CN113838330A - Multi-person collaborative virtual training drilling system and method for rescue - Google Patents

Abstract

The invention belongs to the technical field of virtual reality, and discloses a multi-person collaborative virtual training drilling system and a method for rescue, wherein the multi-person collaborative virtual training drilling system for rescue comprises a management end, a server and a drilling end; the management end, the server and the drilling end are respectively connected through a network; the management terminal is used for setting a virtual drilling scene and a drilling task, wherein the drilling task comprises a drilling scheme and a rescue route; the drilling end is used for displaying a virtual drilling scene and acquiring the drilling operation of rescue workers; the drill end is provided with a plurality of drill ends (including a command end and a common drill end); the server is used for running the drilling program, providing data storage, data forwarding, score calculation and statistics for each drilling end, recording data generated by each drilling end in the operation process in real time, and updating the virtual drilling scene according to the drilling operation. The problems of high drilling cost, long preparation period and unsatisfactory drilling effect in the prior art are solved.

Description

Multi-person collaborative virtual training drilling system and method for rescue

Technical Field

The invention belongs to the technical field of virtual reality, and particularly relates to a multi-person collaborative virtual training drilling system and method for rescue.

Background

Mine rescue is a technical measure for rapidly rescuing people in distress and handling accidents after a disaster occurs in a mine. In order to rapidly deal with mine accidents, protect life safety of workers, reduce national resource and property loss and organize high-level rescue teams, it is very important to be equipped with advanced rescue equipment. In the case of rescue, if the team and the departments do not exercise in advance, problems are easy to occur in cooperation, so that the rescue environments are not smoothly connected, precious rescue time is delayed, and rescue efficiency is seriously affected. Therefore, the rescue workers need to be trained and exercised regularly before the actual rescue work comes.

The existing rescue training and emergency drilling modes generally have the problems of poor training effect and low training efficiency, the emergency drilling cost is high, drilling sites are not easy to arrange, the drilling frequency is low, repeated drilling can not be carried out for multiple times, all disaster types and disaster occurrence sites can not be covered, and the consequences of various rescue schemes can not be compared, so that the expected training drilling effect is difficult to achieve.

For example, a training and practicing mode of single interactive operation or a teaching mode of intensively watching three-dimensional stereo films is adopted, the training and practicing mode has low interactivity, the students have weak sense of integration and substitution, and are easy to forget to see, rescue workers have no obvious capability improvement, and the effect is far from the expected effect. For example, a physical simulation drilling mode is used for drilling, that is, the prop is used for simulating a real scene for rescue workers to drill and train, in which case, a physical disaster area and a drilling site need to be arranged in advance. Although the input sense of the drilling mode is strong, if the disaster relief of various accidents is to be performed, a plurality of physical disaster areas need to be arranged, the arrangement time is long, the cost is too high, the drilling is not beneficial to performing the disaster relief of a plurality of scenes, and if only a single scene is performed for a plurality of times, the rescue ability of rescuers cannot be improved, so that the final purpose of training and drilling cannot be achieved.

Disclosure of Invention

The invention aims to provide a multi-person collaborative virtual training drilling system and method for rescue, and aims to solve the problems of high drilling cost, long preparation period and unsatisfactory drilling effect in the prior art.

The basic scheme provided by the invention is as follows: the multi-person collaborative virtual training drilling system for rescue comprises a management end, a server and a drilling end; the management end, the server and the drilling end are respectively connected through a network;

the management terminal is used for setting a virtual drilling scene and a drilling task, wherein the drilling task also comprises a drilling scheme and a rescue route, and a corresponding drilling program is generated;

the drilling end is used for displaying a virtual drilling scene and acquiring the drilling operation of rescue workers; the number of the drilling ends is multiple, and each drilling end is used for one rescue worker to perform drilling operation;

the server is used for running a drilling program, providing data storage, data forwarding and statistical functions for the drilling end, and updating the virtual drilling scene according to the drilling operation.

