CN103023767B - The automatic reliable asynchronous transmission system of a kind of data for quality system of steel enterprise - Google Patents

Abstract

The invention relates to an automatic and reliable asynchronous data transmission system used in the quality system of iron and steel enterprises, which belongs to the field of information technology of iron and steel enterprises. The device includes a data end, a processing end and a data routing end; the data end includes a receiving end and a sending end; the receiving end and the sending end do not communicate directly, and the processing end includes a processing module I, a processing module II, a processing module I, and a processing module II No direct communication; the sending end is connected to the data routing end through the processing module II, and at the same time, the data routing end is connected to the receiving end through the processing module I. The invention ensures the reliable transmission of data and improves the credibility of the quality data of iron and steel enterprises; adapts to the complex network structure needs of iron and steel enterprises, is conducive to the security and maintainability of the network; adapts to the narrow bandwidth requirements of remote data transmission of iron and steel enterprises, and ensures data Real-time processing needs.

Description

An automatic and reliable asynchronous data transmission system for the quality system of iron and steel enterprises

technical field

The invention relates to an automatic and reliable asynchronous data transmission system used in the quality system of iron and steel enterprises, which belongs to the field of information technology of iron and steel enterprises.

Background technique

At present, the quality analysis data transmission of iron and steel enterprises plays an important role in the quality information management of iron and steel enterprises. Iron and steel enterprises mainly use the following characteristics in the quality information processing: 1) The enterprise data network has a wide distribution range, and the physical distance between data points is long; 2) The on-site working environment of the enterprise is harsh, the communication conditions are poor, the communication reliability is poor, and the communication speed is slow. Due to the above characteristics, it often brings the characteristics of narrow communication bandwidth and poor communication reliability. Traditionally, for this kind of data processing, the database is often used as the center, and other data points are used as client-side processing methods. Such a processing method often brings defects such as poor data communication reliability and slow data processing speed.

Contents of the invention

In order to overcome the defects of poor data communication reliability and slow data processing speed, an automatic and reliable asynchronous data transmission system for the quality system of iron and steel enterprises is designed. This system can overcome the defect that data points are often disconnected and ensure effective and reliable data transmission. This system only transmits necessary data packets, and puts a large amount of data analysis and calculation that requires bandwidth to the data terminal (1) for processing, which can Effectively overcome the data processing bottleneck caused by narrow network bandwidth. The system is conducive to reducing the investment of enterprises in hardware construction such as networks, saving enterprise costs, and improving the reliability of the quality system.

In order to solve the above technical problems, the technical solution adopted in the present invention is: the device includes a data terminal 1, a processing terminal 2 and a data routing terminal 3; the data terminal 1 includes a receiving terminal 4 and a transmitting terminal 5; the receiving terminal 4 and the transmitting terminal 5. No direct communication, processing terminal 2 includes processing module I6, processing module II7, processing module I6, processing module II7 do not communicate directly; sending terminal 5 is connected with data routing terminal 3 through processing module II7, and at the same time, data routing terminal 3 passes processing The module I6 is connected with the receiving end 4 .

The sending end 5 sends data to the processing module II7, and the processing module II7 sends the data to the data routing end 3, and the data routing end 3 sends the data to the processing module I6, and the processing module I6 finally sends the data to the receiving end 4; After terminal 4 receives the data, it sends feedback to the processing module I6 directly connected to it, and the feedback data is passed to the sending terminal 5 through the data routing terminal 3 and processing module II7; specifically, follow the steps below;

In the first step, the operator starts the sending end 5 to start the data sending data task, and needs to determine whether the processing module II7 is online;

1) If the processing module II7 is online, send data to the sending end 5 to the processing end 2 synchronously,

2) If the processing module II7 is offline, restart the sending task;

In the second step, the processing module II7 sends data to the data routing terminal 3 through the message queue asynchronously. After the data routing terminal 3 receives the data, the data routing terminal 3 asynchronously sends data to the processing module I6 directly connected to the receiving terminal;

The third step, the processing module I6 directly connected to the receiving end 4 sends data to the receiving end 4 in a synchronous manner, the receiving end 4 checks the received data, and the receiving end 4 responds to the data sent to the processing module I6, and if the data is correct, then sends a correct response packet , otherwise send and receive an error response packet; the processing module I6 passes it to the data routing end 3, the data routing end 3 passes it to the processing module II7, and the processing module II7 passes it to the sending end 5.

Step 4: After receiving the correct response, the sender 5 completes the current data processing, otherwise re-initiates the data sending task until it is correct.

The data processing connected between the data terminal 1 and the processing terminal 2 adopts the synchronous data transmission method, and the asynchronous data transmission method based on the message queue method is adopted between the processing terminal 2 and the data routing terminal 3 .

