CN215576383U - Interactive fire simulation display screen based on enhanced virtualization - Google Patents
Interactive fire simulation display screen based on enhanced virtualization Download PDFInfo
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- CN215576383U CN215576383U CN202121795454.4U CN202121795454U CN215576383U CN 215576383 U CN215576383 U CN 215576383U CN 202121795454 U CN202121795454 U CN 202121795454U CN 215576383 U CN215576383 U CN 215576383U
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Abstract
The utility model provides an interactive fire simulation display screen based on enhanced virtualization, which comprises a controller, a display screen and a 3d atomized flame device, wherein the display screen is connected with the controller to receive flame state parameters; the controller is connected with a human-computer interaction device for receiving user operation information; the 3d atomizing flame device is positioned in front of the display screen, and when the display screen displays a fire scene, the 3d atomizing flame device generates simulated flames; the scene content of the fire scene and the state of the simulated flames are controlled by flame state parameters generated by a controller; when a user operates the man-machine interaction device, the controller adjusts the flame state parameters according to the operation information input by the user; according to the utility model, the interaction range of the user is expanded to a real three-dimensional space from a two-dimensional plane of the display screen through the 3d atomizing flame device, so that the sense of reality of a fire simulation scene and the immersion and the taste of user interaction are improved.
Description
Technical Field
The utility model relates to the technical field of man-machine interaction, in particular to an interactive fire simulation display screen based on enhanced virtualization.
Background
The existing interactive fire simulation is mainly software simulation, various scenes such as fire occurrence, fire extinguishment, escape and the like are simulated by developing special software and combining with throwing equipment, and the interactive fire simulation is close to a real fire scene to the maximum extent, so that human-computer interaction is completed. However, the method has small interaction space and poor immersion, and cannot meet the increasing immersion interaction requirements of users.
For enlarging the interaction space of the user and improving the immersion and interaction interests of the user, the patent provides an interactive fire simulation display screen based on enhanced virtualization.
Disclosure of Invention
The interactive fire simulation display screen based on the augmented virtual is provided, the interaction range of a user is expanded to a real three-dimensional space from a two-dimensional plane of the display screen through a 3d atomizing flame device, and the sense of reality of a fire simulation scene and the sense of immersion and interest of user interaction are improved.
The utility model adopts the following technical scheme.
An interactive fire simulation display screen based on enhanced virtualization comprises a controller, a display screen and a 3d atomized flame device, wherein the display screen is connected with the controller to receive flame state parameters; the controller is connected with a human-computer interaction device for receiving user operation information; the 3d atomizing flame device is positioned in front of the display screen, and when the display screen displays a fire scene, the 3d atomizing flame device generates simulated flames; the scene content of the fire scene and the state of the simulated flames are controlled by flame state parameters generated by a controller; when a user operates the man-machine interaction device, the controller adjusts the flame state parameters according to the operation information input by the user.
And the fire scene displayed by the display screen and the simulated flame generated by the 3d atomizing flame device are combined to form a fire interaction scene displayed in a three-dimensional space.
The display screen is connected with the 3d atomizing flame device through a communication link.
The communication link between the display screen and the 3d atomizing flame device is a wireless communication link; the wireless communication link is carried and operated by a wireless communication module of the controller.
The fire scene displayed by the display screen can be switched by a user through a man-machine interaction device; the display screen is a touch display device; the man-machine interaction device comprises an interaction interface displayed by a display screen and a touch module arranged at the display screen.
The display screen and the 3d atomizing flame device are both provided with signal output interfaces and signal input interfaces which are connected with the controller to receive flame state parameters.
The flame state parameters comprise color temperature parameters, volume parameters, current parameters and wind speed parameters.
The 3d atomizing flame device comprises an LED lamp, a heating module, a sound simulation device, an atomizer and a fan; the simulated flame is formed by diffusing the light of the LED lamp in the water mist of the atomizer; the fan controls the water mist flow of the atomizer through wind power; the sound simulation device is used for playing the sound of the simulated flame;
the LED lamp switches the flame color according to the received color temperature parameter; the heating module adjusts the temperature of the water mist according to the received temperature parameters; the sound simulation device adjusts the volume according to the received volume parameter; the atomizer controls the on-off of the simulated flame according to the received current parameters; and the fan adjusts the wind speed according to the received wind speed parameter.
