CN220103908U - Mortar simulated training shell and mortar simulated training system - Google Patents

Abstract

The present disclosure relates to a mortar simulated training shell and a mortar simulated training system. The mortar simulated training shell comprises: the bullet comprises a bullet, a bullet tail and a bullet body, wherein a fuze is arranged on the bullet; a plurality of ammunition can be repeatedly arranged in the tail of the bullet; one end of the bullet body is connected with one end of the bullet head far away from the fuze, and the other end of the bullet body is connected with one end of the bullet tail; the surface of the projectile body is provided with control means for controlling a plurality of said ammunition shots. The system includes a mortar simulated shell module, an electronic control module, and a remote control module. The problem that ammunition is insufficient when this disclosure can solve the shooting training to a certain extent, be convenient for develop the shooting training on a large scale to the simulation training shell of used mortar, operate through controlling means, simple to use, fear psychology when can overcome the training of the new soldier to a certain extent.

Description

Mortar simulated training shell and mortar simulated training system

Technical Field

The present disclosure relates to the field of mortar shell manufacturing technology, and more particularly, to a mortar simulated training shell and a mortar simulated training system.

Background

The mortar is a heavy fire equipment commonly used by army forces due to its great power, simple operation and flexible use. However, in practice firing, ammunition is consumed more and the requirements on the ground are higher. The method is influenced by a certain natural environment, which restricts the development of the firing practice of the mortar to a certain extent; meanwhile, the mortar shell belongs to a disposable consumable product, has higher price, has certain danger in operation, is insufficient for some new soldiers to grasp the performance characteristics, has certain fear psychology, is easy to cause deformation of training actions, has higher safety risk, and has certain difficulty in actual combat training of the new soldiers.

Accordingly, there is a need to provide a solution to improve one or more of the problems of the related art described above.

It should be noted that the information disclosed in the above background section is only for enhancing understanding of the background of the present disclosure and thus may include information that does not constitute prior art known to those of ordinary skill in the art.

Disclosure of Invention

A first aspect of the disclosed embodiments provides a mortar simulated training shell comprising:

the bullet is provided with a fuze;

the bullet tail can be internally provided with a plurality of ammunition for shooting repeatedly;

one end of the bullet is connected with one end of the bullet, which is far away from the fuze, and the other end of the bullet is connected with one end of the bullet tail; the surface of the projectile body is provided with a control device for controlling a plurality of the ammunition shots.

In an exemplary embodiment of the present disclosure, the tail includes a tail section including a plurality of tails and a loading section; one end of the loading part is connected with the tail wing part, and the other end of the loading part is connected with the projectile body; at least 6 ammunition to be launched are arranged in the loading part, and the ammunition to be launched is numbered 1-6 in sequence.

In an exemplary embodiment of the present disclosure, the control device includes:

the USB interface is connected with a circuit inside the projectile body and is used for charging the mortar simulated training projectile;

the power switch is connected with an internal bus line of the projectile body and is used for controlling the activation and the closing of the mortar simulated training projectile body;

the ammunition launching keys are sequentially numbered 1-6, and each numbered ammunition launching key is respectively and correspondingly electrically connected with one numbered ammunition launching key;

the ammunition launching indicating lamps are respectively and correspondingly arranged above one ammunition launching key and are respectively and electrically connected with one ammunition launching key;

the power switch is electrically connected with the USB interface, the ammunition firing keys and the ammunition firing indicator lamps respectively.

In an exemplary embodiment of the present disclosure, the warhead, the tail and the shell of the projectile are all made of a black hard resin material.

In an exemplary embodiment of the present disclosure, the control device is in real-time wireless communication with a remote control system.

In an exemplary embodiment of the present disclosure, the mortar simulated training shell to real mortar shell ratio is 1:1; the mortar simulated training shell has weights mounted inside for equalizing the weight of the mortar simulated training shell and the real mortar shell.

A second aspect of the disclosed embodiments provides a mortar simulation training system, comprising:

a mortar simulated shell module comprising a mortar simulated training shell;

an electronic control module disposed on the mortar simulated training shell for controlling activation, firing and closing of the mortar simulated shell module;

and the remote control module is in real-time communication connection with the electronic control module and is used for calculating the firing flight time and the explosion point of the mortar simulated training shell.

In an exemplary embodiment of the present disclosure, in the mortar simulation shell module, the mortar simulation training shell comprises;

the bullet is provided with a fuze;

a tail, wherein a plurality of ammunition to be launched are arranged in the tail;

one end of the bullet is connected with one end of the bullet, which is far away from the fuze, and the other end of the bullet is connected with one end of the bullet tail; the electronic control module is arranged on the surface of the projectile body.

