CN111553449A - High-stability signal interaction method for underground pipe gallery logistics - Google Patents
High-stability signal interaction method for underground pipe gallery logistics Download PDFInfo
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Abstract
The invention relates to a high-stability signal interaction method for underground pipe gallery logistics, which comprises the following steps of: s1, generating radio frequency card information and bar codes corresponding to ordering success information by the pipe gallery logistics management platform, and sending the radio frequency card information and the bar codes to the intelligent terminal; s2, receiving the receiving information by the pipe gallery logistics management platform; s3, binding the wrapped radio frequency card information with a transport tool, and checking and mapping the data of the radio frequency card information by the intelligent terminal; s4, after the package is loaded into the transport tool, reading the loading information of the transport tool by using a radio frequency reader and scanning the information of the vehicle-mounted package; s5, selecting a pipe gallery logistics sorting station and a logistics bin transportation route after the information check is correct; and S6, dispatching the vehicle after the vehicle arrives at the target corridor logistics sorting station, and transmitting the tag data of the corresponding radio frequency card information into the intelligent terminal after signing. The signal interaction method provided by the invention combines the logistics system, the comprehensive pipe gallery and the radio frequency technology, improves the logistics transportation efficiency and reduces the fault tolerance rate.
Description
Technical Field
The invention belongs to the technical field of underground traffic, and particularly relates to a high-stability signal interaction method for underground pipe gallery logistics.
Background
The pipeline gallery, namely the corridor of the pipeline, many pipelines in the chemical industry and its related factory are concentrated together, arrange along the apparatus or factory building outside, prop up with the support, form and the similar appearance with the corridor, generally present "open" type, it is the main place that the large-scale apparatus pipeline is concentrated and laid, it is formed by pillar stand, crossbeam and truss of the steel construction or reinforced concrete structure, can divide into the single-storeyed or multilayer according to the type, can pass or can not pass, etc., build a tunnel space in the city underground, collect various engineering pipelines such as electric power, communication, gas, heat supply, water supply and drainage, etc. in an organic whole, there are specialized maintenance mouth, hoist mouth and monitoring system, implement the unified planning, unified design, unified construction and management, it is the important infrastructure and "lifeline" that guarantee the city runs.
The urban traffic problem in China, particularly the traffic problem of a super-large city, presents a plurality of new characteristics: the electronic commerce is developed in a leap way, so that the logistics distribution quantity and frequency in cities are increased rapidly, the quantity of private cars is increased day by day, the urban traffic jam is increasingly serious, haze is too lou, air pollution is aggravated, the construction and expansion of ground traffic infrastructures are more severe, and the urban natural and human landscape is seriously damaged; in order to solve the problems, the traditional method plays roles of traffic diversion and contradiction alleviation by means of modes of enlarging urban roads, limiting urban truck traffic, reducing construction of distribution centers and the like.
Along with the rise of urban intelligent underground logistics system, will bring a brand-new freight transportation mode, with part urban freight transportation traffic reposition of redundant personnel to the underground, can replace the transportation mode of short-and-medium distance road transportation, not only feasible environmental protection still has development prospect very, along with the development of utility tunnel underground, consequently combine utility tunnel and logistics system, establish automatic, intelligent, accessible urban intelligent underground logistics system to the freight, go to realize really solving the target of urban traffic difficult problem.
However, in the prior art, more problems still exist in the operation management of the comprehensive pipe gallery, for example, the operation management of the comprehensive pipe gallery is warned by a large amount of sensors and alarms, so that the comprehensive pipe gallery is not easy to manage, and is not convenient for positioning and maintaining by workers. The management of utility tunnel still relies on manual management, and manual management can have the untimely problem of update information sometimes, also is convenient for take notes the data that produce among the operation management process of utility tunnel, therefore the management demand of utility tunnel can not be satisfied to traditional utility tunnel's operation management system.
Disclosure of Invention
The invention aims to solve the problems in the background art, and provides a high-stability signal interaction method for underground pipe gallery logistics.
