An unmanned aerial vehicle blood delivery platform management system

By building a drone-based blood delivery platform management system, the problems of slow response speed and weak traceability system in the traditional emergency blood transportation mode have been solved, realizing efficient, safe and traceable blood transportation and improving medical emergency support capabilities.

CN122290927APending Publication Date: 2026-06-26ZHEJIANG PROVINCIAL BLOOD CENT

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
ZHEJIANG PROVINCIAL BLOOD CENT
Filing Date
2026-04-13
Publication Date
2026-06-26

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Abstract

This invention discloses a drone blood delivery platform management system, relating to the field of medical logistics management technology. Its key technical features include: the system comprises an information management module, a work order management module, a flight route module, and a real-time monitoring module; work orders manage detailed information about blood transportation, such as destination and flight equipment, with blood banks reviewing and matching inventory, tracking the status of each node, and hospitals receiving the blood and establishing traceability files; drone management provides visualized monitoring of drone status, supports multi-drone collaboration, and transfer scheduling; flight route management plans optimal routes, presets transfer and alternate landing points, and emergency work orders call preset routes to improve efficiency; flight records are monitored in real time, monitoring flight and blood cold chain status, triggering early warnings for anomalies, retaining full logs and supporting playback, and includes an emergency response process, achieving full-chain digital management, improving transportation efficiency and safety, enhancing medical emergency response capabilities, and promoting the integration of low-altitude economy and medical emergency care.
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Description

Technical Field

[0001] This invention relates to the field of medical logistics management technology, specifically to a management system for a drone blood delivery platform. Background Technology

[0002] Blood transport and distribution refers to the process of delivering collected and stored blood (such as whole blood, plasma, platelets, etc.) from blood collection institutions, blood centers, or hospitals to medical institutions or patients in need. This process is crucial to ensuring the timeliness and safety of blood supply, especially in emergencies, where the efficiency and accuracy of blood distribution are directly related to the patient's life safety.

[0003] Blood transportation typically relies on refrigerated trucks, express delivery, or specialized transport personnel. However, traditional ground-based emergency blood transport methods have numerous limitations. Their response speed is often slow, and they are severely constrained by complex road conditions and severe weather. Furthermore, temperature control and end-to-end traceability systems during transportation are relatively weak. These issues could not only lead to missed opportunities for crucial treatment but also potentially impact blood quality and safety.

[0004] Therefore, the present invention aims to provide a drone blood delivery platform management system to solve the above problems. Summary of the Invention

[0005] The purpose of this invention is to solve the above-mentioned problems and provide a drone blood delivery platform management system. By constructing an "air-ground integrated" intelligent system, it breaks down information barriers between various parties, achieves full-chain digital management, improves transportation efficiency and safety performance, enhances medical emergency support capabilities, and promotes the integration of low-altitude economy and medical emergency care.

[0006] To achieve the above objectives, the technical solution of the present invention is as follows:

[0007] This invention provides a management system for a drone blood delivery platform, the system comprising an information management module, a work order management module, a flight route module, and a real-time monitoring module;

[0008] The information management module is responsible for managing information on organizations, departments, users, roles, and drones.

[0009] Organization Management: Enables the creation and maintenance of basic information for organizations. Organizations are the superior units of departments. Users can create organizations by performing the "Add" operation, filling in the required information, and then submitting and saving.

[0010] Department Management: Subordinate organizations of a department. Department management is used to maintain basic department information, and departments can be added and their superior organizations can be selected.

[0011] User Management: Used to maintain user information in the system backend and terminal APP. It can filter users by department, support adding, deleting, and resetting user passwords. It can also assign departments and roles to users and bind card numbers for device unlocking.

[0012] Role Management: Roles are collections of permissions used to maintain menu function and data scope permissions. It supports adding roles, assigning backend and app function menus, and configuring departmental data permissions to limit data access scope.

[0013] Drone Management: Used to manage delivery drones, maintain drone equipment information (such as equipment code, name, model, affiliated organization and status), support the addition, modification and deletion of drones, and control operation functions according to user role permissions.

[0014] The route module can create and synchronize route information, which includes the route name, the names of the origin and destination airports, the destination, and the latitude and longitude configuration between points. The route module supports adding, modifying, and deleting routes, and can automatically synchronize data through scheduled tasks.

[0015] In the work order management module, users enter delivery work order information via a mini-program. Administrators create delivery work orders in the management system. In the work order management module, users can select the drone model, destination, and delivery time, fill in remarks, and configure blood bag information according to actual transportation needs. After successfully creating a delivery work order, users can query the delivery work order in the information management module. The drone carries out drone delivery based on the delivery work order information in the work order management module, transporting blood to the designated location according to the route specified in the route module.