The principle and the advantages of the invention are as follows: the management terminal is used for constructing a virtual simulation accident scene, the server is used for building a drilling environment platform, running drilling programs, providing data storage, data forwarding and statistics functions for each drilling terminal, and updating a virtual drilling scene; the drill end is used for displaying a drill site, rescue workers carry out rescue operation through the drill end, and each rescue worker participates in virtual rescue training together by using a virtual display technology and a local area network online technology to complete the whole virtual rescue task together. The scheme has the advantages that: the virtual reality technology and disaster emergency rescue are perfectly combined to generate a new drilling mode, monotonous schematic drilling is converted into intelligent advanced and immersion interactive scene drilling, scene features which are difficult to embody in practice are displayed in a virtual reality mode, various drilling conditions can be set up, the drilling quality is improved, the drilling enthusiasm and initiative of rescuers are stimulated, the rescue ability and the cooperative operation ability of mine rescuers are effectively trained, the default contract among the rescuers is improved, and the method has the advantages of high drilling efficiency, low cost, short period and the like.

Further, the server comprises an operation module, an updating module and a synchronization module;

the operation module is used for acquiring and operating a drilling program, and the process of operating the drilling program comprises the steps of providing data storage, data forwarding and statistics functions for the drilling terminals and controlling the scene display of each drilling terminal;

the updating module is used for receiving the drilling operation of each drilling end and updating the drilling program according to the drilling operation;

the synchronization module is used for unifying the display pictures of the drilling ends when the drilling program is updated.

Has the advantages that: the server provides stable operation platform for virtual rescue drilling, and the server still includes synchronous module, and the synchronization of the scene of mainly being responsible for drilling to the scene asynchronous's of each drilling end condition appears in the avoiding, improves the experience of rescue personnel and the authenticity of drilling, guarantees that the drilling can go on smoothly.

Further, the management terminal comprises a setting module, a generating module and a storage module:

the setting module is used for setting drilling parameters, and the drilling parameters comprise virtual drilling scenes, planned drilling number, planned drilling time, prop names and quantity and drilling tasks;

the generating module is used for generating a corresponding drilling program according to the drilling parameters and sending the drilling program to the server;

the storage module is used for storing the drilling parameters.

Has the advantages that: the setting module can set up virtual rehearsal scene, plan rehearsal number of people, plan rehearsal time, stage property name and quantity and rehearsal task respectively, improves the diversification of rehearsal, through changing the rehearsal parameter, carries out the exercise under the different conditions to the rescue personnel, is favorable to arousing rescue personnel's rehearsal enthusiasm, improves rescue personnel's rescue ability, tempers rescue personnel's emergency ability.

Further, the drilling parameters also comprise drilling roles.

Has the advantages that: the management end can set different drilling roles according to different drilling tasks, and the drilling diversity is guaranteed.

Further, the drill end comprises a display module, a selection module and an acquisition module;

the selection module is used for selecting a drill role and sending a selection result to the server; the server controls the display picture of the drilling end according to the selection result;

the display module is used for displaying the virtual drilling scene;

the acquisition module is used for acquiring the drilling operation of the rescue workers and sending the drilling operation to the server, and the server is also used for updating the drilling program in real time according to the drilling operation.

Has the advantages that: the drill end provides a stable operation platform for the rescue workers, so that the rescue workers can be immersed in the rescue tasks, the selection module is arranged, the rescue workers can select different roles to drill, the whole drilling action process is known, and the rescue ability of the rescue workers is comprehensively improved.

Furthermore, the drilling end also comprises a character input module, and the character input module is used for inputting characters; the operation module is also used for acquiring the characters input by the drilling ends and controlling each drilling end to display the characters.

Has the advantages that: the drilling ends can communicate with each other through the character input module, so that rescue workers can cooperate with each other in the rescue drilling process, the smooth proceeding of rescue drilling activities is ensured, and the purpose of rescue and disaster relief cooperative training is realized.

Further, the drill end further comprises a voice module, and the voice module is used for carrying out real-time voice communication; the synchronization module is further used for acquiring real-time voice and synchronizing the real-time voice of each drill end.

Has the advantages that: can exchange through the pronunciation module between each rehearsal end, make the rescue personnel exchange the cooperation each other at the rescue rehearsal in-process to compare with the input characters, the pronunciation exchanges convenient and fast more, guarantees going on smoothly of rescue rehearsal, and compares with the characters exchange.

Further, the server also comprises a recording module; the recording module is still used for acquireing the rehearsal actual data, the rehearsal actual data includes actual rehearsal number of people, actual rehearsal time, stage property use quantity and the actual condition of accomplishing of rehearsal task, the storage module still is used for saving rehearsal actual data.

Has the advantages that: the storage module stores the practice actual data, so that the management terminal can check the practice situation conveniently, and the setting module can set the practice parameters conveniently.

