuel dispenser data processing method described above when executing the program.

According to a fifth aspect of the present invention there is provided a fuel dispenser data processing system comprising at least one fuel dispenser, a hub and a zero line system, wherein the hub comprises at least one first data acquisition channel, each of the first data acquisition channels being connected to a communications module of one of the fuel dispensers, the hub being further communicatively connected to the zero line system via a network, the hub performing the fuel dispenser data processing method described above.

According to the oiling machine data processing method, the device, the storage medium, the electronic equipment and the system, the plurality of first data acquisition channels of the hub are connected with the communication module of each oiling machine, and the original data sent by each oiling machine are sequentially analyzed through the data analysis protocol corresponding to each data acquisition channel which is pre-configured, so that the running data and the oil gun state data of each oiling machine are obtained, the hub can be connected with oiling machines of various types and types at the same time, and therefore the data acquisition efficiency of the oiling machine is effectively improved. In addition, the hub and the oiling machine are connected in a simple mode, the complexity of circuit arrangement is low, and the digital transformation cost of the oiling machine can be effectively reduced.

The foregoing description is only an overview of the technical solutions of the present application, and may be implemented according to the content of the specification in order to make the technical means of the present application more clearly understood, and in order to make the above-mentioned and other objects, features and advantages of the present application more clearly understood, the following detailed description of the present application will be given.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiments of the invention and together with the description serve to explain the invention and do not constitute a limitation on the invention. In the drawings:

FIG. 1 shows a schematic flow chart of a method for processing data of a fuel dispenser according to an embodiment of the present invention;

FIG. 2 is a schematic flow chart of another method for processing data of a fuel dispenser according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of a fuel dispenser data processing apparatus according to an embodiment of the present invention;

FIG. 4 is a schematic diagram of another fuel dispenser data processing apparatus according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of a fuel dispenser data processing system according to an embodiment of the present invention;

FIG. 6 illustrates a schematic diagram of another fuel dispenser data processing system provided in accordance with an embodiment of the present invention.

Detailed Description

The invention will be described in detail hereinafter with reference to the drawings in conjunction with embodiments. It should be noted that, in the case of no conflict, the embodiments and features in the embodiments may be combined with each other.

In one embodiment, as shown in fig. 1, there is provided a fuel dispenser data processing method, which is exemplified as the method applied to a hub, and includes the steps of:

101. and acquiring the original data sent by at least one oiling machine through a first data acquisition channel.

102. And determining a data analysis protocol corresponding to each first data acquisition channel according to the preconfigured hub channel information.

103. Analyzing the original data sent by each oiling machine based on the data analysis protocol corresponding to each first data acquisition channel to obtain the operation data and the gun state data of each oiling machine.

Specifically, the first data acquisition channel refers to a data acquisition module reserved by the hub. In this embodiment, the hub is provided with a plurality of data acquisition modules, each data acquisition module reserves a data acquisition interface for the outside, and the data acquisition interface is connected with the data acquisition interface of the oiling machine, so that the original data sent by the oiling machine can be acquired. Further, the hub is preconfigured with hub channel information, and the hub channel information includes channel information of each first data acquisition channel, for example, channel number, protocol number, communication parameters (baud rate, data bit, check bit, stop bit, etc.), automatic authorization flag, oil engine log flag, oil gun number, oil product code, etc. of the first data acquisition channel.

Further, the controller of the hub is encapsulated with data analysis protocols of various signals and types of oiling machines, the data analysis protocol corresponding to each first data acquisition channel can be determined through the channel information of each first data acquisition channel, and the original data sent by each oiling machine can be analyzed based on the data analysis protocol corresponding to each first data acquisition channel to obtain the operation data and the gun state data of each oiling machine. In this embodiment, the operation data of the fuel dispenser include transaction data and real-time data, wherein the transaction data refers to data generated by the fuel dispenser during the fuel filling process of the vehicle, including transaction price, fuel filling rising number, fuel filling time, etc., the real-time data refers to information that the fuel dispenser may change during the transaction process, such as unit price of fuel, fuel rising number, etc., and the fuel gun status data refers to information about the use status of each fuel gun in the fuel dispenser (including gun lifting status and gun discharging status), and corresponding fuel gun number, etc.

