Individual soldier's portable air defense weapon simulator
Technical Field
The utility model relates to a weapon emulation field, in particular to individual soldier's portable type air defense weapon simulator is applicable to "people is in the ring" combat emulation.
Background
The individual portable air defense weapon is one of the individual weapons which are often important for our army, so the individual portable air defense weapon simulator is very important for analog training and is one of the key landing devices for analog training simulation. The portable air defense weapon simulator for the individual soldier mainly solves the problems of tactical action realization, tactical action uploading to an upper computer and space and position positioning of the simulator. With the continuous refinement of modern electronic technology, the miniaturization of the electronic module enables the electronic logic operation module in the simulator to be installed in the equipment; modern communication modules are becoming mature and miniaturized, and wireless transmission of communication between the simulator and an upper computer is achieved. Based on the above points, the utility model discloses can fall to the ground and implement. The final utility model discloses a single soldier's portable type air defense weapon simulator suitable for simulation training.
SUMMERY OF THE UTILITY MODEL
The utility model discloses an it is exactly not enough to solve prior art, provides an individual soldier's portable type air defense weapon simulator, can carry out the simulation training of individual soldier's portable type air defense guided missile.
The utility model adopts the following technical scheme:
an individual-soldier portable air defense weapon simulator comprises a model front end, a model rear end, a dynamic catching module control box and a small handle;
the dynamic capturing module control box is used for acquiring the position and posture data of the simulation simulator in real time and carrying out information interaction with an upper computer;
the front end of the model is conical, and the rear end of the model is cylindrical; the front end and the rear end of the model are respectively and fixedly connected to two sides of the movable catching module control box; the front end of the model, the rear end of the model and the control box of the movable catching module together present the simulation shape of the portable air defense weapon;
the small handle is fixedly connected to the lower end of the movable catching module control box, and a plurality of buttons and a rocker are arranged on the small handle and used for simulating set actions during training of the air defense weapon.
Furthermore, 3 buttons are arranged on the front side of the small handle, and the rocker is arranged on the side opposite to the buttons;
the buttons comprise an upper button, a middle button and a lower button; the upper button is used for simulating a switch of the air defense weapon, and indicates that the air defense weapon is opened when pressed down and indicates that the air defense weapon is closed when bounced; the middle button is used for simulating the aiming of an air defense weapon, and the parabolic track launched by the missile is adjusted by pressing the middle button; the lower button is used for simulating the launching of an air defense weapon, and a missile is launched when the lower button is pressed (the missile is launched in a VR virtual scene);
the rocker is used for simulating the movement of the personnel to be trained, and the rocker moves up, down, left and right to represent the movement of the personnel to be trained in the VR virtual scene in front, back, left and right directions respectively;
and the position state information of the button and the movement information of the rocker are interacted with the upper computer through a wireless network.
Furthermore, the upper button is a self-locking button, and the middle button and the lower button are self-resetting buttons.
Further, the movable capturing module control box is in a cube shape, the front side of the movable capturing module control box is fixedly connected with the front end of the model, and the rear side of the movable capturing module control box is fixedly connected with the rear end of the model; the left side, the upper side and the right side of the movable capturing module control box are respectively provided with a plurality of first LED lamps, the first LED lamps flicker during use, and the position postures of the movable capturing module control box are calculated by capturing the positions of the first LED lamps through the camera.
Further, the front end of the model is composed of an aluminum pipe with the caliber of 60mm and the wall thickness of 2mm and a conical cap, and the rear end of the model is made of an aluminum pipe with the caliber of 60 mm; the movable catching module control box adopts 125mm square tube aluminum profiles as a shell, two end parts adopt aluminum plates to make a box cover, the aluminum profile square tube and the box cover are locked and sealed through screws, and the total length of the simulation simulator is 700 mm.
Further, a first battery, a first power switch and a first charging port are arranged at the lower part of the movable capturing module control box; and a second battery, a second power switch and a second charging port are arranged at the bottom end of the small handle.
Further, the control box of the movable capture module is powered by a first battery with 11.1V, and a first charging port is a DC circular socket; the first battery supplies power to the power supply conversion board, and the power supply conversion board converts 11.1V voltage into 3.3V working voltage and supplies the working voltage to the control circuit board of the movable LED lamp; the power supply conversion board has a voltage monitoring function at the same time, is used for monitoring the voltage of the battery in real time, and prompts through the second LED indicating lamp when the voltage of the battery is lower than a lower limit set value.
Furthermore, the small handle is powered by a second 8.4V battery, and a second charging port is a micro USB; the control circuit board arranged in the small handle is provided with a voltage conversion circuit and a voltage sampling circuit; the voltage conversion circuit converts the 8.4V voltage into a 3.3V working voltage and then supplies the working voltage to the button and the rocker; the voltage sampling circuit collects battery voltage information and prompts the battery voltage information through a third LED indicating lamp when the battery voltage is lower than a lower limit set value.