Furthermore, the server further comprises an intelligent scoring module, the intelligent scoring module is used for obtaining performance operations of each drilling end to score each rescue worker, and the storage module is used for storing the scores.

Has the advantages that: the rescue personnel are scored, so that the rescue personnel can clearly position the self rescue ability, the rescue personnel are encouraged to work in rescue drilling, and the rescue ability is improved.

The invention also provides a multi-person collaborative virtual training drilling method for rescue, and any multi-person collaborative virtual training drilling system for rescue is used.

Drawings

Fig. 1 is a logic diagram of an embodiment of the multi-person collaborative virtual training drilling system and method for rescue according to the present invention.

Detailed Description

The following is further detailed by way of specific embodiments:

the embodiment is basically as shown in the attached figure 1: the multi-person collaborative virtual training drilling system for rescue comprises a management end, a server and a drilling end; the management end, the server and the drilling end are respectively connected through a network;

in this embodiment, the management terminal implements functions such as exercise scenario management, information management, score management, and connection status management. The management terminal comprises a setting module, a generating module and a storage module: the setting module is used for setting drilling parameters and a network state, wherein the drilling parameters comprise a virtual drilling scene, the number of planned drilling people, planned drilling time, the names and the number of properties, drilling roles and drilling tasks, the drilling tasks comprise drilling schemes and rescue routes, and the setting module is also used for setting emergencies (including accidents), derived accidents and temporarily newly added rescue tasks in the drilling process;

the virtual drilling scene is divided into a plurality of drilling maps, and the drilling maps comprise tunneling working face water permeation, belt conveyor fire, electrical equipment fire, grease storage fire, tunneling working face water permeation, cross-cut coal uncovering, tunneling working face coal and gas outburst, tunneling working face gas explosion and the like. The drilling roles comprise a base commander, a rescue team leader, a subsidiary team leader of the rescue team, a command department expert, a command department master command, a dispatcher, a subsidiary master command of the command department, a security department, a transportation department and an electromechanical department.

The generating module is used for generating a corresponding drilling program according to the drilling parameters and sending the drilling program to the server; the storage module is used for storing the drilling parameters.

In this embodiment, the hardware of the drilling end is a computer, and is provided with a keyboard, a mouse and a microphone, and is used for displaying the drilling scenes (fully mechanized mining face, tunneling face, combined mining face, underground parking lot, substation, and the like) generated by the system, so as to realize operations of ground alarm receiving, equipment selection, underground base establishment, disaster area reconnaissance, mine drawing marking, field marking, medical first aid, and disaster disposal, and perform real-time voice communication, and complete computer interaction of walking, equipment picking and equipment using. The plurality of drilling ends comprise a command end and a common drilling end, and each drilling end is used for a rescue worker to perform drilling operation; the drill terminal comprises a display module, a selection module, an acquisition module, a character input module and a voice module; the selection module is used for selecting a drill role and sending a selection result to the server; the server controls the display picture of the drilling end according to the selection result;

dividing work according to different role types; the command department role proposes a rescue scheme and is reasonably distributed to each rescue team commander and each member of the command department, the commander role receives the command department task and issues the command department task to the squad, and coordinates the cooperation with other squads, and the rescue squad role executes the disaster relief task; the rescue squadron is selected in a division manner, the captain of the team selects gas measurement and top measurement by default, the team member 1 is responsible for recording, the team member 2 is responsible for making site marks and marking on a drawing, the team members 3 and 4 are responsible for treating the persons in distress in the drilling, and the team members 5 and 6 lay telephone lines and are responsible for communication; the expert of the command department is responsible for making a scheme, planning a rescue route and communicating and coordinating the unified action of each department by a dispatcher; the tasks of roles such as a downhole base commander, a security department, a transportation department, an electromechanical department and the like are fixed, the downhole base commander is responsible for commanding rescue teams and reporting important information in the rescue process, the security department is responsible for security tasks, pulling warning lines and the like, the transportation department is responsible for rescuing goods and materials transportation, and the electromechanical department is responsible for maintaining downhole equipment and stopping power transmission.

