CN219891633U - Virtual-real fusion scene system - Google Patents

Abstract

The utility model provides a virtual-real fusion scene system, which comprises: the server side is used for acquiring the virtual reality image data and generating an instruction set according to the virtual reality image data; the clients are electrically connected or network connected with the server and comprise display screens, atmosphere lamps, loudspeakers and odor generators; the atmosphere lamp is used for adjusting the brightness or the color of the lamplight according to the lamplight regulating instruction; the loudspeaker is used for playing audio according to the sound effect regulation and control instruction; the display screen is used for outputting the rendered virtual reality image data; the display screen is provided with a heat dissipation part for cooling the display screen; the odor generator is used for releasing a volatilized odor source according to the odor regulation and control instruction; an odor source is arranged in the odor generator and is contacted with the heat dissipation part; when the display screen works, the heat radiating part guides heat to the odor source, and the odor source is heated and volatilized. The system is used for automatically setting instructions for controlling the client, and simultaneously saving energy required for heating the odor source.

Description

Virtual-real fusion scene system

Technical Field

The utility model relates to the technical field of virtual reality, in particular to a virtual-real fusion scene system.

Background

The virtual reality technology comprises a computer, electronic information and simulation technology, and the basic implementation mode is to integrate three-dimensional graphic technology, multimedia technology, simulation technology, display technology and servo technology, and generate a realistic virtual world with various sensory experiences such as three-dimensional vision, touch sense, smell sense and the like by means of equipment such as the computer, so that a user in the virtual world generates an immersive sense.

Currently, in the technical field of virtual reality, in order to enable a user to obtain olfactory experience in the virtual world, solid or liquid odor sources need to be heated in advance to volatilize the odor sources, different odor sources can bring different olfactory experiences to the user, but a large amount of energy sources can be wasted when a large amount of odor sources are heated. In addition, when the virtual reality scene is initialized, a large number of instructions are required to be set manually to control the client to simulate the real scene, which is time-consuming and labor-consuming and is not beneficial to reducing the application cost. Therefore, a new virtual-real fusion scene system is needed to improve the above problems.

Disclosure of Invention

The utility model aims to provide a virtual-real fusion scene system which is used for automatically setting instructions for controlling a client and saving energy required for heating an odor source.

In a first aspect, the present utility model provides a virtual-real fusion scene display system, including: the server side is used for acquiring virtual reality image data and generating an instruction set matched with the virtual reality image data according to the virtual reality image data; the instruction set comprises a light regulation instruction, an audio regulation instruction and an odor regulation instruction, and is used for controlling a plurality of clients; the clients are electrically connected or network connected with the server, and the clients comprise a display screen, an atmosphere lamp, a loudspeaker and an odor generator; the atmosphere lamp is used for adjusting the brightness or the color of the lamplight according to the lamplight regulation and control instruction; the loudspeaker is used for playing audio according to the sound effect regulation and control instruction; the display screen is used for outputting the rendered virtual reality image data; the display screen is provided with a heat dissipation part for cooling the display screen; the odor generator is used for releasing a volatilized odor source according to the odor regulation and control instruction; an odor source is arranged in the odor generator and is in contact with the heat dissipation part; when the display screen works, the heat dissipation part guides heat to the odor source, and the odor source is heated and volatilized.

The method has the beneficial effects that: according to the utility model, the heat is guided to the odor source through the heat dissipation part of the display screen, so that the odor source is heated and volatilized, and the heat dissipation of the display screen is facilitated, and meanwhile, the energy required for heating the odor source is saved. The utility model can simulate the visual sense, the hearing sense, the touch sense and the olfactory sense of the user in the real environment, so that the user obtains complete immersion sense, and the utility model is beneficial to improving the user experience. According to the utility model, the client is controlled to simulate a real scene without manually setting instructions, so that time and labor are saved, and the application cost is reduced.