Furthermore, the upper computer is a backpack computer.
Further, each small handle has a unique PANID identification, and the micro USB charging port is also used for detecting the PANID of the small handle.
The utility model has the advantages that: the utility model discloses simple structure is compact, realizes showing the perfect unity that action and VR virtual scene participated in training personnel action when can accomplishing the training and attend to the portable air defense guided missile of air defense weapon simulator, has popularization application prospect.
Drawings
Fig. 1 is a schematic structural diagram of an individual-soldier portable air defense weapon simulator according to an embodiment of the present invention.
Fig. 2 is a schematic view showing a combination of a control box and a small handle of the dynamic catching module in the embodiment.
FIG. 3 is a schematic view of a small grip of an embodiment.
Fig. 4 shows an electrical schematic diagram of the small grip in the embodiment.
In the figure: 1-model front end; 2-model back end; 3, moving the catching module control box; 4-small handle; 41-up button; 42-center button; 43-lower button; 44-rocker.
Detailed Description
Specific embodiments of the present invention will be described in detail below with reference to the accompanying drawings. It should be noted that technical features or combinations of technical features described in the following embodiments should not be considered as being isolated, and they may be combined with each other to achieve better technical effects.
As shown in fig. 1, the embodiment of the present invention provides a simulation simulator for an individual-soldier portable air defense weapon, which includes a control box 3 for a movable catching module, a small handle 4, a front end 1 of a model, and a rear end 2 of the model. As a preferred embodiment, the simulator has an overall length of 700 mm. The model front end 1 is composed of an aluminum pipe with the caliber of 60mm and the wall thickness of 2mm and a conical cap, the movable capturing module control box 3 adopts a 125mm x 125mm square pipe aluminum profile as a shell, two ends of the movable capturing module control box adopt aluminum plates to make a box cover, the aluminum profile square pipe and the box cover are locked and sealed through screws, and the model rear end 2 is made of an aluminum pipe with the caliber of 60 mm. The front end 1 of the model and the rear end 2 of the model are connected into a whole by a flange and a dynamic catching module control box 3. The lower part of the dynamic catching module control box 3 is connected with a small handle 4. The small handle 4 is provided with 3 buttons, 1 rocker 44, 1 LED lamp, 1 round switch and a micro USB charging port.
The circuit part of the air defense weapon simulator mainly comprises a dynamic catching module control box 3 and a small handle 4 simulating a missile launching operation part. The dynamic catching module control box 3 is mainly used for collecting posture change data of a weapon, and the small handle 4 is used for simulating the movement of the weapon operated by a trainee and the movement of the trainee.
In a specific embodiment, the dynamic capture module control circuit board is installed in the dynamic capture module control box 3 and comprises 11 first LED lamps and 2 PDs, and the first LED lamps and the PDs are respectively arranged on the left side, the upper side and the right side of the dynamic capture module control box 3. Regular scintillation of first LED lamp among the simulation training process, the camera that arranges in the VR scene gathers the position change data of first LED lamp, fuses with backstage VR virtual model after handling simulator gesture data to real action is unanimous with the virtual model action. A first charging port and a first power switch are installed below the movable capturing module control box 3, and 1 double-color second LED lamp is further installed on the left side of the movable capturing module control box. The movable catching module is powered by an 11.1V lithium battery, the battery is arranged in a battery box, and the battery box is fixed at the bottom of the movable catching module control box 3. The lithium battery is charged by a special charger. The first power switch is used for switching on and off a first power supply of the movable capture module control box 3. The double-color second LED lamp is used for indicating the electric quantity, the second LED lamp is green under the normal condition, and the second LED lamp is changed from green to red when the electric quantity of the battery is lower than the low-voltage threshold value. The first power source must be charged at this time, otherwise it cannot be guaranteed that the weapon can be used normally during the training.
In a specific embodiment, the front end of the small handle 4 is provided with 1 bicolor third LED lamp and 3 buttons, the rear end is provided with 1 rocker 44, and the bottom of the small handle 4 is provided with 1 micro USB charging port (second charging port) and 1 second power switch. The double-color third LED lamp is used for indicating the electric quantity condition of the small handle 4, when the electric quantity is sufficient, the third LED lamp is displayed to be green, and when the electric quantity is lower than a charging set value, the third LED lamp is displayed to be red. The 3 buttons are used to simulate the weapon operation action. The upper button 41 at the top is a self-locking button, and when the upper button 41 is pressed down, the button cannot automatically rebound, and the button needs to be pressed down again to automatically rebound. The button is used for simulating weapon on/off, the button is pressed to indicate that the weapon is opened, and the button is bounced to indicate that the weapon is closed; the middle button 42 and the lower button 43 are self-reset buttons, and when the buttons are pressed by hands, the circuit is conducted, and when the release button is lifted by fingers, the circuit is disconnected. The middle button 42 is used to simulate weapon aiming and pressing this button adjusts the parabolic trajectory of the missile launch. The lower button 43 at the front is used for simulating weapon launching, and when the parabolic track of missile launching is adjusted to the correct position, the lower button 43 is pressed to launch the missile. The rocker 44 is used for simulating movement of the training personnel, and the rocker 44 moves up, down, left and right to represent movement of the training personnel in front, back, left and right directions in the VR virtual scene respectively. Preferably, the rocker 44 is provided with a self-reset button in the center, which button is turned on by pressing the rocker 44. The button is temporarily reserved and corresponding functions can be added as required. And the round second power switch at the bottom of the small handle 4 is used for controlling the on-off of the power supply of the small handle 4. The Micro USB port is used for charging an 8.4V lithium battery in the small handle 4 and setting PANID of the small handle 4.
