CN219676775U

CN219676775U - Virtual shock sensation simulation device

Info

Publication number: CN219676775U
Application number: CN202320859167.8U
Authority: CN
Inventors: 刘畅; 路玉鹏; 高海丽
Original assignee: Beijing Zhongke Zhimao Technology Co ltd
Current assignee: Beijing Zhongke Zhimao Technology Co ltd
Priority date: 2023-04-18
Filing date: 2023-04-18
Publication date: 2023-09-12
Anticipated expiration: 2033-04-18

Abstract

The utility model belongs to the technical field of virtual vibration simulation, and particularly relates to a virtual vibration simulation device which comprises a supporting bottom plate, wherein fixing blocks are connected to four right angles of the supporting bottom plate, a bearing plate is arranged above the fixing blocks, mounting blocks are arranged at bottoms of left and right ends of the bearing plate, fixing columns are connected to front and rear ends of the mounting blocks, a limiting cross rod is fixed between the two mounting blocks, a positioning movable assembly is arranged on the outer side of the middle of the limiting cross rod, and a vibration control assembly is arranged behind the bottom of the positioning movable assembly. According to the utility model, the connecting disc is controlled to rotate rapidly by starting the driving motor, the mounting rod with the horizontal guide groove arranged at the bottom can be extruded through the connecting column eccentrically fixed at the front end of the connecting disc, so that the mounting rod and the connecting sleeve are subjected to rapid reciprocating small-amplitude upgrading along the limiting column, and at the moment, the limiting cross rod can be driven through the connecting sleeve, so that the bearing plate is driven to perform rapid reciprocating vibration, and the vibration sense simulation is performed.

Description

Virtual shock sensation simulation device

Technical Field

The utility model belongs to the technical field of virtual shock simulation, and particularly relates to a virtual shock simulation device.

Background

VR generally refers to virtual reality, which is also called virtual reality or smart technology, and is a new technology that has been developed newly, through which users have the feeling of being personally on the scene, and bring a new and rich visual feast to people, and VR glasses are common, so that with the continuous development of virtual reality, people are no longer satisfied with the richness of vision, and therefore, the virtual reality technology is continuously perfected.

In the virtual process of earthquake and the like, the user experience is brought to the defect that the user cannot feel the horror of the earthquake only by vision, so that a virtual earthquake sensation simulation device is researched and developed, the earthquake sensation is restored by a simulation means, the experience effect is more perfect, the conventional virtual earthquake sensation simulation device on the market at present is complex in structure, the production and purchase cost of the device is high, the vibration direction is single, and the multidirectional earthquake sensation during the earthquake cannot be fully simulated. Therefore, there is an urgent need to improve the existing virtual shock simulation apparatus and provide a virtual shock simulation apparatus.

Disclosure of Invention

Aiming at the defects existing in the prior art, the utility model provides the virtual vibration sense simulation device which is reasonable in design, simple in structure, multi-directional in vibration sense and more realistic in simulation, and is used for solving the problems that the structure is complex, the production and purchase cost of the device is high, the vibration direction is single, the multi-directional vibration sense during earthquake cannot be fully simulated, and the like in the prior art.

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

the utility model provides a virtual jolt sensation analogue means, its includes supporting baseplate, four right angles departments of supporting baseplate all are connected with the fixed block, and the top of fixed block is provided with the loading board, both ends bottom all is provided with the installation piece about the loading board, and both ends all are connected with the fixed column around the installation piece, two be fixed with spacing horizontal pole between the installation piece, the location movable subassembly is installed in the middle part outside of spacing horizontal pole, and the bottom rear of location movable subassembly is provided with vibration control subassembly.

As a preferred implementation mode, the supporting bottom plate is fixedly connected with the four fixing blocks in a welding mode, and the four fixing blocks are internally provided with inclined guide grooves in the same direction.

As a preferred implementation mode, the connection mode of loading board and two the installation piece is the welding, two both sides all welded mounting has the fixed column around the installation piece, the fixed column deviates from the one end of installation piece and extends to in the slope guide way that the fixed block inside was seted up.