Optionally, the odor generator comprises a housing and a gas valve; the odor source is positioned in the shell, and the shell is connected with the air valve; the housing is isolated from the atmosphere when the air valve is in a closed state and is in communication with the atmosphere when the air valve is in an open state.

Optionally, when the odor source is a liquid odor source, the odor generator further comprises a piston, a breathable film and an elastic element; the piston is connected in the shell in a sliding way, and the piston is connected with the ventilation membrane; the ventilation film, the heat dissipation part and the shell are used for jointly forming a cavity for accommodating the liquid odor source, and the piston is provided with a through hole for enabling the volatilized odor source to escape from the shell; the elastic piece is connected with the piston and is used for pushing the piston and the breathable film to the heat dissipation part so that the liquid odor source is always in contact with the heat dissipation part.

Optionally, a temperature detector and a heater are also arranged in the odor generator; the temperature detector is used for acquiring the temperature value of the heat dissipation part; the heater is configured to heat the scent source when the temperature value is less than a first threshold value.

Optionally, the system further comprises an air conditioner; the air conditioner is used for controlling at least one of wind power, air humidity and air temperature blown to a user according to the air regulation and control instruction generated by the service end.

Optionally, before generating the instruction set, the server is further configured to obtain an interaction parameter of the user; the interaction parameters comprise image parameters, lamplight parameters, volume parameters and smell parameters; the image parameters are parameters which are adjusted when the virtual reality image data are rendered, and the lamplight parameters are used for determining a threshold value of lamplight brightness; the volume parameter is used for determining a volume threshold value when the audio is played; the odor parameter is used to determine whether to release the odor source.

Optionally, the server is further configured to generate a plurality of instruction sets matched with the virtual reality image data according to the virtual reality image data; ordering the instruction sets according to the interaction parameters to wait for a selection result; and determining an instruction set for controlling the client according to the selection result.

Optionally, the system further includes an operation end, configured to render and generate the virtual reality image data according to at least one of real video data, real photo data, or virtual scene model data.

Optionally, the number of the display screen, the atmosphere lamp, the loudspeaker and the odor generator is at least 2, and the number of the service terminals is at least 1.

In a second aspect, the present utility model provides a virtual-real fusion scene display method, which is used in the system of any one of the first aspects, and includes: obtaining virtual reality image data, and generating an instruction set matched with the virtual reality image data according to the virtual reality image data; the instruction set comprises a light regulation instruction, an audio regulation instruction and an odor regulation instruction, and is used for controlling a plurality of clients; the atmosphere lamp adjusts the brightness or color of the lamp according to the lamp adjusting instruction; the loudspeaker plays audio according to the sound effect regulation instruction; the display screen outputs the rendered virtual reality image data; the odor generator releases an odor source according to the odor control instruction.

Drawings

Fig. 1 is a schematic structural diagram of a virtual-real fusion scene display system provided by the utility model;

FIG. 2 is a schematic diagram of a solid-state odor source provided by the present utility model;

FIG. 3 is a schematic diagram of an odor generator with a liquid odor source according to the present utility model;

fig. 4 is a schematic structural diagram of a virtual-real fusion scene display system provided with N display screens according to the present utility model;

fig. 5 is a flow chart of a virtual-real fusion scene display method provided by the utility model.

Reference numerals in the drawings:

11. a server; 12. a client; 13. an operation end; 2. an atmosphere lamp; 3. a loudspeaker; 4. a display screen; 41. a heat dissipation part; 5. an odor generator; 51. an odor source; 52. an air valve; 53. a temperature measurer; 54. a heater; 55. a piston; 56. a breathable film; 57. an elastic member; 58. a housing; 59. a through hole; 6. an air conditioner.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the present utility model more apparent, the technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model. Unless otherwise defined, technical or scientific terms used herein should be given the ordinary meaning as understood by one of ordinary skill in the art to which this utility model belongs. As used herein, the word "comprising" and the like means that elements or items preceding the word are included in the element or item listed after the word and equivalents thereof without precluding other elements or items.