Furthermore, after the operation data of the oiling machine and the state data of the oil gun are analyzed, the hub can store the data in an internal memory, and the data can be sent to a third-party data platform through a communication module, so that the timely uploading of the data is realized. In this embodiment, the third party data platform may refer to a preset SAAS (Software-as-a-Service) platform. Further, the operation data of the oiling machine and the state data of the oil gun can be sent to the third party data platform in a timing mode, and also can be sent to the third party data platform in a real-time mode. In the process of uploading data in real time, if the running data and the oil gun state data are not changed, the running data and the oil gun state data can be not uploaded first, and when the data are waited to change, the changed running data and the changed oil gun state data are sent to a third party data platform, so that the communication times are reduced, and the data redundancy is avoided.

According to the oiling machine data processing method, the plurality of first data acquisition channels of the hub are connected with the communication module of each oiling machine, and the original data sent by each oiling machine are sequentially analyzed through the data analysis protocol corresponding to each data acquisition channel which is configured in advance, so that the operation data and the oil gun state data of each oiling machine are obtained, the hub can be simultaneously connected with oiling machines of various types and types, and therefore the data acquisition efficiency of the oiling machines is effectively improved. In addition, the hub and the oiling machine are connected in a simple mode, the complexity of circuit arrangement is low, and the digital transformation cost of the oiling machine can be effectively reduced.

Further, as a refinement and extension of the specific implementation manner of the foregoing embodiment, for a complete description of the implementation process of the embodiment, a method for processing data of a fuel dispenser is provided, as shown in fig. 2, and the method includes the following steps:

201. hub channel information transmitted by a configuration tool connected to a hub network is received and stored in a memory of the hub.

Specifically, the computer device on which the configuration tool is installed may be network-connected to the hub through the IP address and port number of the hub. The channel information of each data acquisition channel (including the first data acquisition channel and the second data acquisition channel) of the hub can be configured by a configuration tool. The channel information of the first data acquisition channel may include information such as a channel number, a protocol number, a communication parameter, an automatic authorization flag, an oil engine log flag, the number of oil guns, and an oil product code of the first data acquisition channel, and the channel information of the second data acquisition channel may include information such as a channel number, a protocol number, and a communication parameter of the second data acquisition channel. After the configuration of the configuration tool is completed, the channel information of each data acquisition channel can be issued to the hub through the network, so that the hub can store the channel information of each data acquisition channel in the memory of the hub.

202. And acquiring the original data sent by at least one oiling machine through a first data acquisition channel.

203. And determining a data analysis protocol corresponding to each first data acquisition channel according to the preconfigured hub channel information.

204. Analyzing the original data sent by each oiling machine based on the data analysis protocol corresponding to each first data acquisition channel to obtain the operation data and the gun state data of each oiling machine.

Specifically, the hub can collect the original data sent by the oiling machine by connecting the data collection interface of the first data collection channel reserved on the hub with the data collection interface of the oiling machine, wherein each first data collection channel on the hub is connected with the communication module of one oiling machine and is used for collecting the original data sent by one oiling machine. Further, the controller of the hub is encapsulated with data analysis protocols of oiling machines of various types and types, the data analysis protocol corresponding to each first data acquisition channel can be determined through the channel information of the preconfigured first data acquisition channel, and the original data sent by each oiling machine can be analyzed based on the data analysis protocol corresponding to each first data acquisition channel to obtain the operation data and the gun state data of each oiling machine. The transaction data refers to data generated by the oiling machine in the vehicle oiling process, including transaction price, oiling rising number, oiling time and the like, and the real-time data refers to information that the oiling machine possibly changes in the transaction process, such as oil unit price, oil rising number and the like.

In one embodiment, the hub may automatically adapt to multiple types of oil machines, including active or passive oil dispensers, where active fuel dispensers refer to fuel dispensers that actively transmit data, and passive fuel dispensers refer to fuel dispensers that transmit response data after receiving a proper command. In addition, the hub can also actively inquire about information in the oiling machine or set about information in the oiling machine, for example, the hub can inquire about accumulated output oil quantity of the oil machine, set or cancel quantitative oiling, set or inquire unit price of the oil machine, set or inquire operation mode of the oil machine and the like. It should be noted that, the different modes of operation set by the fuel dispenser are different, and there are two common modes of online and offline, wherein the online mode refers to that an authorized command needs to be sent to the fuel dispenser after the fuel dispenser lifts a gun, and the offline mode refers to that the fuel dispenser can fill fuel without the authorized command after the fuel dispenser lifts the gun. It will be appreciated that the modes of the fuel dispenser are different for different brands and models, and that each mode may operate differently, and are not illustrated here.