As a preferable implementation mode, the left end and the right end of the limiting cross rod are respectively welded and connected to one side, close to each other, of the two mounting blocks, and the two mounting blocks are symmetrically arranged on the left side and the right side of the central axis of the bearing plate.

As a preferred implementation mode, the positioning movable assembly comprises a connecting sleeve, a mounting rod and limiting columns, wherein the bottom of the connecting sleeve is fixedly connected with the mounting rod, and the two limiting columns are respectively installed at the left end and the right end of the bottom of the mounting rod in a penetrating mode.

As a preferred implementation mode, the adapter sleeve sliding connection is in the outside of spacing horizontal pole, and the longitudinal section of installation pole is the shape of falling "T", and the inside horizontal guiding groove that has seted up of bottom of installation pole, installation pole and two spacing post are sliding connection, two the bottom of spacing post all welds with supporting baseplate.

As a preferred implementation mode, the vibration control assembly comprises a driving motor, a connecting disc and a connecting column, wherein the driving motor is fixedly arranged at the upper end of the middle part of a supporting bottom plate, the connecting disc is fixedly arranged at the output end of the driving motor, the connecting column is welded at the eccentric position of the front end of the connecting disc, and the front end of the connecting column extends into a horizontal guide groove inside the bottom end of the mounting rod.

Compared with the prior art, the utility model has the beneficial effects that:

in the scheme of the utility model:

the connecting disc is controlled to rotate rapidly by starting the driving motor, the mounting rod with the horizontal guide groove arranged at the bottom can be extruded through the connecting column eccentrically fixed at the front end of the connecting disc, so that the mounting rod and the connecting sleeve are subjected to rapid reciprocating type small-amplitude upgrading along the limiting column, and at the moment, the limiting cross rod can be driven through the connecting sleeve, so that the bearing plate is driven to perform rapid reciprocating vibration, and vibration sense simulation is performed;

when the bearing plate is lifted and vibrated by a small margin, because the limiting cross rod is connected with the connecting sleeve in a sliding way, when the bearing plate, the mounting block and the fixed column are lifted and lowered, the bearing plate, the mounting block and the fixed column can be lifted and vibrated by the inclined guide groove inside the fixed block, and simultaneously can shake left and right, so that multidirectional vibration can be realized, vibration simulation is more lifelike, the structure is simple, and the manufacturing cost of the simulation device is low.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the following description will briefly explain the drawings used in the embodiments or the description of the prior art, and the following description will be made with reference to the drawings:

FIG. 1 is a schematic diagram of a three-dimensional front view structure of the present utility model;

FIG. 2 is a schematic diagram of a vibration state structure according to the present utility model;

FIG. 3 is a schematic diagram of a top view of the connection between the support base and the fixed block according to the present utility model;

FIG. 4 is a schematic view showing the bottom view of the connection between the carrier plate and the mounting block according to the present utility model;

FIG. 5 is a schematic view of the bottom view of the positioning movable assembly of the present utility model;

fig. 6 is a schematic left-view structure of the vibration control assembly of the present utility model.

In the figure:

1. a support base plate; 2. a fixed block; 3. a carrying plate; 4. a mounting block; 5. fixing the column; 6. a limiting cross bar; 7. positioning the movable assembly; 71. connecting sleeves; 72. a mounting rod; 73. a limit column; 8. a vibration control assembly; 81. a driving motor; 82. a connecting disc; 83. and (5) connecting the columns.

Detailed Description

The embodiments described below are only some of the embodiments of the present utility model and do not represent all embodiments consistent with the present utility model. Exemplary embodiments will now be described with reference to the accompanying drawings in which:

as shown in fig. 1-6, the virtual vibration simulation device comprises a supporting bottom plate 1, wherein four right angles of the supporting bottom plate 1 are respectively connected with a fixed block 2, through the arrangement of the fixed blocks 2, a bearing plate 3 can have a multidirectional vibration simulation function, a bearing plate 3 is arranged above the fixed blocks 2, mounting blocks 4 are respectively arranged at the bottoms of the left end and the right end of the bearing plate 3, fixing columns 5 are respectively connected at the front end and the rear end of each mounting block 4, the bearing plate 3 is conveniently guided to vibrate by utilizing the fixing columns 5 positioned at the front end and the rear end of each mounting block 4, a limiting cross rod 6 is fixed between the two mounting blocks 4, a positioning movable assembly 7 is arranged at the outer side of the middle of the limiting cross rod 6, vibration of the bearing plate 3 can be controlled under the action of the positioning movable assembly 7, vibration simulation is started, a vibration control assembly 8 is arranged at the rear of the bottom of the positioning movable assembly 7, and the operation and the closing of the simulation device can be controlled under the action of the vibration control assembly 8.

As a preferred embodiment, on the basis of the above structure, further, the supporting base plate 1 and the four fixing blocks 2 are fixedly connected by welding, the inside of the four fixing blocks 2 is provided with the same-direction inclined guide grooves, and the supporting plate 3 can be slightly rocked left and right while being lifted by the inclined guide grooves in the fixing blocks 2.

As a preferred embodiment, on the basis of the above structure, further, the connection mode of the bearing plate 3 and the two installation blocks 4 is welding, the fixing columns 5 are welded and installed on the front side and the rear side of the two installation blocks 4, one ends of the fixing columns 5, which deviate from the installation blocks 4, extend into the inclined guide grooves formed in the fixing blocks 2, and through the arrangement of the fixing columns 5, the bearing plate 3, the installation blocks 4 and the fixing columns 5 can shake left and right under the guidance of the inclined guide grooves in the fixing blocks 2 when being lifted.

As a preferred embodiment, on the basis of the above structure, further, the left and right ends of the limit cross bar 6 are respectively welded and connected to one sides of the two mounting blocks 4, which are close to each other, the two mounting blocks 4 are symmetrically arranged about the central axis of the bearing plate 3, and the setting of the limit cross bar 6 is utilized to facilitate the shaking of the bearing plate 3 without being affected, so as to avoid the locking of the device structure.

As a preferred embodiment, on the basis of the above structure, the positioning movable assembly 7 further includes a connecting sleeve 71, a mounting rod 72 and a limiting post 73, the bottom of the connecting sleeve 71 is fixedly connected with the mounting rod 72, the two limiting posts 73 are respectively installed at the left and right ends of the bottom of the mounting rod 72 in a penetrating manner, and through the setting of the positioning movable assembly 7, the carrier plate 3 is conveniently driven to perform reciprocating lifting vibration, and virtual vibration sense simulation is started.

As a preferred embodiment, on the basis of the above structure, the connecting sleeve 71 is further slidably connected to the outer side of the limiting cross rod 6, the longitudinal section of the mounting rod 72 is in an inverted T shape, the bottom end of the mounting rod 72 is internally provided with a horizontal guiding groove, the mounting rod 72 is slidably connected with the two limiting posts 73, the bottoms of the two limiting posts 73 are welded with the supporting base plate 1, and the lifting stability of the mounting rod 72 and the connecting sleeve 71 can be improved under the action of the left and right limiting posts 73 slidably connected with the mounting rod 72.

As a preferred embodiment, on the basis of the above structure, the vibration control assembly 8 further includes a driving motor 81, a connecting disc 82 and a connecting post 83, the driving motor 81 is fixedly mounted at the upper end of the middle portion of the supporting base plate 1, the connecting disc 82 is fixedly arranged at the output end of the driving motor 81, the connecting post 83 is welded at the eccentric position of the front end of the connecting disc 82, the front end of the connecting post 83 extends into the horizontal guiding groove inside the bottom end of the mounting rod 72, and under the action of the vibration control assembly 8, the virtual vibration sensing simulation device can be controlled to be started or closed.

