CN220455986U - Self-propelled gun 3D vision synchronous response simulation experiment platform - Google Patents

Abstract

The utility model discloses a 3D visual synchronous response simulation experiment platform of a self-propelled gun, which comprises a platform for the self-propelled gun simulation experiment, wherein two groups of baffles are fixedly arranged on one side of the platform, a screw is rotationally connected to the two groups of baffles, a screw sleeve is in threaded connection with the outer wall of the screw, a dust shielding mechanism is arranged on the upper end face of the screw sleeve, a sliding groove is arranged on the upper end face of the platform, a supporting plate is slidingly connected to the sliding groove, a mounting block is fixedly arranged on the upper end face of the supporting plate, a dust-driving fan is detachably arranged in the mounting block, and an intermittent mechanism for changing the dust-driving fan is arranged on the mounting block. The dust shielding mechanism is arranged, so that the experimental articles can be conveniently prevented from being dust, and meanwhile, the intermittent mechanism is arranged, so that dust on the dust-dispelling cloth can be conveniently cleaned.

Description

Self-propelled gun 3D vision synchronous response simulation experiment platform

Technical Field

The utility model relates to the technical field of experimental platforms, in particular to a self-propelled gun 3D vision synchronous response simulation experimental platform.

Background

The digital layered rendering 3D visual synchronous response simulation experiment platform of the self-propelled gun mainly aims at research and development units, use units, related institutions and other institutions of the self-propelled gun to study the technologies of self-propelled gun emission state, emission effect, ballistic effect, emission performance in multi-terrain state and the like, and provides an experiment tool in a three-dimensional simulation environment.

The system adopts a high-definition view to display a high-precision experimental scene, simulates various terrain environments, provides richer terrain resources for users, utilizes a main stream model generating tool, and creates 1:1 a high-precision self-propelled gun digital model truly simulates the mechanical structure of gun equipment, and the animation shows the mechanical motion working state and working principle.

On this basis, the simulation experiment platform taking the self-propelled gun terrain environment as a model is also manufactured by the relevant mechanism, so that the requirement of different crowds on the playability of the simulation gun is met, but the existing simulation experiment platform is poor in dustproof effect when not used, and the simulation experiment platform is easy to be polluted after being exposed for a long time.

Disclosure of Invention

The utility model aims to solve the problem of poor dustproof effect of a simulation experiment platform in the prior art, and provides a 3D vision synchronous response simulation experiment platform for a self-propelled gun.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

the utility model provides a self-propelled gun 3D vision synchronous response simulation experiment platform, includes the platform that is used for self-propelled gun simulation experiment, platform one side fixed mounting has two sets of baffles, two sets of baffle internal rotation is connected with the lead screw, threaded connection has the silk cover on the lead screw outer wall, silk cover up end is equipped with hides dirt mechanism, the platform up end is equipped with the spout, sliding connection has the backup pad in the spout, backup pad up end fixed mounting has the installation piece, demountable installation has the dust expelling fan in the installation piece, be equipped with the intermittent type mechanism that changes the dust expelling fan on the installation piece.

Preferably, the intermittent mechanism comprises a rack fixedly arranged on the lower end surface of the supporting plate, a main bevel gear is fixedly arranged at one end of the screw rod penetrating through the baffle, two groups of fixing blocks are fixedly arranged on one side of the platform, a rotating rod is respectively and rotatably connected with the two groups of fixing blocks, a worm is fixedly arranged between the two groups of rotating rods, a secondary bevel gear is fixedly arranged at one end of the rotating rod penetrating through one group of fixing blocks, the main bevel gear is meshed with the secondary bevel gear, a worm wheel is meshed with the worm, a linkage rod is connected with an inner key of the worm wheel, the linkage rod is rotatably connected in the platform, a gear lack is connected with an outer wall of the linkage rod through a key, and the gear lack is meshed with the rack.

Preferably, the dust shielding mechanism comprises a first sliding block fixedly arranged on the upper end face of the wire sleeve, the first sliding block is slidably connected to the edge of the platform, a second sliding block is correspondingly slidably connected to the edge of the other side of the platform, a dust driving rod is fixedly arranged between the first sliding block and the second sliding block, a slot is formed in the inner side of the platform, a winding rod is rotationally connected to the slot, dust driving cloth is wound on the outer wall of the winding rod, one end of the dust driving cloth is fixedly arranged on the outer wall of the dust driving rod, a torsion spring is sleeved at one end of the winding rod penetrating through the platform, and one end of the torsion spring is fixedly arranged on the platform.

Preferably, a motor is fixedly installed on one group of the baffle plates, one end of the screw rod is fixedly installed on a motor rotor shaft, a dust collecting block is fixedly installed between the first sliding block and the second sliding block, and one end of the dust collecting block abuts against the dust driving rod.