In this embodiment, the hub querying the data in the fuel dispenser may be accomplished by: responding to a first information inquiry request, sending the first information inquiry request to the oiling machine through the first data acquisition channel, wherein the first information inquiry request carries at least one of accumulated output oil quantity of the oiling machine, unit price of oil and working mode of the oiling machine, receiving first inquiry response information sent by the oiling machine, analyzing the first inquiry response information based on a data analysis protocol corresponding to the first data acquisition channel to obtain a first information inquiry result, and storing the first information inquiry result in a memory of the hub. In this embodiment, the hub may query one or more types of data in the fuel dispenser simultaneously through the first information query request, and the hub may query the data in the fuel dispenser in a timed manner, so that the collection efficiency of the fuel dispenser data may be effectively improved by actively querying the data in the fuel dispenser.

In this embodiment, the hub may be configured to store data in the fuel dispenser by: responding to a first information setting request, sending the first information setting request to the oiling machine through the first data acquisition channel, wherein the first information setting request carries at least one of a quantitative oiling start instruction, a quantitative oiling close instruction, an oil unit price and an oiling machine working mode, receiving setting response information of the oiling machine, and analyzing the setting response information through a data analysis protocol corresponding to the first data acquisition channel to obtain an information setting result. In this embodiment, the hub may set one or more data in the fuel dispenser simultaneously through the first information setting request, and in other embodiments, the hub may not accept the setting response information sent by the fuel dispenser. According to the embodiment, the data in the oiling machine is actively set, so that the processing efficiency of the data of the oiling machine can be effectively improved.

205. And acquiring the original data sent by the at least one liquid level instrument through a second data acquisition channel.

206. And determining a data analysis protocol corresponding to each second data acquisition channel according to the hub channel information.

207. And analyzing the original data sent by each liquid level instrument based on a data analysis protocol corresponding to each second data acquisition channel to obtain the oil tank data of each liquid level instrument.

Specifically, the data acquisition interface of the second data acquisition channel reserved on the hub is connected with the data acquisition interface of the liquid level instrument, the hub can acquire the original data sent by the liquid level instrument, and each second data acquisition channel on the hub is connected with the communication module of one liquid level instrument and is used for acquiring the original data sent by one liquid level instrument. Further, the controller of the hub is packaged with data analysis protocols of liquid level meters with various types and types, the data analysis protocol corresponding to each second data acquisition channel can be determined through the channel information of the second data acquisition channel which is configured in advance, and the original data sent by each liquid level meter can be analyzed based on the data analysis protocol corresponding to each second data acquisition channel to obtain oil tank data of each liquid level meter, wherein the oil tank data can comprise data such as oil volume, water volume, oil height, water height, temperature, pressure, density, oil inlet quantity, side leakage quantity and the like.

In one embodiment, the hub can also actively query the relevant information in the liquid level meter, and the specific implementation manner is as follows: responding to a second information inquiry request, and sending the second information inquiry request to the liquid level meter through the second data acquisition channel, wherein the second information inquiry request carries at least one of oil volume, water volume, oil height, water height, temperature, pressure, density, oil inlet amount and side leakage amount; receiving second query response information sent by the liquid level instrument, and analyzing the second query response information based on a data analysis protocol corresponding to the second data acquisition channel to obtain a second information query result; and storing the second information inquiry result in a memory of the hub. In this embodiment, the hub may query one or more types of data in the liquid level meter through the second information query request, and the hub may query the data in the liquid level meter in a timing manner, so that the collection efficiency of the data in the liquid level meter may be effectively improved by actively querying the data in the liquid level meter.

208. The operation data of the oiling machine and the oil gun state data and the oil tank data of the liquid level meter are stored in a memory of the hub.

In particular, the hub may store data through MRAM to prevent loss of data from powering down. In this embodiment, the data in the hub mainly includes two parts, namely fixed data content and cached oil engine data. Wherein, the fixed data content mainly comprises system information, oil gun information, channel information and the like. The system information includes data version, system IP address, system time, last start time, accumulated start times, system running state, program start error count, etc., the oil gun information includes gun number, gun state, last refuel amount/liter, pump code, state flag, gun lifting time, oil machine trade serial number, card type and card number of the refuel card, etc., and the channel information includes channel number, trade number and trade data list, etc. Furthermore, the cached oil engine data mainly comprises real-time information and transaction data of the oil filling machine, wherein after the transaction data are cached to a certain number, the transaction data can be written into a local transaction file, so that the number of times of writing the flash is reduced, and the service life of the flash is prolonged.