Aiming at the problems existing in the prior art, as shown in fig. 1, the utility model provides a virtual-real fusion scene system, which comprises a server 11 and five clients 12; the five clients 12 are respectively a display screen 4, an atmosphere lamp 2, a loudspeaker, an odor generator 5 and an air conditioner 6, and are all electrically connected with the server 11. The server 11 is configured to obtain virtual reality image data, and generate an instruction set matched with the virtual reality image data according to the virtual reality image data; the instruction group comprises a lamplight regulation instruction, an audio effect regulation instruction, an odor regulation instruction and an air regulation instruction. It should be noted that the number of clients 12 may be any positive integer.

Specifically, the server 11 is connected to an operation end 13 through a network, and is configured to render and generate the virtual reality image data according to at least one data in the virtual scene model data. It should be noted that, the operation end 13 may generate the virtual reality image data according to the real video data or the real photo data, or the operation end 13 may also generate the virtual reality image data according to the superposition rendering of the real video data and the virtual scene model data.

In other specific embodiments, the air conditioner 6 is configured as a central air conditioner, and the air conditioning command is used to control the wind power blown by the central air conditioner to the user. It should be noted that the air conditioner 6 may also be configured as a portable air conditioning fan, and the air conditioning command is also used to control the air humidity or the air temperature.

In still other specific embodiments, the atmosphere lamp 2 is configured as a variable color flash, and the light regulation instruction is used for controlling the brightness, the color and the flashing frequency of the variable color flash when in operation. It should be noted that the atmosphere lamp 2 may also be provided as a fluorescent lamp or a laser lamp.

In still other specific embodiments, the speaker is configured as a moving coil speaker, and the sound effect control instruction is configured to control the moving coil speaker to play audio. The speaker can be also be configured as a moving iron speaker, a moving magnetic speaker, an electrostatic speaker and an exciter.

In still other specific embodiments, the display screen 4 is configured as a light-emitting diode (LED) display screen. It is to be noted that the display screen 4 may also be provided as a liquid crystal display (Liquid Crystal Display, LCD).

As shown in fig. 2, the display screen 4 is provided with a heat radiating portion 41 for cooling the display screen 4; the odor generator 5 is configured to release a volatilized odor source 51 according to the odor control instruction; an odor source 51 is arranged in the odor generator 5, and the odor source 51 is in contact with the heat dissipation part 41; when the display screen 4 is in operation, the heat dissipation part 41 directs heat to the odor source 51, and the odor source 51 is volatilized by heat. The scent generator 5 comprises a housing 58 and an air valve 52; the scent source 51 is located within the housing 58, the housing 58 being connected to the gas valve 52; the housing 58 is isolated from the atmosphere when the gas valve 52 is in the closed state, and the housing 58 is in communication with the atmosphere when the gas valve 52 is in the open state.

Specifically, the odor source 51 is a solid odor source 51, and the heat dissipation portion 41 is fixedly connected to a top end of the solid odor source 51; the solid odor source 51 is heated to volatilize, filling the space in the housing 58, and when the air valve 52 is opened, the volatilized odor source 51 escapes from the housing 58 so that the user can smell the odor source 51. When the gas valve 52 is opened, the volatilized source of odor 51 remains within the housing 58.

In other specific embodiments, the odor generator 5 is further provided with a temperature detector 53 and a heater 54; the temperature detector 53 is used for acquiring a temperature value of the heat dissipation part 41; the heater 54 is used to heat the scent source 51 when the temperature value is less than a first threshold value. The first threshold is the lowest temperature value at which odor source 51 volatilizes.