The display module is used for displaying the virtual drilling scene; the acquisition module is used for acquiring the drilling operation of the rescue workers and sending the drilling operation to the server, and the server is also used for updating the drilling program in real time according to the drilling operation. The character input module is used for inputting characters; the voice module is used for carrying out real-time voice communication; and a plurality of departments and a plurality of rescue team members complete rescue training tasks through voice or character communication and mutual cooperation in a virtual simulation environment, so that the purpose of rescue and disaster relief collaborative training is realized.

The server is used for running a drilling program, providing data storage, data forwarding and statistical functions for the drilling end, and updating the virtual drilling scene according to the drilling operation. The server comprises an operation module, a recording module, an updating module, an intelligent scoring module and a synchronization module; the operation module is used for acquiring and operating a drilling program, the operation module is used for acquiring and operating the drilling program, and the process of operating the drilling program comprises the steps of providing data storage, data forwarding and statistics functions for the drilling terminals and controlling the scene display of each drilling terminal; the operation module is also used for acquiring the characters input by the drilling ends and controlling each drilling end to display the characters.

The synchronous module is used for unifying the display picture and the real-time voice of each drilling end when the drilling program is updated so as to avoid the situations of asynchronous scenes and delayed voice of each drilling role; the recording module is further used for acquiring practical drilling data, the practical drilling data comprise practical drilling number, practical drilling time, prop using number and practical drilling task completion conditions, and the storage module is further used for storing the practical drilling data; the intelligent scoring module is used for acquiring the drilling operation of each drilling end, the system provides a knowledge base of tasks to judge and prompt the correctness of the operation process, records the operation process of each user in detail, and scores according to preset scoring rules. The storage module is also used for storing the scores.

The intelligent scoring module scores in a deduction mode, the total score is 130, and the deduction is finished; the specific deduction standard comprises the following 21 items:

1. carrying equipment: firstly, the necessary equipment is not carried, and each button is 0.5 min; secondly, the subsequent related tasks cannot be completed, and corresponding scores are deducted; and thirdly, interference item equipment is carried, and deduction is avoided.

2. Equipment inspection + oxygen call self-inspection: selecting wrong answers, deducting 0.2 points per question/person, and deducting points in the whole team and accumulating; and secondly, after the well is drilled, the incomplete task scores are all deducted.

3. Establishing an underground base: knocking help and asking the top: the total is 2 minutes, the top plate is knocked for less than 2 times, 1 minute is buckled, and the side buckles are not knocked or knocked firstly for 2 minutes; the side knocking sequence is not limited, and the buttons are knocked for 0.5 minutes for 2 times or less. Measuring temperature and gas (multiple reference), wherein the measurement is carried out for 2 minutes, the upper position, the middle position and the lower position are respectively measured, and the measurement is omitted or not carried out for 2 minutes; measuring the temperature by 1 minute; testing gas: 1 minute for each of 3 gases; measuring wind: 1 point is totally divided, and the score can be obtained by taking out the wind measuring equipment, and 1 point is not taken out of the equipment; sixthly, testing the electric telephone: 1 point is counted, the score can be obtained by picking up the microphone, and 1 point is not picked up; seventhly, all the personnel leave the base to move a certain distance to perform task closing judgment (beyond 15 meters); the score of the selected base corresponds to A1\ A2\ A3\ A4: 5. 4, 3 and 2 points, if the base is not selected for 5 points within the specified time.

4. Knocking the upper and asking the top: knocking help and asking the top: the total is 2 minutes, the top plate is knocked for less than 2 times, 1 minute is buckled, the side buckles are not knocked or knocked for 2 minutes first, the side knocking sequence is not limited, and the buckles are knocked for less than 2 times for 0.5 minute; secondly, the step of: the operation is not standard, and two branches are deducted when the operation is not tested; and thirdly, eliminating all extreme posture problems such as straight tapping of the top of the head during tapping in 2 minutes (as a subjective item deduction).

5. Temperature measurement: the total score is 1.

6. Gas measurement: the gas is measured, 1 point for each category, and 1 point is deducted if the action is not standard (wrong method) or not measured.