In one embodiment, the hub may store the collected operation data and the gun state data of each oiling machine, and the oil tank data of each level meter in a buffer space, determine whether the data amount in the buffer space reaches a preset value, and store the transaction data and the oil tank data in the buffer space in the memory of the hub if the data amount in the buffer space reaches the preset value. In addition, the hub can also realize the function of losing-prevention of the power-down data, namely, when the hub is powered down, the operation data and the oil gun state data of each oiling machine acquired last time and the oil tank data of each liquid level instrument acquired last time are stored in a memory of the hub.

209. And transmitting the operation data of the oiling machine and the oil gun state data stored in the hub and the oil tank data of the liquid level meter to a zero pipe system.

Specifically, the hub may communicate with a zero management system through a wired network, and the zero management system may query or set related information in the hub through the network, including: inquiring or setting configuration information of a hub, inquiring oil engine transaction data stored by the hub, inquiring or setting hub time, inquiring maximum transaction serial number stored by the hub, authorizing or canceling authorized oiling, inquiring accumulated output oil quantity of an oil gun, setting or inquiring unit price of an oil engine, acquiring oil tank data and the like. In this embodiment, the hub configuration information may be manually configured through a configuration tool, or may be remotely configured through a zero management system, where the zero management system may actively query the data of the hub, or the hub may actively report the data to the zero management system.

In one embodiment, the data in the zero-pipe system query hub may be implemented by the following method: and receiving a third information inquiry request sent by the zero management system, and determining information to be inquired according to information carried in the third information inquiry request, wherein the third information inquiry request carries at least one of information of hub channel information, transaction data, oil tank data, hub time, accumulated output oil quantity of an oil filling machine and unit price of oil, reading an inquiry result corresponding to the information to be inquired in a memory of the hub, and sending the inquiry result to the zero management system. In this embodiment, the zero management system may query one or more data in the hub through the third information query request, and may query the data in the hub in a timing manner, and may effectively improve the processing efficiency of the fuel dispenser data by actively querying the data in the hub.

In one embodiment, the data in the zero pipe system setup hub may be implemented by: receiving a second information setting request sent by the zero pipe system, and determining information to be set according to information carried in the second information setting request, wherein the second information setting request carries at least one of hub channel information, hub time, an authorized oiling start instruction, an authorized oiling close instruction and an oil unit price, setting the information to be set according to a value corresponding to the information carried in the second information setting request, and storing a setting result in a memory of the hub. In this embodiment, the zero pipe system may set one or more data in the hub simultaneously through the second information setting request. According to the embodiment, the data in the hub is actively set, so that the processing efficiency of the data of the oiling machine can be effectively improved.

In the above embodiment, from the hardware, the hub can support hardware equipment access of multiple protocols and interfaces, from the software, each channel of the hub can support hardware of different protocols, and by adding the protocols in the configuration tool, any new serial port hardware access can be supported, including equipment such as oiling machines and liquid level meters of various types. Based on the above, the hub can guarantee the high efficiency of data acquisition and oil engine control from both hardware and software aspects, thereby reducing the complexity of connecting and wiring the hub with each device in the oil station and simultaneously reducing the digital reconstruction cost of the oiling machine.

According to the oiling machine data processing method, the first data acquisition channel of the concentrator is connected with the communication module of each oiling machine, the second data acquisition channel of the concentrator is connected with the communication module of each liquid level meter, and the original data sent by each oiling machine and the liquid level meter are sequentially analyzed through preconfigured concentrator channel information to obtain the running data and the oil gun state data of each oiling machine and the oil tank data of each liquid level meter, so that the concentrator can be simultaneously abutted to oiling machines and liquid level meters of various types, and the data acquisition efficiency of the oiling machines and the liquid level meters is effectively improved. In addition, the method supports various data query modes and data setting modes, can effectively improve the data processing efficiency of the oiling machine and the liquid level instrument, is simple in connection mode of the hub and the oiling machine and the liquid level instrument, is low in line arrangement complexity, and can effectively reduce the digital transformation cost of the oiling machine and the liquid level instrument.