[0016] The real-time monitoring module automatically records the drone's flight trajectory and associates the blood delivery information with the flight record. Users can query the drone's basic information, blood delivery information, and complete flight record. The module supports trajectory playback and displays the temperature, latitude and longitude, and real-time parameters of the drone during transportation, thereby enabling traceability of the transportation process.

[0017] Compared with existing technologies, the beneficial effects of this solution are:

[0018] The system of this invention supports systematic management of institutions, departments, users, roles, and drones, thereby significantly improving overall management efficiency. It can also customize and synchronize route information to ensure each delivery follows the optimal path, improving transportation efficiency. The system supports full-process management of work orders and can configure blood information to achieve precise control over blood transportation information, including destination, flight equipment matching, inventory verification, full-node tracking, and hospital reception, ultimately establishing a complete traceability file. Regarding drone management, the system provides visual monitoring, supports multi-drone collaboration and transfer scheduling. The route management function can plan optimal routes, preset transfer and alternate landing points, and quickly call preset routes in emergencies to ensure uninterrupted delivery. The flight recording and monitoring function monitors flight status and blood cold chain conditions in real time, triggering warnings for abnormal situations, recording the entire log and supporting playback, while also providing emergency response procedures to ensure the safety, traceability, and system reliability of blood transportation. Attached Figure Description

[0019] Figure 1 This is a schematic diagram of the structure of the unmanned aerial vehicle (UAV) blood delivery platform management system in an embodiment of the present invention. Detailed Implementation

[0020] To enable those skilled in the art to better understand the present invention, the technical solution of the present invention will be described in further detail below with reference to the embodiments and accompanying drawings. Obviously, the described embodiments are merely some, not all, of the embodiments of the present invention. All other embodiments obtained by those skilled in the art based on the embodiments of the present invention without creative effort should fall within the scope of protection of the present invention.

[0021] It should be noted that, unless otherwise specified, the embodiments and features described in the present invention can be combined with each other. The present invention will now be described in detail with reference to the embodiments.

[0022] Example:

[0023] The solution provided by the embodiments of the present invention, as described above, provides a drone blood delivery platform management system. The system is built on a B / S architecture and includes an information management module, a work order management module, a flight route module, and a real-time monitoring module. Each module interacts with data through a platform service interface and communicates with drone equipment and temperature acquisition terminals, thereby realizing digital management and traceability of the entire blood transportation process.

[0024] The information management module is used for unified management of organizational information, departmental information, user information, role information, and drone equipment information. Organizations are the superior units of departments; the system supports creating organizations and maintaining their basic information through the "Add" operation. Departments are subordinate to organizations; the department management module creates subordinate departments and establishes hierarchical relationships. User management maintains user account information for the system backend and terminal APP, supporting adding, deleting, and resetting users' passwords, and assigning departments and roles to users. Role management configures system menu permissions and data permissions to restrict the data access scope of different users. Drone management maintains basic drone equipment information, including equipment code, equipment name, equipment model, serial number, affiliated organization, and current drone status, and supports adding, modifying, and deleting drone equipment.

[0025] The flight path module is used to manage the flight paths of UAVs. The flight path module includes a flight path configuration unit and a flight path synchronization unit. The flight path configuration unit is used to maintain basic flight path information, which includes the flight path name, origin airport name, destination airport name, and destination information, as well as the latitude and longitude coordinates of multiple waypoints. The flight path synchronization unit synchronizes data with the UAV scheduling system or an external flight path service system through an interface and updates the flight path data through scheduled tasks to ensure the real-time nature of the flight path information. When the system creates a delivery work order, it automatically matches the corresponding flight path based on the selected destination and associates the flight path information with the delivery work order.

[0026] The work order management module is used to create blood transportation and delivery work orders. Delivery work orders are entered through a mini-program or management system. Work order information includes the delivery drone, destination, estimated start time, and remarks. It also includes blood bag information configuration, which includes blood type, quantity of blood bags, and transportation requirements. After the delivery work order is created, the system generates a work order status and binds the work order information with the drone equipment and flight route information for subsequent transportation scheduling.

[0027] The real-time monitoring module is used to collect and record the flight process of the drone and the status of blood transportation. The real-time monitoring module includes a trajectory recording unit and a temperature monitoring unit. The trajectory recording unit is used to acquire the flight trajectory data generated during the flight of the drone. The flight trajectory data includes latitude and longitude information, flight time, flight altitude and drone operating parameters. The system automatically associates the drone flight data within the corresponding time period according to the drone equipment configured in the delivery work order and the work order execution time, thereby generating a flight trajectory record corresponding to the work order.