In an exemplary embodiment of the present disclosure, the electronic control module includes:

the USB interface is connected with a circuit inside the projectile body and is used for charging the mortar simulated training projectile;

the power switch is connected with an internal bus of the projectile body and used for controlling the activation and closing of the mortar simulated training projectile;

the ammunition launching keys are sequentially numbered 1-6, and each numbered ammunition launching key is correspondingly connected with one numbered ammunition launching key respectively;

the ammunition launching device comprises a plurality of ammunition launching indicating lamps, a plurality of ammunition launching button and a plurality of ammunition launching button, wherein each ammunition launching indicating lamp is correspondingly arranged above one ammunition launching button and is correspondingly connected with one ammunition launching button;

the power switch is electrically connected with the USB interface, the ammunition firing keys and the ammunition firing indicator lamps respectively.

In an exemplary embodiment of the present disclosure, the warhead, the tail and the shell of the projectile are all made of a black hard resin material.

According to the mortar simulated training shell, a plurality of ammunition to be launched is repeatedly installed in the tail of the shell, and the installed ammunition to be launched is controlled through the control device on the surface of the shell, so that the mortar simulated training shell can be repeatedly utilized, the problem of insufficient ammunition during shooting training is solved to a certain extent, the shooting training is conveniently carried out on a large scale, and the used mortar simulated training shell is operated through the control device, is simple to use, and can overcome fear psychology during training of a new soldier to a certain extent.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the disclosure and together with the description, serve to explain the principles of the disclosure. It will be apparent to those of ordinary skill in the art that the drawings in the following description are merely examples of the disclosure and that other drawings may be derived from them without undue effort.

FIG. 1 illustrates a schematic structural diagram of a mortar simulated training shell in an exemplary embodiment of the present disclosure;

FIG. 2 illustrates a block diagram of a mortar simulation training system in an exemplary embodiment of the disclosure;

in the figure, 100, a mortar simulated training shell; 101. a bullet; 1011. a fuze; 102. a tail; 1021. a tail section; 1022. a tail wing; 1023. a loading part; 103. a shell body; 104. a control device; 1041. a USB interface; 1042. a power switch; 1043. firing ammunition keys; 1044. and (5) firing ammunition indicator lamps.

Detailed Description

Example embodiments will now be described more fully with reference to the accompanying drawings. However, the exemplary embodiments may be embodied in many forms and should not be construed as limited to the examples set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the concept of the example embodiments to those skilled in the art. The described features, structures, or characteristics may be combined in any suitable manner in one or more embodiments.

Furthermore, the drawings are merely schematic illustrations of the present disclosure and are not necessarily drawn to scale. The same reference numerals in the drawings denote the same or similar parts, and thus a repetitive description thereof will be omitted. Some of the block diagrams shown in the figures are functional entities and do not necessarily correspond to physically or logically separate entities. These functional entities may be implemented in software or in one or more hardware modules or integrated circuits or in different networks and/or processor devices and/or microcontroller devices.

A first aspect of the present exemplary embodiment provides a mortar simulated training shell 100, as shown in fig. 1, the mortar simulated training shell 100 comprising:

a warhead 101, wherein a fuze 1011 is arranged on the warhead 101;

a tail 102, wherein a plurality of ammunition to be launched are repeatedly arranged in the tail 102;

a projectile body 103, wherein one end of the projectile body 103 is connected with one end of the projectile head 101 far away from the fuze 1011, and the other end of the projectile body 103 is connected with one end of the projectile tail 102; the surface of the projectile body 103 is provided with a control device 104, which control device 104 is used for controlling a plurality of ammunition shots.

According to the mortar simulated training shell 100, a plurality of ammunition to be launched is repeatedly installed in the tail 102 of the mortar simulated training shell 100, and the installed ammunition to be launched is controlled through the control device 104 on the surface of the projectile body 103, so that the mortar simulated training shell 100 can be repeatedly utilized, the problem of insufficient ammunition during shooting training is solved to a certain extent, the shooting training is conveniently carried out on a large scale, and the used mortar simulated training shell 100 is operated through the control device 104, so that the mortar simulated training shell 100 is simple to use, and the fear of a new soldier during training can be overcome to a certain extent.