The purpose of the invention is realized as follows:
a high-stability signal interaction method for underground pipe gallery logistics comprises the following steps:
s1, the pipe gallery logistics management platform generates radio frequency card information and a bar code corresponding to the ordering success information according to the sent ordering success information, and sends the radio frequency card information and the bar code to the intelligent terminal;
s2, receiving the receiving information sent by the intelligent terminal after the package arrives at the logistics center of the pipe gallery by the logistics management platform of the pipe gallery, wherein the receiving information comprises user identity information, receiving time and receiving place;
s3, sorting the packages in the logistics center of the pipe gallery, distributing the packages to corresponding transport means, binding the information of the packaged radio frequency cards with the transport means, checking whether the radio frequency cards are used by the intelligent terminal, if the radio frequency cards are used, replacing a new radio frequency card to bind with a target, transmitting the read data to the intelligent terminal, and mapping the data of the radio frequency card information by the intelligent terminal;
s4, after the packages are loaded into the transport tool, reading the loading information of the transport tool by using a radio frequency reader and scanning the information of the vehicle-mounted packages, if the packages are not matched or omitted, alarming by the logistics management platform of the pipe gallery, and checking the information by staff until the packages are correct;
s5, after the information is checked to be correct, selecting a pipe gallery logistics sorting station according to the receiving place, and selecting a corresponding logistics bin transportation route by the intelligent terminal according to the position service information of the pipe gallery logistics sorting station;
s6, after the vehicle arrives at the target corridor logistics sorting station, the information is calibrated again, whether the package is lost or damaged is checked, the delivery is carried out according to the position service information and the receiving information of the pipe corridor logistics sorting station, and after the customer finishes signing, the deliverer transmits the label data of the corresponding radio frequency card information into the intelligent terminal through the reader.
Preferably, in S1, establish the logistics storehouse in the pipe gallery and the transport means of going in the logistics storehouse, pipe gallery commodity circulation management platform is used for the basis according to the successful information generation of ordering that intelligent terminal sent with the radio frequency card information that the successful information of ordering corresponds, and will radio frequency card information sends intelligent terminal, intelligent terminal is used for arriving at express mail send on after the pipe gallery commodity circulation center and receive a piece information to pipe gallery commodity circulation management platform, supply pipe gallery commodity circulation management platform judges whether radio frequency card information matches with user identity information, and select pipe gallery commodity circulation letter sorting station and bind radio frequency card information and transport means.
Preferably, in S3, the pipe gallery logistics center includes a processor, a baffle type sorting machine, a conveyor belt, a database, and a bar code identifier, the processor is in communication connection with the intelligent terminal and the database, respectively, the processor controls the conveyor belt and the baffle type sorting machine, the bar code identifier is connected with the processor through a local area network, and the bar code identifier is connected with the baffle type sorting machine through the intelligent terminal.
Preferably, the intelligent terminal adopts a C/S architecture, and the intelligent terminal and the processor perform data communication by establishing a TCP/IP network connection.
Preferably, in S5, the transportation means sends the package of the corresponding radio frequency card information after sorting and binding the pipe rack logistics center according to the sending instruction of the pipe rack logistics management platform through the logistics warehouse to the pipe rack logistics sorting station for sending.
Preferably, when the transportation tool loads the packages in the logistics center of the pipe rack, the information of the transportation tool and the packages loaded into the transportation tool is read by the radio frequency reader for identifying the radio frequency card information, and whether the loading is correct is verified according to the matching result of the radio frequency card information of the packages and the transportation tool.
Preferably, in S6, after the transportation tool arrives at the corresponding pipe gallery logistics sorting station, the information of the transportation tool and the package loaded into the transportation tool is read again by the radio frequency reader for identifying the radio frequency card information, and whether the unloading is correct is verified according to the dispatch instruction of the pipe gallery logistics management platform.
Preferably, the intelligent terminal is further configured to map the radio frequency card information data and check whether the radio frequency card information is used.
Preferably, the material warehouse is detected and the transport vehicle is tracked and positioned by combining GPRS and RDIF technologies.
Preferably, the radio frequency card information is a 915MHz frequency band radio frequency tag AZ-9662/9762, and the reader adapted to the radio frequency card information is a high-power module SLR1200 or SLR 5300.