[0028] When there is a transit flight during the drone transportation process, the real-time monitoring module automatically associates multiple flight segment data and splices them together in chronological order to form a complete transportation trajectory. Users can view the drone's basic information, blood delivery information, and all flight records on the trajectory query interface, and the drone's flight path can be displayed through trajectory playback.

[0029] The temperature monitoring unit is used to collect ambient temperature data inside the blood transport box. The temperature data is acquired through a temperature acquisition terminal and uploaded to the platform system over time. The real-time monitoring module correlates the temperature data with the flight trajectory data over time and displays the temperature change curve during the transportation process synchronously during trajectory playback, thereby realizing visualized monitoring of blood cold chain transportation.

[0030] When displaying the flight trajectory, the system simultaneously shows the latitude and longitude records, temperature records, and real-time operating parameters of the drone during the flight, enabling users to trace the entire blood transportation process. When an abnormal temperature occurs during transportation, the system records the time of the abnormality and the corresponding flight location, and stores the abnormal information in association with the delivery work order for subsequent traceability analysis.

[0031] In addition, the system also includes a display dashboard module, which is connected to the real-time monitoring module and is used to perform statistical analysis on drone transportation data. The statistical data includes the total number of drones, the number of drones currently en route, the flight time this week, and the transportation mileage of the day. It can also statistically analyze the number of drone flights and blood delivery rankings, thereby realizing a visual display of the drone blood delivery platform's operating status.

[0032] Through the above technical solution, the present invention realizes unified management of work order management, route management, and flight trajectory and temperature monitoring in the process of unmanned aerial vehicle blood delivery, thereby improving the safety and traceability of the blood transportation process.

[0033] The above specific embodiments are merely explanations of the present invention and are not intended to limit the present invention. After reading this specification, those skilled in the art can make modifications to these embodiments without contributing any inventive step, but as long as they are within the scope of the claims of the present invention, they are protected by patent law.

Claims

1. A management system for a drone-based blood delivery platform, characterized by: The system includes an information management module, a work order management module, a flight route module, and a real-time monitoring module; The information management module manages information from the organization management terminal, user terminal, roles, and drones. Administrators can create and maintain organizational information through the organizational management interface, and the information management module stores the organizational information. Meanwhile, the information management module can maintain user information for the terminal APP, support adding users, deleting users and resetting user passwords, and assign departments and roles to users, and bind card numbers for device unlocking by swiping cards; The information management module supports adding roles, assigning backend and APP function menus, and configuring departmental data permissions to restrict the scope of data access. The information management module stores information such as the device code, name, model, and affiliated organization of the UAV, and updates the status of the UAV in real time. At the same time, the information management module supports adding, modifying, and deleting UAVs, and can control the operation functions according to the user's role and permissions. The route module can create and synchronize route information, which includes the route name, the names of the origin and destination airports, the destination, and the latitude and longitude configuration between points. The route module supports adding, modifying, and deleting routes, and can automatically synchronize data through scheduled tasks. In the work order management module, users enter delivery work orders through a mini-program, and managers manage the creation of delivery work orders. In the work order management module, users can select the drone model, destination, and delivery time, fill in remarks, and configure blood bag information according to actual transportation needs. After successfully creating a delivery work order, the delivery work order can be queried in the information management module. The real-time monitoring module automatically records the drone's flight trajectory and associates it with the blood delivery information and flight records. Users can query the drone's basic information, blood delivery information, and complete flight records. The module supports trajectory playback and displays the temperature, latitude and longitude, and real-time drone parameters during transportation to achieve traceability of the transportation process.

2. The unmanned aerial vehicle (UAV) blood delivery platform management system as described in claim 1, characterized in that: The organizational information includes basic organizational information and basic departmental information, with the organizational unit being the superior unit of the department; Users can create an organization by clicking "Add," and submit the completed required information to save the changes. Departments belong to an organization and maintain basic department information through department management, supporting the creation of new departments and the selection of a superior organization.

3. The unmanned aerial vehicle (UAV) blood delivery platform management system as described in claim 1, characterized in that: When the drone involves a transfer during flight, the real-time monitoring module associates and records multiple flight records.

4. The unmanned aerial vehicle (UAV) blood delivery platform management system as described in claim 1, characterized in that: The drone delivers blood to the designated location according to the delivery work order information in the work order management module and the route specified by the route module.