More than one 3d atomizing flame device is arranged in front of the display screen.
The display screen is an LED display screen, a liquid crystal display screen or a projection display device.
The utility model solves the problems of smaller interaction space and poorer immersion of a single display screen, and the interaction range of a user is expanded to a real three-dimensional space from a two-dimensional plane of the display screen through the 3d atomizing flame device, so that the reality of a fire simulation scene and the immersion and the interest of user interaction are greatly improved in a virtual enhancement mode.
Drawings
The utility model is described in further detail below with reference to the following figures and detailed description:
FIG. 1 is a schematic diagram of the overall structure of the present invention;
FIG. 2 is a schematic view of a 3d atomizing flame apparatus;
FIG. 3 is a schematic diagram of the working principle of the present invention;
in the figure: 1-a display screen; 2-a controller; 3-3d atomizing flame device; 4-LED lamps; 5-heating the module; 6-a sound simulation device; 7-an atomizer; 8-a fan; 9-simulating flames.
Detailed Description
As shown in the figure, the interactive fire simulation display screen based on the enhanced virtual comprises a controller 2 and display screens 1 and 3d atomizing flame devices 3 which are connected with the controller to receive flame state parameters; the controller is connected with a human-computer interaction device for receiving user operation information; the 3d atomizing flame device is positioned in front of the display screen, and when the display screen displays a fire scene, the 3d atomizing flame device generates simulated flames 9; the scene content of the fire scene and the state of the simulated flames are controlled by flame state parameters generated by a controller; when a user operates the man-machine interaction device, the controller adjusts the flame state parameters according to the operation information input by the user.
And the fire scene displayed by the display screen and the simulated flame generated by the 3d atomizing flame device are combined to form a fire interaction scene displayed in a three-dimensional space.
The display screen is connected with the 3d atomizing flame device through a communication link.
The communication link between the display screen and the 3d atomizing flame device is a wireless communication link; the wireless communication link is carried and operated by a wireless communication module of the controller.
The fire scene displayed by the display screen can be switched by a user through a man-machine interaction device; the display screen is a touch display device; the man-machine interaction device comprises an interaction interface displayed by a display screen and a touch module arranged at the display screen.
The display screen and the 3d atomizing flame device are both provided with signal output interfaces and signal input interfaces which are connected with the controller to receive flame state parameters.
The flame state parameters comprise color temperature parameters, volume parameters, current parameters and wind speed parameters.
The 3d atomizing flame device comprises an LED lamp 4, a heating module 5, a sound simulation device 6, an atomizer 7 and a fan 8; the simulated flame is formed by diffusing the light of the LED lamp in the water mist of the atomizer; the fan controls the water mist flow of the atomizer through wind power; the sound simulation device is used for playing the sound of the simulated flame;
the LED lamp switches the flame color according to the received color temperature parameter; the heating module adjusts the temperature of the water mist according to the received temperature parameters; the sound simulation device adjusts the volume according to the received volume parameter; the atomizer controls the on-off of the simulated flame according to the received current parameters; and the fan adjusts the wind speed according to the received wind speed parameter.
More than one 3d atomizing flame device is arranged in front of the display screen.
The display screen is an LED display screen, a liquid crystal display screen or a projection display device.
Example (b):
in this example, the display screen is used for displaying fire scene information and acquiring operation information of a user, and transmitting the information to the controller through the data line; the controller is used for receiving operation information of a user, generating flame state parameters based on the operation information and transmitting the flame state parameters to the 3d atomizing flame device through a data line; the 3d atomizing flame device is used for simulating real flames and receiving flame state parameters transmitted by the controller so as to change the flame state to complete interaction.