Preferably, the system further comprises a self-lifting box communicated with the pipe gallery logistics sorting station, and after the customer signs in, the dispatcher transmits the tag data of the corresponding radio frequency card information into the intelligent terminal through the reader.
Preferably, the intelligent terminal completes the optimal path of transportation of the transport vehicle on the basis of combining with the basic ant colony algorithm.
Preferably, the algorithm of the optimal path includes the following steps:
1) initializing parameters: setting maximum iteration times and cycle times, setting an information heuristic factor alpha according to the optimal parameters of the ant colony algorithm, and expecting the values of the heuristic factor beta and the pheromone volatilization coefficient p;
2) setting a tabu table, putting m Ants into each vertex, the tabu table being corresponding city vertex, and calculating pheromone quantity delta tau of each ant left on each sidek ij;
3) The kth ant calculates the transition probability pk ij(t), selecting the next city to arrive, updating the tabu table, and repeating the process until all cities are traversed;
4) updating pheromones, including the total pheromone amount volatilized on the path and the total pheromone amount newly added by the ant colony on the path;
5) recording the optimal path found out by the current cycle;
6) comparing the next circulation with the recorded optimal solution, and performing mutation operation if the conditions are met;
7) the inverse ratio of the shortest path value which passes through all the places once is used as a fitness function, the smaller the value of the shortest path is, the better the value of the fitness function is, and the new optimal solution is recorded and updated in the solving process of each time;
8) and judging whether the iteration times are reached, if so, outputting a value of an optimal path, and otherwise, jumping to the step 4, wherein the iteration times are increased by 1, and continuing to execute.
Preferably, the global pheromone adjustment rule of the ant system can be expressed as:
τij=(1-p)τij(t)+Δτij(t),
Δτij(t)=
,
wherein p is the information volatilization coefficient and represents the inspiring capacity of pheromone left by each ant on the next ant, delta tauij(t) all pheromone increments, Δ τ, over path (i, j) after the end of a cyclek ij(t) represents the amount of pheromone left by the kth ant on path (i, j).
Preferably,. DELTA.tau.k ij(t) = [ Q if ant k passes city (i, j) between t and t + 1; 0, otherwise]Wherein the size of Q represents the intensity of the pheromone.
Preferably, the intelligent terminal further comprises a monitoring unit and a data storage unit, the monitoring unit comprises a plurality of monitoring devices arranged in the pipe gallery, the monitoring devices are used for monitoring state parameters of facilities and environments in the pipe gallery in real time, the monitoring unit sends the acquired monitoring data to the data storage system, and the data storage system is used for storing data information of all systems in the intelligent terminal, the data information monitored by the monitoring system, operation and maintenance information generated in daily operation, a BIM model database and a GIS model database.
Preferably, supervisory equipment is including setting up temperature sensor, humidity transducer, smoke alarm, gas alarm, ponding alarm, video monitor, valve monitor, the lighting monitor on each piping lane facility, supervisory equipment's shell waterproof performance is IP68, supervisory equipment passes through optic fibre and intelligent terminal and realizes the internet access.
Preferably, be equipped with a plurality of wiFi signal transmission points, bluetooth signal transmission point in the piping lane, remove to serve and be equipped with bluetooth WIFI module, wiFi signal, the bluetooth signal connection back in transport means and the piping lane, the transport means sends current bluetooth, WIFI's signal information to intelligent terminal, bluetooth, WIFI's signal information includes the name and the signal intensity degree of tie point, and the procedure of setting for in the intelligent terminal is according can reachd the accurate spatial position information of transport means after signal information and the data calculation.
Compared with the prior art, the invention has the beneficial effects that:
1. according to the high-stability signal interaction method for the logistics of the underground pipe gallery, a logistics system, the comprehensive pipe gallery and a radio frequency technology are combined to form new logistics transportation management, delivery destination errors are avoided, package query time and fault tolerance rate are reduced, and logistics transportation efficiency is improved.
2. According to the high-stability signal interaction method for the logistics of the underground pipe gallery, underground transportation and management are adopted, the occupied ground space is prevented from being large, the closed logistics management avoids the occurrence of express mail loss and delivery errors, the road and urban landscape environment is improved, the corner space of the pipe gallery is used as a channel for express transportation, the occupied usable space of the comprehensive pipe gallery is minimized, and the construction cost is reduced.