7. Side wind: and (4) totally dividing into 1 point, testing according to an appointed path, and deducting 1 point.

8. Passing through the door wind: and the buttons are not measured for 1 point.

9. Hanging windbreak: reporting (0.5 min), measuring gas (0.5 min), hanging windbreak (5 min), reporting (0.5 min), marking on site (0.5 min) and marking mine map (0.5 min), and completing corresponding point deduction before clicking the completion button. Secondly, reporting and gas measurement are not in sequence, and the reporting and the gas measurement are completed before the windbreak is hung, and related scores are completely deducted. And thirdly, after hanging the wind barrier, reporting, marking on site, marking a mine drawing (no sequence is finished before leaving a hot spot area), and fourthly, hanging the correct time point of the wind barrier can be carried out after all tasks are finished. If the windbreak is hung under the condition that all the preposed tasks are not finished, 30 minutes are deducted; all outstanding pre-tasking scores are subtracted. Fifthly, if the player picks up the hot prop but does not hang the wind barrier in the specified trigger area, the player is prompted that the wind barrier cannot be hung in the area, and then the position is replaced. The system prompt is needed for picking up the wind barrier material (hot point prop): UI + voice.

10. The treatment of the wounded: firstly, a reporting button is not made for 1 minute before the wounded is cured, a top button for asking for help is not made for 2 minutes, air measurement is not made for 3 minutes, and temperature measurement is not made for 1 minute; secondly, reporting and gas measuring, help knocking and top asking and temperature measuring items are finished before the wounded are cured (no sequence is adopted), reporting, gas measuring, help knocking and top asking and temperature measuring are not finished before the wounded are cured, and relevant scores are completely deducted; thirdly, after the wounded person is treated, reporting, field marking and mine drawing marking (no sequence) are carried out; fourthly, field marking and mine drawing marking (without sequence, completed before carrying wounded); the human shape marking is completed before the wounded person is carried.

11. The person in distress: reporting, measuring qi (3 minutes, which must be finished before judging consciousness), judging consciousness, breathing (0.5 minute), heartbeat and pulse (0.5 minute) (tasks do not have a sequence), humanoid marking (0.5 minute), field marking (0.5 minute), and mine map marking (0.5 minute) (without a sequence, finished before leaving a hot spot area, unfinished or omitted steps, and all scores of the parts are deducted).

12. Draining in a water flooded area: firstly, reporting (0.5 minutes, 'ground base reporting and power transmission application') is carried out, a button (sending is finished by default) is sent to a finish point, a submersible pump switch, gas measurement, hydrogen sulfide measurement (1 minute, completion before the switch is turned on), water detection by an exploration stick (1 minute, completion before water is put into the submersible pump), dropping of the submersible pump into water, line connection at a switch, site marking (0.5 minute), and mine map marking (0.5 minute) (no sequence, completion before leaving a hot spot area can be carried out, and fraction deduction of the part is not finished or omitted).

13. A smoke passing area: reporting (0.5 min), measuring gas (3 min) and hanging a contact rope (1 min) (without sequence); the second step is that the connection rope: and hanging the contact ropes in the sequence of 1-6, and buckling 1 point if the contact ropes are not hung or hung wrongly.

14. High temperature zone: fast entering a high-temperature area to prompt overhigh temperature, report and measure temperature (1 minute), wearing heat insulation clothes (total score: 2 minutes, if no person wears the heat insulation clothes, each person buckles 1 minute until the heat insulation clothes are buckled), and turning on a water curtain switch (1 minute) (highlight prompt); after passing through the hot spot area, the task cannot be executed, and all scores are deducted.

15. Fire extinguishing (extinguishable): reporting (0.5 min), knocking help and asking for help (2 min), measuring gas (3 min) and measuring temperature (1 min) (without sequence), extinguishing fire (10 min, if the fire is not successfully extinguished after leaving a hot spot area, the fire is completely deducted), and reporting (0.5 min), mine map marking (0.5 min) and site marking (0.5 min) (without sequence, completing before leaving the hot spot area, not completing or omitting steps and deducting corresponding scores).

16. Fire extinguishing (non-extinguishable): building a wood board airtight wall: reporting (0.5 minutes, team members with disaster area telephones have special reporting function keys), measuring gas (3 gases need to be detected, can be detected by a multi-parameter or single detector, and are divided into 3 minutes, each gas is divided into 1 minute), building a wood board airtight wall (the wood board is triggered, and the wood board airtight wall is not built for 5 minutes), reporting (0.5 minutes), marking on site (0.5 minutes) and marking mine drawings (0.5 minutes); secondly, building the wood board sealing wall can be carried out only after all tasks are finished, and if all preposed tasks are not finished, building the wood board sealing wall for 30 minutes; all unfinished preposed tasks are deducted (hanging windbreak or building wood plate airtight wall is selected as an alternative); reporting and gas measurement are not in sequence, and the reporting and the gas measurement are completed before the wood board airtight wall is built, and the reporting and the gas measurement are completed before the wood board airtight wall is not built, and the related fractions are completely deducted; and fourthly, after the construction of the wood board airtight wall is finished, reporting, carrying out field marking and mine drawing marking (without sequence, the steps are finished before leaving the hot spot area, and corresponding scores are deducted if the steps are not finished or omitted).