The control box 3 of the dynamic catching module and the small handle 4 belong to independent modules, are not electrically connected, independently supply power and independently communicate.
In a preferred embodiment, the control box 3 of the dynamic capture module is powered by an 11.1V lithium battery, and the charging port is a small-size DC circular socket. The power supply of 11.1V is supplied to the power conversion board, and the power conversion board converts the voltage of 11.1V into the voltage of 3.3V and supplies the voltage to the control panel of the movable LED lamp. The power supply conversion board has a voltage monitoring function at the same time, is used for monitoring the voltage of the battery in real time, and prompts through the second LED indicating lamp when the voltage of the battery is lower than a lower limit set value.
In a preferred embodiment, the small handle 4 is powered by an 8.4V lithium battery, and the charging port is micro USB. The control circuit board inside the small handle 4 is provided with a voltage conversion circuit and a voltage sampling circuit. The voltage conversion circuit converts the 8.4V voltage into 3.3V voltage and then supplies the voltage to other control modules. The voltage sampling circuit collects the voltage of the battery through the ADC, and after the voltage sampling circuit analyzes the voltage of the battery through the MCU, the voltage sampling circuit indicates whether the battery needs to be charged through the LED lamp. If the LED lamp is green, the battery capacity of the small handle is sufficient, and if the LED lamp is red, the battery capacity of the small handle 4 is low, and the battery needs to be charged.
When the personnel of participating in operation air defense weapon simulator, air defense weapon simulator communication system sends weapon action data frame to backpack computer according to the personnel operation action of participating in real time, and wherein the weapon action includes: an on button 41, an on button 42, an off button 43, and an operation rocker 44. And the weapon action frame reported to the backpack computer by the small handle 4 of the air defense weapon simulator carries rocker position coordinate sampling information to indicate the moving coordinate of VR virtual participant.
Preferably, each participant is equipped with a backpack computer and several weapons, all weapons having the same PANID as the backpack computer, forming an independent ZigBee network. The backpack computer is used as a main machine of the network, and the weapon is used as a slave machine of the network. The portable air defense missile of the air defense weapon simulator is used as a slave machine and is automatically networked with the backpack computer after being started, when a participant operates the small handle 4 arranged below the air defense missile of the air defense weapon simulator, the ZigBee module of the small handle 4 sends the information of the operation button of the participant to the backpack computer in real time, and after the computer collects the information sent by the small handle 4, the information is synchronized with the operation action of the participant in a VR virtual scene, so that the simulated training is realized. In the training process, the small grip can send data to the back-loading computer once when a training person operates one button or operates the rocker once, and different buttons correspond to different data frames.
Preferably, each air weapon simulator portable air defense missile is equipped with a small grip 4, and each small grip 4 is provided with a unique PANID (network identifier). The PANID of the portable air defense missile provided with the air defense weapon simulator is the same as those of the backpack computer and other weapons, and all the equipment can be automatically networked to form an independent ZigBee network after being started. Each set of equipment is provided with a ZigBee receiver for a backpack computer with a U disk shape and 1 PANID setting module with the U disk shape, and the ZigBee receiver and the PANID setting module have unique PANID and cannot be modified. Each set of equipment takes a backpack computer as a main machine, and the other weapons are slave machines. The host is used as a coordinator of the ZigBee network, and the slave is used as a router. In principle, the attending personnel are not allowed to use the weapon at will. If the air-defense missile of the air-defense weapon simulator needs to be replaced due to special reasons, a trainee needs to open the power supply of the air-defense missile of the new air-defense weapon simulator, the PANID setting module is inserted into the micro USB interface of the air-defense missile of the air-defense weapon simulator, the air-defense missile of the air-defense weapon simulator automatically reads the PANID in the PANID setting module after detecting the PANID setting module, and the original PANID in the air-defense missile of the air-defense weapon simulator is updated. When PANID of the new air defense weapon simulator air defense missile is consistent with the backpack computer, the air defense weapon simulator air defense missile is added into the ZigBee network of the device, and normal training can be started.
While several embodiments of the present invention have been presented herein, it will be appreciated by those skilled in the art that changes can be made to the embodiments herein without departing from the spirit of the invention. The above-described embodiments are merely exemplary and should not be taken as limiting the scope of the invention.