In still other embodiments, as shown in fig. 3, when the scent source 51 is a liquid scent source 51, the scent generator 5 further includes a piston 55, a gas permeable membrane 56, and an elastic member 57; the piston 55 is slidably connected in the housing 58, and the top end of the piston 55 is connected with the ventilation membrane 56; the air-permeable membrane 56, the heat dissipation part 41 and the housing 58 are used for jointly forming a cavity for accommodating the liquid odor source 51, and the piston 55 is provided with a through hole 59 for enabling the volatilized odor source 51 to escape from the housing 58; the top end of the elastic member 57 is connected to the bottom end of the piston 55 for pushing the piston 55 and the air permeable membrane 56 toward the heat dissipating part 41 so that the liquid odor source 51 is always in contact with the heat dissipating part 41. The bottom end of the elastic member 57 is connected to the inside bottom end of the housing 58. Illustratively, the elastic member 57 is a spring or a leaf spring. The air permeable membrane 56 may also be disposed within the through hole 59 or the bottom end of the piston 55.

It should be noted that, before generating the instruction set, the server 11 is further configured to obtain an interaction parameter of a user; the interaction parameters comprise image parameters, lamplight parameters, volume parameters and smell parameters; the image parameters are parameters which are adjusted when the virtual reality image data are rendered, and the lamplight parameters are used for determining a threshold value of lamplight brightness; the volume parameter is used for determining a volume threshold value when the audio is played; the scent parameter is used to determine whether to release the scent source 51.

Illustratively, the image parameter is a brightness parameter. The image parameter may be at least one of color system parameter, exposure parameter, transparency parameter, and style parameter. The virtual reality image data generated during rendering is beneficial to meeting the user requirements.

In other examples, the light parameter is used to determine a maximum threshold for light intensity; this example can avoid light luminance too big to cause the user uncomfortable. The lamplight parameter is used for determining a minimum threshold value of the lamplight brightness; this example can avoid that the lamp brightness is too little to cause user experience bad.

In still other examples, the volume parameter is used to determine a maximum threshold for volume; this example can avoid the volume from being too loud to cause user discomfort. The volume parameter is used for determining a minimum threshold value of the volume; this example can avoid volume that is too low resulting in poor user experience.

In still other examples, the scent parameter is used to determine release of the scent source 51; this example can avoid the user experience being poor due to insufficient release of scent source 51. The scent parameter is used to determine to stop releasing the scent source 51; this example can avoid odor source 51 causing discomfort to the user.

In other embodiments, the server 11 is further configured to generate, according to the virtual reality image data, a plurality of instruction sets matched with the virtual reality image data; ordering the instruction sets according to the interaction parameters to wait for a selection result; a set of instructions for controlling the client 12 is determined based on the selection result.

Illustratively, ordering the plurality of instruction sets according to the interaction parameter includes: and ordering the instruction groups from large to small according to the instruction quantity meeting the interaction parameters in each instruction group, so that the instruction groups meeting all the interaction parameters are ordered to the forefront of the instruction groups, the selection of a user is facilitated, and the user experience is improved.

In still other embodiments, as shown in fig. 4, the number of the display screen 4, the atmosphere lamp 2, the speaker and the odor generator 5 is N, N is any positive integer greater than 1, and the number of the service terminals 11 is 1. The number of air conditioners 6 is 1. In still other embodiments, the number of the service terminals 11 and the air conditioners 6 may be any positive integer. It is worth noting that the display 4, the atmosphere lamp 2, the speaker and the scent generator 5 may be integrated into one client 12 or provided separately.

As shown in fig. 5, this embodiment further provides a virtual-real fusion scene display method, which is used in the system described in any one of the foregoing embodiments, and includes: s1, obtaining virtual reality image data, and generating an instruction set matched with the virtual reality image data according to the virtual reality image data; the instruction set comprises a light regulation instruction, an audio regulation instruction and an odor regulation instruction, and is used for controlling a plurality of clients; s2, the atmosphere lamp adjusts the brightness or the color of the lamp according to the lamp light adjusting and controlling instruction; s3, the loudspeaker plays the audio according to the sound effect regulation instruction; s4, outputting the rendered virtual reality image data by the display screen; s5, the odor generator releases the odor source according to the odor regulation and control instruction.