Compared with the prior art, the utility model provides a self-propelled gun 3D vision synchronous response simulation experiment platform, which has the following beneficial effects:

1. this a simulation experiment platform for walking gun 3D vision synchronous response through setting up and hide dirt mechanism, only needs the starter motor, and the motor drives the lead screw and rotates, and first slider is spacing to the direction of rotation of silk cover to drive the dirt pole that drives between first slider and the second slider and do linear motion, so make the dirt cloth that drives on the dirt pole protect experimental article.

2. This a simulation experiment platform for walking gun 3D vision synchronous response is through setting up intermittent type mechanism for when the motor drove the lead screw and rotates, drive the backup pad through gear engagement linkage and do reciprocating motion in the spout, so start simultaneously and drive the dirt fan, thereby clear up the dust on the dust cloth, make the dust fall into the integrated piece at last.

The device has the advantages that the dust shielding mechanism is arranged, so that the experimental articles can be conveniently prevented from being dust, and meanwhile, the intermittent mechanism is arranged, so that dust on the dust-removing cloth can be conveniently cleaned.

Drawings

Fig. 1 is a schematic structural diagram of a self-propelled gun 3D vision synchronous response simulation experiment platform provided by the utility model;

fig. 2 is an enlarged schematic diagram of a part a of a self-propelled gun 3D vision synchronous response simulation experiment platform provided by the utility model;

fig. 3 is an enlarged schematic diagram of a b-site of a 3D vision synchronous response simulation experiment platform of a self-propelled gun according to the present utility model.

In the figure: 1. a platform; 2. a baffle; 3. a screw rod; 4. a silk sleeve; 5. a chute; 6. a support plate; 7. a mounting block; 8. a dust-removing fan; 9. a rack; 10. a main bevel gear; 11. a fixed block; 12. a rotating lever; 13. a secondary bevel gear; 14. a worm wheel; 15. a linkage rod; 16. a gear-missing; 17. a first slider; 18. a second slider; 19. a dust-removing rod; 20. slotting; 21. a winding rod; 22. dust-removing cloth; 23. a torsion spring; 24. a motor; 25. a dust collection block; 100. a dust shielding mechanism; 101. an intermittent mechanism; 102. a worm.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

In the description of the present utility model, it should be understood that the terms "upper," "lower," "front," "rear," "left," "right," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the present utility model and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

Referring to fig. 1-3, a self-propelled gun 3D vision synchronous response simulation experiment platform comprises a platform 1 for a self-propelled gun simulation experiment, wherein two groups of baffles 2 are fixedly installed on one side of the platform 1, a screw rod 3 is rotationally connected to the two groups of baffles 2, a screw sleeve 4 is connected to the outer wall of the screw rod 3 in a threaded manner, a dust shielding mechanism 100 is arranged on the upper end face of the screw sleeve 4, a chute 5 is arranged on the upper end face of the platform 1, a supporting plate 6 is connected in a sliding manner in the chute 5, an installation block 7 is fixedly installed on the upper end face of the supporting plate 6, a dust-driving fan 8 is detachably installed in the installation block 7, and an intermittent mechanism 101 for changing the dust-driving fan 8 is arranged on the installation block 7;

by arranging the dust shielding mechanism 100, the experimental articles in the platform 1 are conveniently protected;

the dust shielding mechanism 100 comprises a first sliding block 17 fixedly arranged on the upper end face of the wire sleeve 4, the first sliding block 17 is in sliding connection with the edge of the platform 1, a second sliding block 18 is correspondingly in sliding connection with the edge of the other side of the platform 1, a dust driving rod 19 is fixedly arranged between the first sliding block 17 and the second sliding block 18, a slot 20 is arranged on the inner side of the platform 1, a winding rod 21 is rotationally connected with the slot 20, dust driving cloth 22 is wound on the outer wall of the winding rod 21, one end of the dust driving cloth 22 is fixedly arranged on the outer wall of the dust driving rod 19, a torsion spring 23 is sleeved at one end of the winding rod 21 penetrating through the platform 1, and one end of the torsion spring 23 is fixedly arranged on the platform 1;

by arranging the torsion spring 23, the dust-driving cloth 22 cannot generate excessive wrinkles when the winding rod 21 winds the dust-driving cloth 22;

a motor 24 is fixedly arranged on the group of baffles 2, one end of a screw rod 3 is fixedly arranged on a rotor shaft of the motor 24, a dust collecting block 25 is fixedly arranged between the first sliding block 17 and the second sliding block 18, and one end of the dust collecting block 25 is propped against the dust removing rod 19;

by arranging the dust collecting block 25, dust blown by the dust expelling fan 8 is conveniently collected;

in the utility model, when the experimental article in the platform 1 is required to be protected, only the motor 24 is required to be started, the motor 24 drives the screw rod 3 to rotate, the first sliding block 17 limits the rotation direction of the wire sleeve 4, so that the wire sleeve 4 linearly moves on the screw rod 3, the dust-removing rod 19 between the first sliding block 17 and the second sliding block 18 is driven to linearly move, and the dust-removing cloth 22 on the dust-removing rod 19 is used for protecting the experimental article.