The processing terminal 2 transmits the data to the data routing terminal 3 in an asynchronous manner. The advantage of processing is that the processing terminal 2 and the data routing terminal 3 do not need to be online synchronously, and can also ensure reliable data transmission, which is beneficial to the network disconnection of steel enterprises. Handle the situation.

The synchronous processing method of data terminal 1 and processing terminal 2 is conducive to ensuring timely response and processing of user data, and processing terminal 2 is a background running server, so that data terminal 1 does not need to be online to wait for data processing all the time, which is conducive to improving data processing efficiency.

The purpose of adopting the data routing terminal 3 is to ensure that it is suitable for the complex structure network needs of iron and steel enterprises, and to realize the requirement that the receiving terminal 4 and the transmitting terminal 5 cannot communicate directly. In the iron and steel information network, the receiving terminal 4 and the transmitting terminal 5 often cannot communicate with each other. The data routing end 3 that can be accessed by both the sending end 5 and the receiving end 4 implements data forwarding between the receiving end 4 and the sending end 5 .

The beneficial effects that the present invention has are:

1) Ensure the reliable transmission of data and improve the credibility of the quality data of iron and steel enterprises;

2) Adapt to the complex network structure needs of iron and steel enterprises, which is conducive to the security and maintainability of the network;

3) Adapt to the narrow bandwidth requirements of remote data transmission of iron and steel enterprises, and ensure real-time data processing needs.

Description of drawings

Figure 1 is a hierarchical diagram of the system module structure.

Figure 2 is a flow chart of data transfer processing.

In the figure: 1-data terminal, 2-processing terminal, 3-data routing terminal, 4-receiving terminal, 5-sending terminal, 6-processing module I, 7-processing module II.

Specific implementation method

The present invention will be described in further detail below in conjunction with the accompanying drawings and embodiments, so as to facilitate the understanding of technical personnel.

As shown in Figure 1: the device includes a data terminal 1, a processing terminal 2 and a data routing terminal 3; the data terminal 1 includes a receiving terminal 4 and a transmitting terminal 5; the receiving terminal 4 and the transmitting terminal 5 do not communicate directly, and the processing terminal 2 includes Processing module I6, processing module II7, processing module I6, processing module II7 do not communicate directly; sending end 5 is connected to data routing end 3 through processing module II7, and data routing end 3 is connected to receiving end 4 through processing module I6.

The sending end 5 sends data to the processing module II7, and the processing module II7 sends the data to the data routing end 3, and the data routing end 3 sends the data to the processing module I6, and the processing module I6 finally sends the data to the receiving end 4; Terminal 4 sends feedback to the processing module I6 directly connected to it after receiving the data, and the feedback data is passed to the transmitting terminal 5 through the data routing terminal 3 and the processing module II7.

The data processing connected between the data terminal 1 and the processing terminal 2 adopts the synchronous data transmission method, and the asynchronous data transmission method based on the message queue method is adopted between the processing terminal 2 and the data routing terminal 3 .

The processing terminal 2 transmits the data to the data routing terminal 3 in an asynchronous manner. The advantage of processing is that the processing terminal 2 and the data routing terminal 3 do not need to be online synchronously, and can also ensure reliable data transmission, which is beneficial to the network disconnection of steel enterprises. Handle the situation.

The synchronous processing method of data terminal 1 and processing terminal 2 is conducive to ensuring timely response and processing of user data, and processing terminal 2 is a background running server, so that data terminal 1 does not need to be online to wait for data processing all the time, which is conducive to improving data processing efficiency.

As shown in Figure 2, the working process of the present invention:

In the first step, the operator starts the sending end 5 to start the data sending data task, and needs to determine whether the processing module II7 is online;

1) If the processing module II7 is online, send data to the sending end 5 to the processing end 2 synchronously,

2) If the processing module II7 is offline, restart the sending task;

In the second step, the processing module II7 sends data to the data routing terminal 3 through the message queue asynchronously. After the data routing terminal 3 receives the data, the data routing terminal 3 asynchronously sends data to the processing module I6 directly connected to the receiving terminal;

The third step, the processing module I6 directly connected to the receiving end 4 sends data to the receiving end 4 in a synchronous manner, the receiving end 4 checks the received data, and the receiving end 4 responds to the data sent to the processing module I6, and if the data is correct, then sends a correct response packet , otherwise send and receive an error response packet; the processing module I6 passes it to the data routing end 3, the data routing end 3 passes it to the processing module II7, and the processing module II7 passes it to the sending end 5.

Step 4: After receiving the correct response, the sender 5 completes the current data processing, otherwise re-initiates the data sending task until it is correct.