Further, as a specific implementation of the methods shown in fig. 1 and fig. 2, the present embodiment provides a data processing device of a fuel dispenser, as shown in fig. 3, where the device includes: a data acquisition module 31, a protocol determination module 32, and a data parsing module 33, wherein,

The data acquisition module 31 is configured to acquire, through the first data acquisition channel, raw data sent by at least one fuel dispenser;

the protocol determining module 32 is configured to determine a data parsing protocol corresponding to each first data acquisition channel according to preconfigured hub channel information;

the data analysis module 33 may be configured to analyze the raw data sent by each fuel dispenser based on the data analysis protocol corresponding to each first data collection channel, so as to obtain the operation data and the gun state data of each fuel dispenser.

In a specific application scenario, the data acquisition module 31 may be further configured to acquire, through the second data acquisition channel, raw data sent by at least one liquid level meter; the protocol determining module 32 is further configured to determine a data parsing protocol corresponding to each of the second data acquisition channels according to the hub channel information; the data analysis module 33 may be further configured to analyze the raw data sent by each of the liquid level meters based on a data analysis protocol corresponding to each of the second data acquisition channels, so as to obtain the oil tank data of each of the liquid level meters.

In a specific application scenario, as shown in fig. 4, the apparatus further includes a channel configuration module 34, where the channel configuration module 34 is specifically configured to receive the hub channel information sent by a configuration tool connected to the hub network, where the hub channel information includes a channel number, a protocol number, a communication parameter, an automatic authorization flag, an oil engine log flag, the number of oil guns, an oil gun number, and an oil product code of the first data acquisition channel, and a channel number, a protocol number, and a communication parameter of the second data acquisition channel; the hub channel information is stored in a memory of the hub.

In a specific application scenario, as shown in fig. 4, the apparatus further includes a data query module 35, where the data query module 35 is specifically configured to respond to a first information query request, and send the first information query request to the fuel dispenser through the first data acquisition channel, where the first information query request carries at least one of accumulated fuel output of the fuel dispenser, unit price of fuel and working mode of the fuel dispenser; receiving first query response information sent by the oiling machine, and analyzing the first query response information based on a data analysis protocol corresponding to the first data acquisition channel to obtain a first information query result; and storing the first information inquiry result in a memory of the hub.

In a specific application scenario, the data query module 35 may be further configured to send a second information query request to the liquid level meter through the second data acquisition channel in response to the second information query request, where the second information query request carries at least one of information of oil volume, water volume, oil height, water height, temperature, pressure, density, oil inlet amount, and side leakage; receiving second query response information sent by the liquid level instrument, and analyzing the second query response information based on a data analysis protocol corresponding to the second data acquisition channel to obtain a second information query result; and storing the second information inquiry result in a memory of the hub.

In a specific application scenario, as shown in fig. 4, the apparatus further includes a data setting module 36, where the data setting module 36 is specifically configured to respond to a first information setting request, and send the first information setting request to the fuel dispenser through the first data collecting channel, where the first information setting request carries at least one of a quantitative fuel filling opening instruction, a quantitative fuel filling closing instruction, a fuel unit price, and a fuel dispenser working mode; and receiving the setting response information of the oiling machine, and analyzing the setting response information through a data analysis protocol corresponding to the first data acquisition channel to obtain an information setting result.

In a specific application scenario, the data query module 35 is specifically configured to receive a third information query request sent by the zero management system, and determine information to be queried according to information carried in the third information query request, where the third information query request carries at least one of information of the hub channel, transaction data, oil tank data, hub time, accumulated output oil quantity of the oiling machine, and unit price of an oil product; and reading a query result corresponding to the information to be queried from the memory of the hub, and sending the query result to the zero management system.

In a specific application scenario, the data setting module 36 is specifically configured to receive a second information setting request sent by the zero pipe system, and determine information to be set according to information carried in the second information setting request, where the second information setting request carries at least one of information about a hub channel, a hub time, an authorized fueling start instruction, an authorized fueling close instruction, and an oil unit price; and setting the information to be set according to the value corresponding to the information carried in the second information setting request, and storing the setting result in a memory of the hub.

In a specific application scenario, as shown in fig. 4, the apparatus further includes a data storage module 37, where the data storage module 37 is specifically configured to store the operation data and the oil gun state data of each oiling machine, and the oil tank data of each level meter in a buffer space, and determine whether the data amount in the buffer space reaches a preset value; if the data volume in the cache space reaches the preset value, storing transaction data and oil tank data in the cache space in a memory of the hub; and/or when the hub is powered down, storing the operation data and the oil gun state data of each oiling machine acquired last time and the oil tank data of each liquid level instrument acquired last time in a memory of the hub.