17. And (3) damage treatment of the bracket: reporting (0.5 min), knocking help and asking for help (2 min), measuring gas (3 min) (without sequence), breaking and dismantling (2 min), supporting (3 min), reporting, marking a mine map (0.5 min) and marking a site (0.5 min), and deducting corresponding fractions in incomplete or omitted steps; and secondly, the completion sequence of the forcible entry and the support cannot be wrong, otherwise, all scores are deducted, and if the forcible entry is completed and the support is not completed, the corresponding scores of the support are deducted.

18. Answering: each title is 0.5 point.

19. Gas concentration anomaly (explosion point: gas concentration too high (over 2%)): opening a multi-parameter detection device (in an opening state), entering a gas abnormal hot spot area (the gas is transited from 1% to 2%, and the content of other gases is abnormal), alarming by the multi-parameter detection device, switching an optical gas detection instrument to detect the gas (2 minutes), reporting (0.5), evacuating (3 minutes), and deducting all the scores (5 minutes) if the gas is not detected, reported or evacuated.

20. And (3) mine drawing labeling: the notations are classified into 3 types: the direction symbol does not exist, and the position where people can approach is not existed; position where there is no sign of direction, but a person cannot approach; symbols along the roadway, and possibly pointed symbols, but positions which people can approach; marking the mark with error or less by 1, and deducting 0.5 minutes; and (4) totally dividing into 5 minutes until the buckling is finished.

21. And (3) field labeling: the notations are classified into 3 types: marking a place; secondly, marking the victim or the victim; thirdly, marking the air quantity of the wind measuring station; marking the mark with error or less by 1, and deducting 0.5 minutes; and dividing the total into 3 minutes until the deduction is finished.

The specific implementation process is as follows:

s1 sequentially starts the server, the management terminal and the plurality of drilling terminals.

S2 starts the setting module, selects a kind of drilling scene in the built-in map, sets the drilling task, the planning drilling number and time, the prop name and number, and sets the drilling role.

S3, selecting roles from the drilling ends; and performing division and selection according to different role types.

And S4, after the role selection is completed, firstly, the drill is started, the dispatcher receives an alarm, and after the alarm is received, the commander general command, the dispatcher, the commander auxiliary general command, the sanitation department, the transportation department and the electromechanical department are informed to build a rescue and disaster relief command department, and the rescue team is called to rescue the disaster.

S5 the members of the command department of emergency rescue and disaster relief in the system make the disaster relief plan, including the contents of the advancing route of disaster relief, the search and rescue of the people in distress, the recovery of disaster area, etc.

S6 rescue team receives the call instruction, takes team commander to rescue and relief command department to get task, team leader, team member No. 1-6, team deputy according to their task division work condition, selects the rescue equipment carried with them.

S7, after the equipment is selected, the team leader arranges the rescue team to check before battle through online voice, and after the team members finish the check, the team member waits for the team commander to get the task and returns.

S8 commanders with team arrive at the command department of emergency rescue and disaster relief preset in the system, and the task of disaster relief is obtained from the command department of emergency rescue and disaster relief, and the task includes task map, investigation advancing route, important place information in investigation region, disaster information in region, and possible distress personnel condition in region.

S9 commanders with team return from the command part, then take the rescue team who has finished the pre-war inspection to go down the well to the underground base, and start to scout the disaster area from the underground base, in the process of scout the disaster area, all scout data are reported to the underground base through voice, and the underground base reports the information to the emergency rescue command part.

S10 the command department receives the scouting information, organizes the expert to study the rescue scheme in time, and adjusts the scheme in real time.

S11, after each rescue team finishes all tasks of disaster relief, people relief, ventilation recovery and the like on the disaster relief scheme, task completion data are transmitted to the server.

And the S12 server automatically scores according to the uploaded drilling log, the task completion condition, the prop use record and the walking route and according to the set scoring rule.

And S13, the management end stores the drilling log, the task completion condition, the prop use record and the walking route.