Example 2:

referring to fig. 1-3, an intermittent mechanism 101 includes a rack 9 fixedly mounted on a lower end surface of a support plate 6, a lead screw 3 fixedly mounted on a main bevel gear 10 penetrating through one end of a baffle 2, two groups of fixed blocks 11 fixedly mounted on one side of a platform 1, rotating rods 12 respectively rotatably connected to the two groups of fixed blocks 11, a worm 102 fixedly mounted between the two groups of rotating rods 12, a secondary bevel gear 13 fixedly mounted on one end of the rotating rods 12 penetrating through one group of fixed blocks 11, the main bevel gear 10 meshed with the secondary bevel gear 13, a worm wheel 14 meshed with the worm 102, a linkage rod 15 connected with an inner key of the worm wheel 14 in a rotating manner, a gear-missing 16 connected with an outer wall of the linkage rod 15 in a key manner, and the gear-missing 16 meshed with the rack 9;

when the motor 24 drives the lead screw 3 to rotate, the lead screw 3 drives the main bevel gear 10 to rotate, the main bevel gear 10 is meshed with the auxiliary bevel gear 13, thereby driving the rotating rod 12 to rotate, the worm 102 is driven to rotate while the rotating rod 12 rotates, the worm 102 drives the linkage rod 15 in the worm wheel 14 to rotate, the linkage rod 15 rotates while driving the gear lack 16 to rotate, the gear lack 16 is meshed with the rack 9, thereby driving the supporting plate 6 to reciprocate in the chute 5, and thus the dust driving fan 8 is started simultaneously, dust on the dust driving cloth 22 is cleaned, and finally the dust falls into the dust collecting block 25.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (4)

1. The utility model provides a self-propelled gun 3D vision synchronous response simulation experiment platform, includes platform (1) that is used for self-propelled gun simulation experiment, its characterized in that, platform (1) one side fixed mounting has two sets of baffles (2), two sets of baffle (2) internal rotation is connected with lead screw (3), threaded connection has silk cover (4) on lead screw (3) outer wall, silk cover (4) up end is equipped with dust shielding mechanism (100), platform (1) up end is equipped with spout (5), sliding connection has backup pad (6) in spout (5), backup pad (6) up end fixed mounting has installation piece (7), demountable installation in installation piece (7) is last to be equipped with intermittent type mechanism (101) that change dust-expelling fan (8).

2. The self-propelled gun 3D vision synchronous response simulation experiment platform according to claim 1, wherein the intermittent mechanism (101) comprises a rack (9) fixedly installed on the lower end face of the supporting plate (6), a main bevel gear (10) is fixedly installed at one end of the screw rod (3) penetrating through the baffle plate (2), two groups of fixing blocks (11) are fixedly installed on one side of the platform (1), rotating rods (12) are respectively connected to the two groups of fixing blocks (11) in a rotating mode, a worm (102) is fixedly installed between the two groups of rotating rods (12), a secondary bevel gear (13) is fixedly installed at one end of the rotating rods (12) penetrating through one group of fixing blocks (11), the main bevel gear (10) is meshed with the secondary bevel gear (13), the worm (102) is meshed with a worm wheel (14), a linkage rod (15) is connected to the inner key of the worm wheel (14), a gear (16) is connected to the outer wall of the linkage rod (15) in a rotating mode, and the gear (16) is meshed with the rack (9).

3. The self-propelled gun 3D vision synchronous response simulation experiment platform according to claim 1, wherein the dust shielding mechanism (100) comprises a first sliding block (17) fixedly installed on the upper end face of the wire sleeve (4), the first sliding block (17) is slidably connected to the edge of the platform (1), a second sliding block (18) is correspondingly slidably connected to the edge of the other side of the platform (1), a dust driving rod (19) is fixedly installed between the first sliding block (17) and the second sliding block (18), a slot (20) is formed in the inner side of the platform (1), a winding rod (21) is rotationally connected to the slot (20), dust driving cloth (22) is wound on the outer wall of the winding rod (21), one end of the dust driving cloth (22) is fixedly installed on the outer wall of the dust driving rod (19), one end of the winding rod (21) penetrates through one end of the platform (1) and is sleeved with a torsion spring (23), and one end of the torsion spring (23) is fixedly installed on the platform (1).

4. The self-propelled gun 3D vision synchronous response simulation experiment platform according to claim 3, wherein a motor (24) is fixedly installed on one group of baffle plates (2), one end of the screw rod (3) is fixedly installed on a rotor shaft of the motor (24), a dust collecting block (25) is fixedly installed between the first sliding block (17) and the second sliding block (18), and one end of the dust collecting block (25) is propped against the dust removing rod (19).