3. The invention provides a high-stability signal interaction method for logistics of an underground pipe gallery, wherein a processor in a logistics center of the pipe gallery controls the running state of a conveyor belt, stores information of each package recorded into a system, displays the running state of equipment in real time, gives a trigger signal to an intelligent terminal when the package running on the conveyor belt passes through a position detection device, immediately acquires an image by a bar code recognizer, processes and analyzes the image to finally recognize a waybill number of the package, inquires the destination of the next baffle plate station of the package through TCP/IP connection established between a local area network and the processor, returns the destination, controls a sorting machine to dial express items from the conveyor belt if the express items are to be sorted at the position, and enters the next separation area through the baffle plate to finish sorting the packages if the express items are to be sorted at the position.
4. According to the high-stability signal interaction method for the logistics of the underground pipe gallery, automatic sorting is the key for improving the logistics distribution efficiency, the automatic control system of the sorting machine with the automatic bar code identification is adopted, the position of a package on a conveyor belt of the sorting machine can be automatically detected, the signal for triggering the intelligent terminal to collect an image is convenient to trigger, after image processing, decoding and information query are carried out, the next station destination of the express package is obtained, a separation baffle of the sorting machine is controlled to guide the package to enter a corresponding sliding chute, and therefore the purpose of automatic sorting is achieved.
5. The high-stability signal interaction method for underground pipe gallery logistics, provided by the invention, combines the optimal parameter configuration of the ant colony algorithm and the variation search of the genetic algorithm, and overcomes the defects that the traditional ant colony algorithm searches the optimal path for too long time and easily falls into the local optimal solution.
Drawings
Fig. 1 is a work flow diagram of a high stability signal interaction method for underground pipe gallery logistics according to the invention.
Fig. 2 is a schematic diagram of connection of working units of a high-stability signal interaction method for underground pipe gallery logistics.
Fig. 3 is a schematic diagram of a signal interaction method for high stability of underground pipe gallery logistics in the center of pipe gallery logistics.
Fig. 4 is a flow chart of the ant colony algorithm of the high-stability signal interaction method for underground pipe gallery logistics.
In the figure: 1. an intelligent terminal; 2. a pipe gallery logistics management platform; 3. a pipe gallery logistics center; 4. a logistics bin; 5. a pipe gallery logistics sorting station; 6. a vehicle; 31. a processor; 32. a conveyor belt; 33. a database; 34. a bar code identifier; 35. baffle type sorting machine.
Detailed Description
The technical solutions in the embodiments of the present invention are clearly and completely described below with reference to the accompanying drawings, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, rather than all embodiments, and all other embodiments obtained by those skilled in the art without any creative work based on the embodiments of the present invention belong to the protection scope of the present invention.
Example 1
With reference to fig. 1, a signal interaction method for high stability of underground pipe gallery logistics includes the following steps:
s1, the pipe gallery logistics management platform 2 generates radio frequency card information and a bar code corresponding to the ordering success information according to the sent ordering success information, and sends the radio frequency card information and the bar code to the intelligent terminal 1;
s2, receiving the receiving information sent by the intelligent terminal 1 after the package arrives at the pipe gallery logistics center 3 by the pipe gallery logistics management platform 2, wherein the receiving information comprises user identity information, receiving time and receiving place;
s3, sorting the packages in the pipe gallery logistics center 3, distributing the packages to corresponding transport means 6, binding the information of the packaged radio frequency cards with the transport means 6, checking whether the radio frequency cards are used by the intelligent terminal 1, if the radio frequency cards are used, binding a new radio frequency card with a target, transmitting the read data to the intelligent terminal 1, and mapping the data of the radio frequency card information by the intelligent terminal 1;
s4, after the packages are loaded into the transport tool 6, reading the loading information of the transport tool 6 by using a radio frequency reader and scanning the information of the vehicle-mounted packages, if the packages are not matched or omitted, alarming by the logistics management platform 2 of the pipe gallery, and checking the information by staff until the information is correct;
s5, after the information check is correct, selecting the pipe gallery logistics sorting station 5 according to the receiving place, and selecting the corresponding logistics cabin 4 transportation route by the intelligent terminal 1 according to the position service information of the pipe gallery logistics sorting station 5;
s6, after the vehicle arrives at the target corridor logistics sorting station 5, the information calibration is carried out again, whether the package is lost or damaged is checked, the delivery is carried out according to the position service information and the receiving information of the pipe corridor logistics sorting station 5, and after the customer finishes signing, the deliverer transmits the label data of the corresponding radio frequency card information into the intelligent terminal 1 through the reader.