The working principle of the utility model is as follows:

when the vibration simulation device is used, firstly, an experimenter stands or sits on the bearing plate 3, and takes protective measures for the experimenter by utilizing the prior means, after the preparation is complete, the driving motor 81 at the upper end of the supporting bottom plate 1 is started, the connecting disc 82 is controlled to drive the connecting post 83 eccentrically fixed at the front end of the connecting post to rotate quickly, the mounting rod 72 with the horizontal guide groove at the bottom can be extruded when the connecting post 83 rotates, the mounting rod 72 and the connecting sleeve 71 can be rapidly and reciprocally lifted and lowered along the limiting post 73, and the limiting cross rod 6, the mounting block 4 and the bearing plate 3 can be pushed to follow the synchronous small lifting and lowering, so that vibration simulation is started;

in the lifting process of the bearing plate 3, the connecting sleeve 71 is connected with the limiting cross rod 6 in a sliding manner, so that the fixing column 5 can move along the direction of the inclined guide groove inside the fixing block 2 in the synchronous and rapid lifting process of the bearing plate 3, the mounting block 4 and the bearing plate 3 are driven to vibrate in a lifting manner, the multidirectional vibration simulation can be realized, the virtual vibration simulation is more realistic, and the simulation device is simple in structure, low in manufacturing cost and beneficial to popularization and use.

The above is only a preferred embodiment of the present utility model, and is not intended to limit the scope of the present utility model; all equivalent changes, modifications, substitutions and variations on the prior art by logic analysis, reasoning or limited experiments by those skilled in the art, based on the present inventive concept, shall be made within the scope of protection as defined by the claims.

Claims

1. The utility model provides a virtual shock sensation analogue means, includes supporting baseplate (1), its characterized in that: four right angle departments of supporting baseplate (1) all are connected with fixed block (2), and the top of fixed block (2) is provided with loading board (3), both ends bottom all is provided with installation piece (4) about loading board (3), and both ends all are connected with fixed column (5) around installation piece (4), two be fixed with spacing horizontal pole (6) between installation piece (4), location movable subassembly (7) are installed in the middle part outside of spacing horizontal pole (6), and the bottom rear of location movable subassembly (7) is provided with vibrations control assembly (8).

2. The virtual vibration simulation apparatus according to claim 1, wherein: the supporting bottom plate (1) is fixedly connected with the four fixed blocks (2) in a welding mode, and the four fixed blocks (2) are internally provided with inclined guide grooves in the same direction.

3. The virtual vibration simulation apparatus according to claim 1, wherein: the bearing plate (3) is welded with two mounting blocks (4) in a connecting mode, fixing columns (5) are welded and mounted on the front side and the rear side of each mounting block (4), and one end, deviating from each mounting block (4), of each fixing column (5) extends into an inclined guide groove formed in each fixing block (2).

4. The virtual vibration simulation apparatus according to claim 1, wherein: the left end and the right end of the limiting cross rod (6) are respectively welded and connected to one sides of the two mounting blocks (4) which are close to each other, and the two mounting blocks (4) are symmetrically arranged left and right relative to the central axis of the bearing plate (3).

5. The virtual vibration simulation apparatus according to claim 1, wherein: the positioning movable assembly (7) comprises a connecting sleeve (71), a mounting rod (72) and limiting columns (73), wherein the bottom of the connecting sleeve (71) is fixedly connected with the mounting rod (72), and the two limiting columns (73) are respectively arranged at the left end and the right end of the bottom of the mounting rod (72) in a penetrating mode.

6. The virtual vibration simulation apparatus according to claim 5, wherein: the connecting sleeve (71) is slidably connected to the outer side of the limiting cross rod (6), the longitudinal section of the mounting rod (72) is in an inverted T shape, a horizontal guide groove is formed in the bottom end of the mounting rod (72), the mounting rod (72) is slidably connected with the two limiting columns (73), and the bottoms of the two limiting columns (73) are welded with the supporting bottom plate (1).

7. The virtual vibration simulation apparatus according to claim 1, wherein: the vibration control assembly (8) comprises a driving motor (81), a connecting disc (82) and a connecting column (83), wherein the driving motor (81) is fixedly installed at the upper end of the middle of the supporting base plate (1), the connecting disc (82) is fixedly arranged at the output end of the driving motor (81), the connecting column (83) is welded at the eccentric position of the front end of the connecting disc (82), and the front end of the connecting column (83) extends into the horizontal guide groove inside the bottom end of the mounting rod (72).