While embodiments of the present utility model have been described in detail hereinabove, it will be apparent to those skilled in the art that various modifications and variations can be made to these embodiments. It is to be understood that such modifications and variations are within the scope and spirit of the present utility model as set forth in the following claims. Moreover, the utility model described herein is capable of other embodiments and of being practiced or of being carried out in various ways.

Claims (9)

1. A virtual-real fusion scene display system, comprising:

the server side is used for acquiring virtual reality image data and generating an instruction set matched with the virtual reality image data according to the virtual reality image data; the instruction set comprises a light regulation instruction, an audio regulation instruction and an odor regulation instruction, and is used for controlling a plurality of clients;

the clients are electrically connected or network connected with the server, and the clients comprise a display screen, an atmosphere lamp, a loudspeaker and an odor generator; the atmosphere lamp is used for adjusting the brightness or the color of the lamplight according to the lamplight regulation and control instruction; the loudspeaker is used for playing audio according to the sound effect regulation and control instruction; the display screen is used for outputting the rendered virtual reality image data; the display screen is provided with a heat dissipation part for cooling the display screen; the odor generator is used for releasing a volatilized odor source according to the odor regulation and control instruction; an odor source is arranged in the odor generator and is in contact with the heat dissipation part; when the display screen works, the heat dissipation part guides heat to the odor source, and the odor source is heated and volatilized.

2. The system of claim 1, wherein the scent generator comprises a housing and a gas valve;

the odor source is positioned in the shell, and the shell is connected with the air valve;

the housing is isolated from the atmosphere when the air valve is in a closed state and is in communication with the atmosphere when the air valve is in an open state.

3. The system of claim 2, wherein when the scent source is a liquid scent source, the scent generator further comprises a piston, a gas permeable membrane, and an elastic member therein; the piston is connected in the shell in a sliding way, and the piston is connected with the ventilation membrane; the ventilation film, the heat dissipation part and the shell are used for jointly forming a cavity for accommodating the liquid odor source, and the piston is provided with a through hole for enabling the volatilized odor source to escape from the shell; the elastic piece is connected with the piston and is used for pushing the piston and the breathable film to the heat dissipation part so that the liquid odor source is always in contact with the heat dissipation part.

4. A system according to claim 2 or 3, wherein a temperature detector and a heater are also provided in the scent generator;

the temperature detector is used for acquiring the temperature value of the heat dissipation part;

the heater is configured to heat the scent source when the temperature value is less than a first threshold value.

5. The system of claim 1 or 2, wherein the system further comprises an air conditioner;

the air conditioner is used for controlling at least one of wind power, air humidity and air temperature blown to a user according to the air regulation and control instruction generated by the service end.

6. The system of claim 1, wherein the server is further configured to obtain interaction parameters of a user before generating the instruction set; the interaction parameters comprise image parameters, lamplight parameters, volume parameters and smell parameters;

the image parameters are parameters adjusted when rendering the virtual reality image data,

the lamplight parameters are used for determining a threshold value of lamplight brightness;

the volume parameter is used for determining a volume threshold value when the audio is played;

the odor parameter is used to determine whether to release the odor source.

7. The system of claim 6, wherein the server is further configured to generate a plurality of instruction sets matching the virtual reality image data from the virtual reality image data; ordering the instruction sets according to the interaction parameters to wait for a selection result; and determining an instruction set for controlling the client according to the selection result.

8. The system of claim 1, further comprising an operation terminal for rendering the virtual reality image data based on at least one of real video data, real photo data, or virtual scene model data.

9. The system of claim 1, wherein the number of display screens, atmosphere lights, speakers, and odor generators is at least 2 and the number of service terminals is at least 1.