Through combining logistics system, utility tunnel and radio frequency technology three and forming new logistics transportation management, avoid delivery destination mistake, reduced the inquiry time and the fault-tolerant rate of parcel, improve logistics transportation efficiency.
Example 2
With reference to fig. 1-3, a signal interaction method for high stability of underground pipe gallery commodity circulation, establish logistics storehouse 4 and the transport 6 that traveles in logistics storehouse 4 in the piping lane, including piping lane commodity circulation management platform 2, intelligent terminal 1, piping lane commodity circulation center 3, through the piping lane commodity circulation letter sorting station 5 of logistics storehouse 4 with 3 intercommunications in piping lane commodity circulation center, intelligent terminal 1, piping lane commodity circulation center 3 and piping lane commodity circulation letter sorting station 5 are communication connection to piping lane commodity circulation management platform 2 respectively.
Piping lane commodity circulation management platform 2 be used for according to the successful information generation of ordering that intelligent terminal 1 sent with the radio frequency card information that the successful information of ordering corresponds, and will radio frequency card information is given to intelligent terminal 1, intelligent terminal 1 is used for arriving at express mail send on after piping lane commodity circulation center 3 and receive a piece information to piping lane commodity circulation management platform 2, supply piping lane commodity circulation management platform 2 judges whether radio frequency card information matches with user identity information to and select piping lane commodity circulation letter sorting station 5 and bind radio frequency card information and transport 6.
Transport means 6 with the parcel of 3 letter sorting in pipe gallery commodity circulation center and binding back corresponding radio frequency card information according the dispatch piece instruction of pipe gallery commodity circulation management platform 2 passes through logistics storehouse 4 reachs 5 executions of pipe gallery commodity circulation letter sorting station dispatch.
When the transport means 6 loads the packages at the pipe rack logistics center 3, the radio frequency reader for identifying the radio frequency card information is used for reading the transport means 6 and loading the information of the packages in the transport means 6, whether the loading is correct or not is verified according to the radio frequency card information matching result of the packages and the transport means 6, after the transport means 6 arrives at the corresponding pipe rack logistics sorting station 5, the radio frequency reader for identifying the radio frequency card information is used for reading the transport means 6 and loading the information of the packages in the transport means 6 again, and whether the unloading is correct or not is verified according to the dispatching instruction of the pipe rack logistics management platform 2.
The pipe gallery logistics center 3 comprises a processor 31, a baffle type sorting machine 35, a conveyor belt 32, a database 33 and a bar code recognizer 34, wherein the processor 31 is respectively connected with the intelligent terminal 1 and the database 33 in a communication mode, the processor 31 controls the conveyor belt 32 and the baffle type sorting machine 35, the bar code recognizer 34 is connected with the processor 31 through a local area network, the bar code recognizer 34 is connected with the baffle type sorting machine 35 through the intelligent terminal 1, automatic sorting is the key for improving logistics distribution efficiency, a sorting machine automatic control system adopting automatic bar code recognition can automatically detect the position of a package on the conveyor belt of the sorting machine, signals for triggering and collecting images for the intelligent terminal are convenient, after image processing, decoding and information query are carried out, the next station destination of the express package is obtained, a separation baffle of the sorting machine is controlled to guide the package to enter a corresponding chute, thereby realizing the purpose of automatic sorting.
Example 3
On the basis of embodiment 2, intelligent terminal still includes monitoring unit, data storage unit, and the monitoring unit is including setting up a plurality of supervisory equipment in the piping lane, supervisory equipment is used for the status parameter of facility and environment in the real-time supervision piping lane, and the monitoring unit sends the monitoring data who acquires to data storage system, and data storage system is used for storing the data information of each system in the intelligent terminal of terminal, the data information that monitored by supervisory system, the operation and maintenance information and BIM model database and GIS model database that daily operation produced.