It should be noted that, other corresponding descriptions of each functional unit related to the fuel dispenser data processing apparatus provided in this embodiment may refer to corresponding descriptions in fig. 1 and fig. 2, and are not described herein again.

Based on the above-mentioned methods shown in fig. 1 and 2, correspondingly, the present embodiment further provides a storage medium, on which a computer program is stored, which when executed by a processor, implements the above-mentioned fuel dispenser data processing method shown in fig. 1 and 2.

Based on such understanding, the technical solution of the present application may be embodied in the form of a software product, where the software product to be identified may be stored in a non-volatile storage medium (may be a CD-ROM, a U-disc, a mobile hard disk, etc.), and include several instructions for causing a computer device (may be a personal computer, a server, or a network device, etc.) to execute the method described in each implementation scenario of the present application.

Based on the method shown in fig. 1 and fig. 2, and the embodiment of the fuel dispenser data processing apparatus shown in fig. 3 and fig. 4, in order to achieve the above object, this embodiment further provides an entity device for fuel dispenser data processing, which may specifically be a personal computer, a server, a smart phone, a tablet computer, a smart watch, or other network devices, where the entity device includes a storage medium and a processor; a storage medium storing a computer program; a processor for executing a computer program to implement the method as shown in fig. 1 and 2.

Optionally, the physical device may further include a user interface, a network interface, a camera, radio Frequency (RF) circuitry, sensors, audio circuitry, WI-FI modules, and the like. The user interface may include a Display screen (Display), an input unit such as a Keyboard (Keyboard), etc., and the optional user interface may also include a USB interface, a card reader interface, etc. The network interface may optionally include a standard wired interface, a wireless interface (e.g., WI-FI interface), etc.

It will be appreciated by those skilled in the art that the physical device structure for processing data of a fuel dispenser provided in this embodiment is not limited to this physical device, and may include more or fewer components, or may combine certain components, or may have a different arrangement of components.

The storage medium may also include an operating system, a network communication module. The operating system is a program for managing the entity equipment hardware and the software resources to be identified, and supports the operation of the information processing program and other software and/or programs to be identified. The network communication module is used for realizing communication among all components in the storage medium and communication with other hardware and software in the information processing entity equipment.

In one embodiment, as shown in fig. 5, there is provided a fuel dispenser data processing system, which includes at least one fuel dispenser 10, a hub 20 and a zero pipe system 30, wherein the hub 20 includes at least one first data collection channel, each first data collection channel is connected to a communication module of one fuel dispenser 10, the hub 20 is further connected to the zero pipe system 30 in a communication manner through a network, the hub 20 can collect raw data sent by the fuel dispenser 10, and sequentially parse the raw data sent by each fuel dispenser 10 through a pre-configured data parsing protocol corresponding to each data collection channel to obtain operation data and gun state data of each fuel dispenser 10, so that the hub 20 can simultaneously dock multiple types and types of fuel dispensers 10, thereby improving efficiency of fuel dispenser data collection.

In one embodiment, as shown in fig. 6, the fuel dispenser data processing system further comprises at least one fluid level meter 40, and the hub 20 further comprises at least one second data acquisition channel, wherein each of the second data acquisition channels may be connected to a communication module of one of the fluid level meters 40. In this embodiment, the hub 20 may collect the raw data sent by the liquid level meter 40, and sequentially parse the raw data sent by each liquid level meter 40 through a pre-configured data parsing protocol corresponding to each second data collection channel, so as to obtain the oil tank data of each liquid level meter 40, so that the hub 20 may dock multiple types and types of liquid level meters 40 at the same time, thereby improving the efficiency of data collection of the liquid level meters.

In one embodiment, as shown in fig. 6, the fuel dispenser data processing system further includes at least one communication relay device 50, and the hub 20 further includes at least one third data acquisition channel, where each third data acquisition is connected to a first communication module of the communication relay device 50, and a second communication module of the communication relay device 50 is connected to a communication module of the fuel dispenser 20. In this embodiment, for the fuel dispensers with different models, the data in the fuel dispenser can be read by the communication transfer device, and the data is analyzed into real-time data and transaction data and then sent to the hub, and the hub can store and upload the received data. In addition, the hub can set an authorization mark in the communication transfer device so as to realize the control of the oiling gun through the communication transfer device.