In one embodiment of the present disclosure, specifically, the tail 102 includes a tail section 1021 and a loading section 1023, the tail section 1021 including a plurality of tail fins 1022; one end of the loading unit 1023 is connected to the tail unit 1021, and the other end of the loading unit 1023 is connected to the projectile 103. And the number of ammunition to be set is limited, in this embodiment, at least 6 ammunition to be set is set inside the loading part 1023, and the ammunition to be set is numbered 1 to 6 in order. And after each shooting training, the ammunition can be repeatedly installed, so that the repeated use is realized, and the problem of insufficient ammunition during the shooting training is solved to a certain extent. And numbering the ammunition to facilitate the control of the control device 104 separately. And the number of ammunition shots installed determines the firing rate of the mortar simulated training shell 100. And the launched ammunition is simulated ammunition, and can be reinstalled in the loading part 1023 after simulated explosion, thereby realizing the recycling of the mortar simulated training shell 100.

In one embodiment of the present disclosure, the control device 104 provided on the surface of the projectile body 103 is specifically designed. The control device 104 includes:

a USB interface 1041, the USB interface 1041 being connected to a circuit inside the projectile body 103 for charging the mortar simulation training projectile 100;

a power switch 1042, the power switch 1042 being connected to the main line inside the projectile 103 for controlling the activation and closure of the mortar simulated training projectile 100; the power switch 1042 is a red button which is activated by pressing the red button after the mortar simulated training shell 100 has been set to the firing position. And when an emergency occurs, the emergency is closed by continuously pressing twice;

the ammunition firing button 1043 is a plurality of ammunition firing buttons 1043, the numbers of the ammunition firing buttons 1043 are 1-6 in sequence, and each numbered ammunition firing button 1043 is respectively and correspondingly and electrically connected with one numbered ammunition firing button. After pressing the red button and waiting for 3 seconds of activation time, the corresponding numbered ammunition firing button 1043 may be selected to press, and the corresponding ammunition firing may be controlled to fire. The ammunition firing button 1043 is numbered 1 to 6, the ammunition firing button 1043 No. 1 corresponds to the ammunition firing number No. 1, and so on, the ammunition firing button 1043 No. 6 corresponds to the ammunition firing number No. 6, so that the ammunition firing button 1043 which is pressed more later in number is more ammunition firing carried during firing, and the longer the firing range is. Thus by adjusting the number of ammunition shots, an adjustment of the firing distance of the mortar simulated training shell 100 is achieved.

The ammunition firing lamps 1044 are respectively and correspondingly arranged above one ammunition firing button 1043, and are respectively and electrically connected with one ammunition firing button 1043. After waiting for 3 seconds of activation time, the corresponding ammunition firing button 1043 is pressed, and the ammunition firing indicator light 1044 above it is turned on for displaying that the operation was successful.

The power switch 1042 is electrically connected to the USB interface 1041, the ammunition-firing buttons 1043, and the ammunition-firing lamps 1044, respectively. In this way, the charging and the electricity storage of the mortar simulated training shell 100 are uniformly controlled by the power switch 1042, and the power switch 1042 is used for respectively providing the electric energy for the ammunition firing button 1043 and the ammunition firing indicator lamp 1044, so that when the ammunition firing button 1043 is pressed, the corresponding ammunition firing indicator lamp 1044 is turned on and off.

In one embodiment of the present disclosure, the shells of the mortar simulated training shell 100, i.e. the shells of the warhead 101, the projectile 103 and the tail 102, are all provided as black hard resin materials. The material is a high-toughness material and has excellent surface quality and isotropic mechanical properties. By adopting the material, the mortar simulated training shell 100 is prevented from scratching internal devices and circuits when in repeated training use, and plays a role in protection.

In an embodiment of the present disclosure, the control device 104 further includes a wireless receiving and transmitting unit and an information processing unit, where the wireless receiving and transmitting unit may be disposed at the front of the warhead 101, and the inside is connected with the information processing unit of the control device 104 through a line; or may be provided on the projectile 103 or the tail 102, with the interior being wired. The wireless receiving and transmitting unit ensures that the control device 104 is in real time wireless communication with a remote control system, preferably a command unit console, which receives real time information of the mortar simulated training shell 100 transmitted by the control device 104 and calculates the firing time of the mortar simulated training shell 100 and the landing explosion point, thereby completing a simulated firing training.

In an embodiment of the present disclosure, in order to increase the realism of the simulated training, in this embodiment, the ratio of the mortar simulated training shell 100 to the real mortar shell is designed to be 1:1, the external structure is also made in the form of the real mortar shell, and a certain weight is installed inside the shell so that the weight of the mortar simulated training shell 100 is almost equal to that of the real mortar shell.