The specific use comprises the following steps;
step 1: switching on a power supply;
step 2: opening a display screen to load a fire scene;
and step 3: turning on the 3d atomizing flame device to finish the initialization setting of flame size, flame color, flame temperature and simulation sound;
and 4, step 4: the confirmation controller is linked to the display screen and the 3d atomizing flame device;
and 5: a user operates in front of a display screen to generate operation information;
step 6: the display screen completes the picture switching according to the operation information;
and 7: the controller receives the operation information and feeds back the new flame state parameters to the 3D atomizing flame device to control the atomizing flame state;
and 8: the user completes all the designated operations or quits the interaction, and all the elements and parameters return to the initial state.
Claims (10)
1. The utility model provides an interactive conflagration simulation display screen based on it is virtual to strengthen which characterized in that: comprises a controller, a display screen connected with the controller to receive flame state parameters, and a 3d flame atomizing device; the controller is connected with a human-computer interaction device for receiving user operation information; the 3d atomizing flame device is positioned in front of the display screen, and when the display screen displays a fire scene, the 3d atomizing flame device generates simulated flames; the scene content of the fire scene and the state of the simulated flames are controlled by flame state parameters generated by a controller; when a user operates the man-machine interaction device, the controller adjusts the flame state parameters according to the operation information input by the user.
2. The interactive fire simulation display screen based on augmented virtualization of claim 1, wherein: and the fire scene displayed by the display screen and the simulated flame generated by the 3d atomizing flame device are combined to form a fire interaction scene displayed in a three-dimensional space.
3. The interactive fire simulation display screen based on augmented virtualization of claim 1, wherein: the display screen is connected with the 3d atomizing flame device through a communication link.
4. The interactive fire simulation display screen based on augmented virtualization of claim 3, wherein: the communication link between the display screen and the 3d atomizing flame device is a wireless communication link; the wireless communication link is carried and operated by a wireless communication module of the controller.
5. The interactive fire simulation display screen based on augmented virtualization of claim 1, wherein: the fire scene displayed by the display screen can be switched by a user through a man-machine interaction device; the display screen is a touch display device; the man-machine interaction device comprises an interaction interface displayed by a display screen and a touch module arranged at the display screen.
6. The interactive fire simulation display screen based on augmented virtualization of claim 1, wherein: the display screen and the 3d atomizing flame device are both provided with signal output interfaces and signal input interfaces which are connected with the controller to receive flame state parameters.
7. The interactive fire simulation display screen based on augmented virtualization of claim 1, wherein: the flame state parameters comprise color temperature parameters, volume parameters, current parameters and wind speed parameters.
8. The interactive fire simulation display screen based on augmented virtualization of claim 7, wherein: the 3d atomizing flame device comprises an LED lamp, a heating module, a sound simulation device, an atomizer and a fan; the simulated flame is formed by diffusing the light of the LED lamp in the water mist of the atomizer; the fan controls the water mist flow of the atomizer through wind power; the sound simulation device is used for playing the sound of the simulated flame;
the LED lamp switches the flame color according to the received color temperature parameter; the heating module adjusts the temperature of the water mist according to the received temperature parameters; the sound simulation device adjusts the volume according to the received volume parameter; the atomizer controls the on-off of the simulated flame according to the received current parameters; and the fan adjusts the wind speed according to the received wind speed parameter.
9. The interactive fire simulation display screen based on augmented virtualization of claim 1, wherein: more than one 3d atomizing flame device is arranged in front of the display screen.
10. The interactive fire simulation display screen based on augmented virtualization of claim 1, wherein: the display screen is an LED display screen, a liquid crystal display screen or a projection display device.
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CN202121795454.4U CN215576383U (en) | 2021-08-03 | 2021-08-03 | Interactive fire simulation display screen based on enhanced virtualization |
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CN202121795454.4U CN215576383U (en) | 2021-08-03 | 2021-08-03 | Interactive fire simulation display screen based on enhanced virtualization |
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2021
- 2021-08-03 CN CN202121795454.4U patent/CN215576383U/en active Active
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