In one embodiment, as shown in fig. 6, the fuel dispenser data processing system further includes a cloud platform 60, where the zero pipe system 30 is communicatively connected to the cloud platform 60 through a network, and the cloud platform 60 is configured to collect and/or set data in the zero pipe system 30. In this embodiment, the hub may be connected to each hardware device in the gas station through a hardware interface, including the fuel dispenser and the liquid level meter of each model, and then the hub may collect the data in the fuel dispenser and the liquid level meter, parse and store the data, and further respond to the query request of the zero pipe system, upload the data to the zero pipe system, and further, the zero pipe system may store the data in the database, or upload the data to the cloud platform.

It should be noted that, in the foregoing description of the fuel dispenser data processing system related to the fuel dispenser data processing method portion in each embodiment, reference may be made to the corresponding description of each fuel dispenser data processing method embodiment, which is not repeated herein.

From the above description of the embodiments, it will be apparent to those skilled in the art that the present application may be implemented by means of software plus necessary general hardware platforms, or may be implemented by hardware. The method comprises the steps of connecting a plurality of first data acquisition channels of a hub with a communication module of each oiling machine, and sequentially analyzing original data sent by each oiling machine through a data analysis protocol corresponding to each pre-configured data acquisition channel to obtain operation data of each oiling machine and oil gun state data. Compared with the prior art, the method can enable the hub to be simultaneously connected with oiling machines of various types and types, thereby effectively improving the data acquisition efficiency of the oiling machine. In addition, the hub and the oiling machine are connected in a simple mode, the complexity of circuit arrangement is low, and the digital transformation cost of the oiling machine can be effectively reduced.

Those skilled in the art will appreciate that the drawings are merely schematic illustrations of one preferred implementation scenario, and that the modules or flows in the drawings are not necessarily required to practice the present application. Those skilled in the art will appreciate that modules in an apparatus in an implementation scenario may be distributed in an apparatus in an implementation scenario according to an implementation scenario description, or that corresponding changes may be located in one or more apparatuses different from the implementation scenario. The modules of the implementation scenario may be combined into one module, or may be further split into a plurality of sub-modules.

The foregoing application serial numbers are merely for description, and do not represent advantages or disadvantages of the implementation scenario. The foregoing disclosure is merely a few specific implementations of the present application, but the present application is not limited thereto and any variations that can be considered by a person skilled in the art shall fall within the protection scope of the present application.

Claims (16)

1. A fuel dispenser data processing method, the fuel dispenser data processing method being applied to a hub, the hub including at least one first data acquisition channel, each of the first data acquisition channels being for connection to a communications module of a fuel dispenser, the method comprising:

Acquiring original data sent by at least one oiling machine through the first data acquisition channel;

determining a data analysis protocol corresponding to each first data acquisition channel according to preconfigured hub channel information;

analyzing the original data sent by each oiling machine based on the data analysis protocol corresponding to each first data acquisition channel to obtain the operation data and the oil gun state data of each oiling machine.

2. The method of claim 1, wherein the hub further comprises at least one second data acquisition channel, each second data acquisition channel for connection with a communication module of a level gauge, the method further comprising:

collecting original data sent by at least one liquid level meter through the second data collecting channel;

determining a data analysis protocol corresponding to each second data acquisition channel according to the hub channel information;

and analyzing the original data sent by each liquid level instrument based on a data analysis protocol corresponding to each second data acquisition channel to obtain the oil tank data of each liquid level instrument.

3. The method of claim 2, wherein prior to said collecting raw data transmitted by at least one of said fuel dispensers via said first data collection channel, said method further comprises:

receiving the hub channel information sent by a configuration tool connected with the hub network, wherein the hub channel information comprises a channel number, a protocol number, a communication parameter, an automatic authorization flag, an oil engine log flag, the number of oil guns and an oil product code of the first data acquisition channel, and the channel number, the protocol number and the communication parameter of the second data acquisition channel;

the hub channel information is stored in a memory of the hub.

4. The method according to claim 1, wherein the method further comprises:

responding to a first information inquiry request, and sending the first information inquiry request to the oiling machine through the first data acquisition channel, wherein the first information inquiry request carries at least one of accumulated output oil quantity of the oiling machine, unit price of oil and working mode of the oiling machine;

receiving first query response information sent by the oiling machine, and analyzing the first query response information based on a data analysis protocol corresponding to the first data acquisition channel to obtain a first information query result;

And storing the first information inquiry result in a memory of the hub.