In summary, in the mortar simulated training shell 100 of the present disclosure, when in use, the mortar simulated training shell 100 is first set at a designated position, then the red button is pressed, the mortar simulated training shell 100 is activated, after waiting for 3 seconds of activation time, the corresponding ammunition firing button 1043 is pressed, and the ammunition firing indicator 1044 above the pressed ammunition firing button 1043 is lit. The control device 104 communicates in real time with a remote control system that calculates the firing time of flight and landing blast points of the mortar simulated training shell 100, thereby completing a simulated firing training.

A second aspect of the present exemplary embodiment provides a mortar simulation training system. As shown in fig. 2, the mortar simulation training system comprises:

a mortar simulated shell module comprising a mortar simulated training shell 100;

an electronic control module provided on the mortar simulation training shell 100 for controlling activation, firing and closing of the mortar simulation shell module;

and the remote control module is in real-time communication connection with the electronic control module and is used for calculating the shooting flight time and the explosion point of the mortar simulated training shell 100.

Further, in an embodiment of the present disclosure, the mortar simulated training shell 100 comprises:

a warhead 101, wherein a fuze 1011 is arranged on the warhead 101;

a tail 102, wherein a plurality of ammunition to be launched are repeatedly arranged in the tail 102;

a projectile body 103, wherein one end of the projectile body 103 is connected with one end of the projectile head 101 far away from the fuze 1011, and the other end of the projectile body 103 is connected with one end of the projectile tail 102; the surface of the projectile 103 is provided with an electronic control module for controlling a plurality of ammunition shots.

Further, in an embodiment of the disclosure, the electronic control module includes:

a USB interface 1041, the USB interface 1041 being connected to a circuit inside the projectile body 103 for charging the mortar simulation training projectile 100;

a power switch 1042, the power switch 1042 being connected to the main line inside the projectile 103 for controlling the activation and closure of the mortar simulated training projectile 100;

the ammunition firing button 1043 is a plurality of ammunition firing buttons 1043, the numbers of the ammunition firing buttons 1043 are 1-6 in sequence, and each numbered ammunition firing button 1043 is correspondingly connected with a numbered ammunition firing button. Each ammunition firing button 1043 is used to control firing of a corresponding ammunition firing;

a plurality of ammunition firing indicator lamps 1044, wherein each ammunition firing indicator lamp 1044 is respectively and correspondingly arranged above one ammunition firing button 1043 and is respectively and correspondingly connected with the ammunition firing button 1043 below;

the power switch 1042 is electrically connected to the USB interface 1041, the ammunition-firing buttons 1043, and the ammunition-firing lamps 1044, respectively. In this way, the charging and the electricity storage of the mortar simulated training shell 100 are uniformly controlled by the power switch 1042, and the power switch 1042 is used for respectively providing the electric energy for the ammunition firing button 1043 and the ammunition firing indicator lamp 1044, so that when the ammunition firing button 1043 is pressed, the corresponding ammunition firing indicator lamp 1044 is turned on and off.

Further, the shells of the mortar simulated training shell 100, namely, the shells of the warhead 101, the shell 103 and the tail 102 are all provided with a black hard resin material. The material is a high-toughness material and has excellent surface quality and isotropic mechanical properties. By adopting the material, the mortar simulated training shell 100 is prevented from scratching internal devices and circuits when in repeated training use, and plays a role in protection.

The second aspect of the present exemplary embodiment provides a mortar simulation training system that calculates the firing time of flight and the detonation point of the mortar simulation training shell 100 by connecting an electronic control module in real-time communication with a remote control module. The multiple ammunition shots are repeatedly arranged in the tail 102, and the arranged ammunition shots are controlled by the electronic control module on the surface of the projectile body 103, so that the mortar simulated training projectile 100 can be repeatedly utilized, the problem of insufficient ammunition during shooting training is solved to a certain extent, the large-scale shooting training is convenient to develop, the used mortar simulated training projectile 100 is operated by the control device 104, and the mortar simulated training projectile is simple to use, and can overcome fear psychology during training of a new soldier to a certain extent.

Further, the shells of the mortar simulated training shell 100, i.e., the shells of the warhead 101, the projectile 103 and the tail 102, are each provided with a black hard resin material. The material is a high-toughness material and has excellent surface quality and isotropic mechanical properties. By adopting the material, the mortar simulated training shell 100 is prevented from scratching internal devices and circuits when in repeated training use, and plays a role in protection.