The foregoing are merely exemplary embodiments of the present invention, and no attempt is made to show structural details of the invention in more detail than is necessary for the fundamental understanding of the art, the description taken with the drawings making apparent to those skilled in the art how the several forms of the invention may be embodied in practice with the teachings of the invention. It should be noted that, for those skilled in the art, without departing from the structure of the present invention, several changes and modifications can be made, which should also be regarded as the protection scope of the present invention, and these will not affect the effect of the implementation of the present invention and the practicability of the patent. The scope of the claims of the present application shall be determined by the contents of the claims, and the description of the embodiments and the like in the specification shall be used to explain the contents of the claims.

Claims (10)

1. A many people virtual training rehearsal system in coordination for rescue, its characterized in that: comprises a management end, a server and a drilling end; the management end, the server and the drilling end are respectively connected through a network;

the management terminal is used for setting a virtual drilling scene and a drilling task, wherein the drilling task also comprises a drilling scheme and a rescue route, and a corresponding drilling program is generated;

the drilling end is used for displaying a virtual drilling scene and acquiring the drilling operation of rescue workers; the number of the drilling ends is multiple, and each drilling end is used for one rescue worker to perform drilling operation;

the server is used for running a drilling program, providing data storage, data forwarding and statistical functions for the drilling end, and updating the virtual drilling scene according to the drilling operation.

2. The multi-person collaborative virtual training drill system for rescuing as claimed in claim 1, wherein: the server comprises an operation module, an updating module and a synchronization module;

the operation module is used for acquiring and operating a drilling program, and the process of operating the drilling program comprises the steps of providing data storage, data forwarding and statistics functions for the drilling terminals and controlling the scene display of each drilling terminal;

the updating module is used for receiving the drilling operation of each drilling end and updating the drilling program according to the drilling operation;

the synchronization module is used for unifying the display pictures of the drilling ends when the drilling program is updated.

3. The multi-person collaborative virtual training drill system for rescuing as claimed in claim 1, wherein: the management terminal comprises a setting module, a generating module and a storage module:

the setting module is used for setting drilling parameters, and the drilling parameters comprise virtual drilling scenes, planned drilling number, planned drilling time, prop names and quantity and drilling tasks;

the generating module is used for generating a corresponding drilling program according to the drilling parameters and sending the drilling program to the server;

the storage module is used for storing the drilling parameters.

4. The multi-person collaborative virtual training drill system for rescuing as claimed in claim 3, wherein: the drilling parameters also include a drilling role.

5. The multi-person collaborative virtual training drill system for rescuing as claimed in any one of claims 1 to 4, wherein: the drill terminal comprises a display module, a selection module and an acquisition module;

the selection module is used for selecting a drill role and sending a selection result to the server; the server controls the display picture of the drilling end according to the selection result;

the display module is used for displaying the virtual drilling scene;

the acquisition module is used for acquiring the drilling operation of the rescue workers and sending the drilling operation to the server, and the server is also used for updating the drilling program in real time according to the drilling operation.

6. The multi-person collaborative virtual training drill system for rescuing as claimed in claim 5, wherein: the drill terminal also comprises a character input module, and the character input module is used for inputting characters; the operation module is also used for acquiring the characters input by the drilling ends and controlling each drilling end to display the characters.

7. The multi-person collaborative virtual training drill system for rescuing as claimed in claim 5, wherein: the drill end also comprises a voice module, and the voice module is used for carrying out real-time voice communication; the synchronization module is further used for acquiring real-time voice and synchronizing the real-time voice of each drill end.

8. The multi-person collaborative virtual training drill system for rescuing as claimed in claim 5, wherein: the server also comprises a recording module; the recording module is still used for acquireing the rehearsal actual data, the rehearsal actual data includes actual rehearsal number of people, actual rehearsal time, stage property use quantity and the actual condition of accomplishing of rehearsal task, the storage module still is used for saving rehearsal actual data.

9. The multi-person collaborative virtual training drill system for rescuing as claimed in claim 8, wherein: the server further comprises an intelligent scoring module, the intelligent scoring module is used for obtaining the performance operation of each drill end to score each rescue worker, and the storage module is used for storing the scores.

10. A multi-person collaborative virtual training drilling method for rescue is characterized in that: the multi-person collaborative virtual training drill system for rescuing as claimed in any one of claims 1 to 4 and 6 to 9 is used.

Images