The supervisory equipment is including setting up temperature sensor, humidity transducer, smoke alarm, gas alarm, ponding alarm, video monitor, valve monitor, the illumination watch-dog on each piping lane facility, supervisory equipment's shell waterproof performance is IP68, supervisory equipment passes through optic fibre and intelligent terminal and realizes the internet access.
Be equipped with a plurality of wiFi signal transmission points, bluetooth signal transmission point in the piping lane, remove to serve and be equipped with bluetooth WIFI module, after wiFi signal, the bluetooth signal connection in transport means and the piping lane, the transport means sends current bluetooth, WIFI's signal information to intelligent terminal, bluetooth, WIFI's signal information includes the name and the signal intensity degree of tie point, and the procedure of setting for in the intelligent terminal is according can reachd the accurate spatial position information of transport means after signal information and the data calculation.
Example 4
With reference to fig. 4, the intelligent terminal 1 completes an optimal path for transportation of the transportation vehicle based on a basic ant colony algorithm, where the optimal path is obtained through the following algorithm steps:
1) initializing parameters: setting maximum iteration times and cycle times, setting an information heuristic factor alpha according to the optimal parameters of the ant colony algorithm, and expecting the values of the heuristic factor beta and the pheromone volatilization coefficient p;
2) setting a tabu table, putting m Ants into each vertex, the tabu table being corresponding city vertex, and calculating pheromone quantity delta tau of each ant left on each sidek ij;
3) The kth ant calculates the transition probability pk ij(t), selecting the next city to arrive, updating the tabu table, and repeating the process until all cities are traversed;
4) updating pheromones, including the total pheromone amount volatilized on the path and the total pheromone amount newly added by the ant colony on the path;
5) recording the optimal path found out by the current cycle;
6) comparing the next circulation with the recorded optimal solution, and performing mutation operation if the conditions are met;
7) the inverse ratio of the shortest path value which passes through all the places once is used as a fitness function, the smaller the value of the shortest path is, the better the value of the fitness function is, and the new optimal solution is recorded and updated in the solving process of each time;
8) and judging whether the iteration times are reached, if so, outputting a value of an optimal path, and otherwise, jumping to the step 4, wherein the iteration times are increased by 1, and continuing to execute.
Preferably, the global pheromone adjustment rule of the ant system can be expressed as:
τij=(1-p)τij(t)+Δτij(t),
Δτij(t)=
,
wherein p is the information volatilization coefficient and represents the inspiring capacity of pheromone left by each ant on the next ant, delta tauij(t) all pheromone increments, Δ τ, over path (i, j) after the end of a cyclek ij(t) represents the amount of pheromone left by the kth ant on path (i, j).
Preferably,. DELTA.tau.k ij(t) = [ Q if ant k passes city (i, j) between t and t + 1; 0, otherwise]Wherein the size of Q represents the intensity of the pheromone.
By combining the optimal parameter configuration of the ant colony algorithm and the variation search of the genetic algorithm, the defects that the time for searching the optimal path by the traditional ant colony algorithm is too long and the optimal path is easy to fall into the local optimal solution are overcome.
The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalents and substitutions made within the scope of the present invention should be included.