Embodiment 1: The processing module II7 and the processing module I6 are online, and the receiving end 4 receives correct data

The sending end 5 sends data to the processing module II7, and the processing module II7 immediately sends the data to the data routing end 3 in an asynchronous manner after receiving the data, and the data routing end 3 asynchronously sends the data to the processing module I6, and the processing module I6 passes the synchronous method after receiving the data. send data to the receiving end 4, 4 sends the correct response packet to the processing module I6, and pass it to the data routing end 3 through the processing module I6, and the data routing end 3 passes it to the processing module II7, and the processing module II7 passes it to the sending end 5, and completes this secondary data communication.

Embodiment 2: The processing module II7 is not online, the processing module I6 is online, and the receiving end 4 receives correct data

The sending end 5 sends data to the processing module II7, and waits for the processing module II7 to go online. After the processing module II7 goes online, the processing module II7 immediately sends the data to the data routing end 3 asynchronously after receiving the data, and the data routing end 3 sends it to the processing module asynchronously. I6, the processing module I6 sends the data to the receiving end 4 in a synchronous manner after receiving the data, and the receiving end 4 sends a correct response packet to the processing module I6, which is passed to the data routing end 3 through the processing module I6, and the data routing end 3 is passed to the processing module II7, the processing module II7 transmits to the sending end 5 to complete this data communication.

Embodiment 3: The processing module II7 is online, the processing module I6 is not online, and the receiving end 4 receives correct data

The sending end 5 sends data to the processing module II7, and the processing module II7 immediately sends the data to the data routing end 3 in an asynchronous manner after receiving the data, and the data routing end 3 asynchronously sends the data to the processing module I6, and the pending processing module I6 passes through the message queue after going online After receiving the data asynchronously, send the data to the receiving end 4 in a synchronous manner, and the receiving end 4 sends a correct response packet to the processing module I6, which is passed to the data routing end 3 through the processing module I6, and the data routing end 3 is passed to the processing module II7, and the processing The module II7 is passed to the sending end 5 to complete this data communication.

Embodiment 4: The processing module II7 is online, the processing module I6 is not online, and the receiving end 4 receives incorrect data

The sending end 5 sends data to the processing module II7, and the processing module II7 immediately sends the data to the data routing end 3 in an asynchronous manner after receiving the data, and the data routing end 3 asynchronously sends the data to the processing module I6, and the pending processing module I6 passes through the message queue after going online After receiving the data asynchronously, send the data to the receiving end 4 in a synchronous manner, and the receiving end 4 sends an incorrect response packet to the processing module I6, which is passed to the data routing end 3 through the processing module I6, and the data routing end 3 is passed to the processing module II7, The processing module II7 passes it to the sending end 5, and after receiving the incorrect response packet, the sending end 5 repeatedly sends the data packet to the processing module II7 and retransmits the data according to the above process until a correct response is received.

The present invention is illustrated by the accompanying drawings, without departing from the scope of the present invention, various transformations and equivalent substitutions can also be made to the patent of the present invention. Therefore, the patent of the present invention is not limited to the disclosed specific implementation process, but should include All embodiments falling within the scope of the patent claims of the present invention.

Claims (1)

1. for the automatic reliable asynchronous transmission system of data of quality system of steel enterprise, it is characterized in that: this device comprises data terminal, end for process and data route end; Data terminal includes receiving terminal and transmitting terminal; Receiving terminal and transmitting terminal not direct communication, end for process comprises processing module I, processing module II, processing module I, processing module II not direct communication; Transmitting terminal is connected with data route end by processing module II, and meanwhile, data route end is connected with receiving terminal by processing module I;

Transmitting terminal is by sending data to processing module II, and processing module II is sent to data route end data again, and data route end is sent to processing module I data again, and processing module I finally sends to receiving terminal data; After receiving the data, the processing module I that Xiang Yuqi is directly connected sends feedback to receiving terminal, and feedback data passes to transmitting terminal by data route end, processing module II feedback data; Specifically carry out according to step below;

The first step, to be started transmitting terminal log-on data by operating personnel and send data task, need determination processing module ii whether online;

1) if processing module II is online, then end for process is sent data to the transmitting terminal method of synchronization,

2) if processing module II is not online, then transmission task is restarted;

Second step, processing module II send data to data route end 3 by message queue asynchronous system, and after data route end receives data, data route end asynchronous system sends data to the processing module I be directly connected with receiving terminal;

3rd step, send data to receiving terminal with the processing module I method of synchronization that receiving terminal is directly connected, receiving terminal verification receives data, receiving terminal response data sends to processing module I, if data correctly, send correct respond packet, otherwise transmission and reception errored response bag; Processing module I passes to data route end, and data route end passes to processing module II processing module II and passes to transmitting terminal;

4th step, transmitting terminal complete this data processing after receiving correct response, otherwise again initiate data transmission task, until correct.