It should be noted that although several units of the system for action execution are mentioned in the detailed description above, this partitioning is not mandatory. Indeed, the features and functions of two or more of the units described above may be embodied in one unit in accordance with embodiments of the present disclosure. Conversely, the features and functions of one unit described above may be further divided into a plurality of units to be embodied. Some or all of the units may be selected according to actual needs to achieve the objectives of the disclosed solution. Those of ordinary skill in the art will understand and implement the present utility model without undue burden.

Other embodiments of the disclosure will be apparent to those skilled in the art from consideration of the specification and practice of the disclosure disclosed herein. This application is intended to cover any adaptations, uses, or adaptations of the disclosure following, in general, the principles of the disclosure and including such departures from the present disclosure as come within known or customary practice within the art to which the disclosure pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the disclosure being indicated by the following claims.

Claims (10)

1. A mortar simulated training shell, said mortar simulated training shell comprising:

the bullet is provided with a fuze;

the bullet tail can be internally provided with a plurality of ammunition for shooting repeatedly;

one end of the bullet is connected with one end of the bullet, which is far away from the fuze, and the other end of the bullet is connected with one end of the bullet tail; the surface of the projectile body is provided with a control device for controlling a plurality of the ammunition shots.

2. A mortar simulated training shell as claimed in claim 1, wherein said tail comprises a tail section and a loading section, said tail section comprising a plurality of tails; one end of the loading part is connected with the tail wing part, and the other end of the loading part is connected with the projectile body; at least 6 ammunition to be launched are arranged in the loading part, and the ammunition to be launched is numbered 1-6 in sequence.

3. A mortar simulated training shell as claimed in claim 2, wherein said control means comprises:

the USB interface is connected with a circuit inside the projectile body and is used for charging the mortar simulated training projectile;

the power switch is connected with an internal bus line of the projectile body and is used for controlling the activation and the closing of the mortar simulated training projectile body;

the ammunition launching keys are sequentially numbered 1-6, and each numbered ammunition launching key is respectively and correspondingly electrically connected with one numbered ammunition launching key;

the ammunition launching indicating lamps are respectively and correspondingly arranged above one ammunition launching key and are respectively and electrically connected with one ammunition launching key;

the power switch is electrically connected with the USB interface, the ammunition firing keys and the ammunition firing indicator lamps respectively.

4. A mortar simulated training shell as claimed in claim 1, wherein said nose, said tail and said shell of said shell are each of a black hard resin material.

5. A mortar simulated training shell as claimed in claim 1, wherein said control means is in real time wireless communication with a remote control system.

6. A mortar simulated training shell as claimed in claim 1, wherein the ratio of mortar simulated training shell to real mortar shell is 1:1; the mortar simulated training shell has weights mounted inside for equalizing the weight of the mortar simulated training shell and the real mortar shell.

7. A mortar simulation training system, the mortar simulation training system comprising:

a mortar simulated shell module comprising a mortar simulated training shell;

an electronic control module disposed on the mortar simulated training shell for controlling activation, firing and closing of the mortar simulated shell module;

and the remote control module is in real-time communication connection with the electronic control module and is used for calculating the firing flight time and the explosion point of the mortar simulated training shell.

8. A mortar simulated training system as claimed in claim 7, wherein in said mortar simulated shell module said mortar simulated training shell comprises;

the bullet is provided with a fuze;

a tail, wherein a plurality of ammunition to be launched are arranged in the tail;

one end of the bullet is connected with one end of the bullet, which is far away from the fuze, and the other end of the bullet is connected with one end of the bullet tail; the electronic control module is arranged on the surface of the projectile body.

9. A mortar simulation training system as claimed in claim 8, wherein the electronic control module comprises:

the USB interface is connected with a circuit inside the projectile body and is used for charging the mortar simulated training projectile;

the power switch is connected with an internal bus line of the projectile body and is used for controlling the activation and the closing of the mortar simulated training projectile body;

the ammunition launching keys are sequentially numbered 1-6, and each numbered ammunition launching key is correspondingly connected with one numbered ammunition launching key respectively;

the ammunition launching device comprises a plurality of ammunition launching indicating lamps, a plurality of ammunition launching button and a plurality of ammunition launching button, wherein each ammunition launching indicating lamp is correspondingly arranged above one ammunition launching button and is correspondingly connected with one ammunition launching button;

the power switch is electrically connected with the USB interface, the ammunition firing keys and the ammunition firing indicator lamps respectively.

10. A mortar simulated training system as claimed in claim 9, wherein the casing of the bullet, tail and shell is of a black hard resin material.