Claims (8)
1. A high-stability signal interaction method for underground pipe gallery logistics is characterized in that: the method comprises the following steps:
s1, the pipe gallery logistics management platform (2) generates radio frequency card information and bar codes corresponding to the ordering success information according to the sent ordering success information, and sends the radio frequency card information and the bar codes to the intelligent terminal (1);
s2, receiving the receiving information sent by the intelligent terminal (1) after the package arrives at the pipe gallery logistics center (3) by the pipe gallery logistics management platform (2), wherein the receiving information comprises user identity information, receiving time and receiving place;
s3, sorting the packages in the pipe gallery logistics center (3), distributing the packages to corresponding transport means (6), binding the information of the packaged radio frequency cards with the transport means (6), checking whether the radio frequency cards are used by the intelligent terminal (1), if the radio frequency cards are used, binding a new radio frequency card with a target, transmitting the read data to the intelligent terminal (1), and mapping the data of the radio frequency card information by the intelligent terminal (1);
s4, after the packages are loaded into the transport tool (6), reading the loading information of the transport tool (6) and scanning the information of the vehicle-mounted packages by using a radio frequency reader, if the packages are not matched or omitted, alarming by the logistics management platform (2) of the pipe gallery, and checking the information by a worker until the information is correct;
s5, after the information check is correct, selecting a pipe gallery logistics sorting station (5) according to the receiving place, and selecting a corresponding logistics cabin (4) transportation route by the intelligent terminal (1) according to the position service information of the pipe gallery logistics sorting station (5);
s6, after the vehicle arrives at the target corridor logistics sorting station (5), information calibration is carried out again, whether the package is lost or damaged is checked, dispatch is carried out according to the position service information and the receiving information of the pipe corridor logistics sorting station (5), and after the customer finishes signing, the dispatcher transmits the label data of the corresponding radio frequency card information into the intelligent terminal (1) through the reader.
2. The signal interaction method for high stability of underground pipe gallery logistics according to claim 1, characterized in that: s1, establish commodity circulation storehouse (4) and transport means (6) of traveling in commodity circulation storehouse (4) in the piping lane, piping lane logistics management platform (2) are used for the basis the successful information generation of ordering that intelligent terminal (1) sent with the radio frequency card information that the successful information of ordering corresponds, and general the radio frequency card information is given intelligent terminal (1), intelligent terminal (1) are used for arriving at express mail send on after piping lane logistics center (3) and receive a piece information to piping lane logistics management platform (2), supply piping lane logistics management platform (2) are judged whether radio frequency card information matches with user identity information to and select piping lane logistics sorting station (5) and bind radio frequency card information and transport means (6).
3. The signal interaction method for high stability of underground pipe gallery logistics according to claim 1, characterized in that: in S3, the pipe gallery logistics center (3) comprises a processor (31), a baffle type sorting machine (35), a conveyor belt (32), a database (33) and a bar code identifier (34), the processor (31) is respectively in communication connection with an intelligent terminal (1) and the database (33), the processor (31) controls the conveyor belt (32) and the baffle type sorting machine (35), the bar code identifier (34) is connected with the processor (31) through a local area network, and the bar code identifier (34) is connected with the baffle type sorting machine (35) through the intelligent terminal (1).
4. The signal interaction method for high stability of underground pipe gallery logistics according to claim 1, characterized in that: the intelligent terminal (1) adopts a C/S architecture, and the intelligent terminal (1) and the processor (31) carry out data communication by establishing TCP/IP network connection.
5. The signal interaction method for high stability of underground pipe gallery logistics according to claim 1, characterized in that: in S5, the transportation tool (6) sends the package of the corresponding radio frequency card information after the pipe gallery logistics center (3) is sorted and bound according to the sending instruction of the pipe gallery logistics management platform (2) through the logistics bin (4) to the pipe gallery logistics sorting station (5) to execute sending.
6. A signal interaction method for high stability of underground pipe gallery logistics according to claim 5, characterized in that: when the transportation tool (6) loads the packages in the pipe gallery logistics center (3), the transportation tool (6) and the information of the packages loaded into the transportation tool (6) are read by a radio frequency reader for identifying the radio frequency card information, and whether the packages are loaded correctly is verified according to the radio frequency card information matching result of the packages and the transportation tool (6).
7. The signal interaction method for high stability of underground pipe gallery logistics according to claim 1, characterized in that: in S6, after the transport tool (6) arrives at the corresponding pipe gallery logistics sorting station (5), the radio frequency reader for identifying the radio frequency card information is used again for reading the transport tool (6) and the information of the packages loaded into the transport tool (6), and whether unloading is correct is verified according to the dispatching instruction of the pipe gallery logistics management platform (2).
8. The signal interaction method for high stability of underground pipe gallery logistics according to claim 1, characterized in that: the intelligent terminal (1) is also used for mapping the radio frequency card information data and checking whether the radio frequency card information is used.
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