5. The method according to claim 2, wherein the method further comprises:

responding to a second information inquiry request, and sending the second information inquiry request to the liquid level meter through the second data acquisition channel, wherein the second information inquiry request carries at least one of oil volume, water volume, oil height, water height, temperature, pressure, density, oil inlet amount and side leakage amount;

receiving second query response information sent by the liquid level instrument, and analyzing the second query response information based on a data analysis protocol corresponding to the second data acquisition channel to obtain a second information query result;

and storing the second information inquiry result in a memory of the hub.

6. The method according to claim 1, wherein the method further comprises:

responding to a first information setting request, and sending the first information setting request to the oiling machine through the first data acquisition channel, wherein the first information setting request carries at least one of quantitative oiling opening instruction, quantitative oiling closing instruction, oil unit price and oiling machine working mode;

And receiving the setting response information of the oiling machine, and analyzing the setting response information through a data analysis protocol corresponding to the first data acquisition channel to obtain an information setting result.

7. The method of any of claims 1-6, wherein the hub is further communicatively coupled to a zero pipe system via a network, the method further comprising:

receiving a third information inquiry request sent by the zero management system, and determining information to be inquired according to information carried in the third information inquiry request, wherein the third information inquiry request carries at least one of information of hub channel information, transaction data, oil tank data, hub time, accumulated output oil quantity of an oiling machine and unit price of oil products;

and reading a query result corresponding to the information to be queried from the memory of the hub, and sending the query result to the zero management system.

8. The method of claim 7, wherein the method further comprises:

receiving a second information setting request sent by the zero pipe system, and determining information to be set according to information carried in the second information setting request, wherein the second information setting request carries at least one of information of hub channel information, hub time, an authorized oiling start instruction, an authorized oiling close instruction and an oil unit price;

And setting the information to be set according to the value corresponding to the information carried in the second information setting request, and storing the setting result in a memory of the hub.

9. The method according to any one of claims 1-6, further comprising:

storing the operation data and the oil gun state data of each oiling machine and the oil tank data of each liquid level meter in a cache space, and judging whether the data amount in the cache space reaches a preset value or not;

if the data volume in the cache space reaches the preset value, storing transaction data and oil tank data in the cache space in a memory of the hub;

and/or when the hub is powered down, storing the operation data and the oil gun state data of each oiling machine acquired last time and the oil tank data of each liquid level instrument acquired last time in a memory of the hub.

10. A fuel dispenser data processing apparatus, the apparatus comprising:

the data acquisition module is used for acquiring the original data sent by at least one oiling machine through the first data acquisition channel;

The protocol determining module is used for determining a data analysis protocol corresponding to each first data acquisition channel according to the preconfigured hub channel information;

the data analysis module is used for analyzing the original data sent by each oiling machine based on the data analysis protocol corresponding to each first data acquisition channel to obtain the operation data and the gun state data of each oiling machine.

11. A storage medium having stored thereon a computer program, which when executed by a processor performs the steps of the method according to any of claims 1 to 9.

12. A computer device comprising a memory, a processor and a computer program stored on the memory and executable on the processor, characterized in that the computer program when executed by the processor implements the steps of the method according to any one of claims 1 to 9.

13. A fuel dispenser data processing system, said system comprising at least one fuel dispenser, a hub and a zero line system, wherein said hub comprises at least one first data acquisition channel, each of said first data acquisition channels being connected to a communication module of one of said fuel dispensers, said hub being further communicatively connected to said zero line system via a network, said hub performing the method of any one of claims 1 to 9.

14. The system of claim 13, further comprising at least one level gauge, the hub further comprising at least one second data acquisition channel, wherein each of the second data acquisition channels is coupled to a communication module of one of the level gauges.

15. The system of claim 13, further comprising at least one communication relay, the hub further comprising at least one third data acquisition channel, wherein each third data acquisition is coupled to a first communication module of one of the communication relay, and wherein a second communication module of the communication relay is coupled to a communication module of the fuel dispenser.

16. The system of claim 13, further comprising a cloud platform, wherein the zero pipe system is communicatively coupled to the cloud platform via a network, wherein the cloud platform is configured to collect and/or set data in the zero pipe system.

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