阅读说明：本技术 模拟翼装飞行极限运动的展项装置 (Item unfolding device for simulating wing-mounted flight extreme motion ) 是由 曾子光 石宏伟 于 2021-01-26 设计创作，主要内容包括：本发明公开了一种模拟翼装飞行极限运动的展项装置,本装置的模拟滑翔机构包括滑翔翼模型、万向节、支架、握杆和九轴传感器,万向节设于滑翔翼模型顶面,支架连接万向节并使滑翔翼模型架设于显示屏前方,握杆设于滑翔翼模型底面,九轴传感器内嵌于滑翔翼模型,九轴传感器、显示屏和音频播放设备与多媒体工作站通讯连接,握杆带动滑翔翼模型以万向节为支点运动后,九轴传感器输出信号传输至多媒体工作站,多媒体工作站根据九轴传感器输出信号控制显示屏播放相应的画面,同时控制音频播放设备播放相应的音频。本展项装置通过虚拟现实技术与飞行设备的结合,使体验者感受到翼装飞行的乐趣,避免安全隐患,增强展项的趣味性和竞争力。(The invention discloses an item unfolding device for simulating wing-mounted flight limit movement, wherein a simulated gliding mechanism of the device comprises a gliding wing model, a universal joint, a support, a holding rod and a nine-axis sensor, the universal joint is arranged on the top surface of the gliding wing model, the support is connected with the universal joint and enables the gliding wing model to be erected in front of a display screen, the holding rod is arranged on the bottom surface of the gliding wing model, the nine-axis sensor is embedded in the gliding wing model, the nine-axis sensor, the display screen and audio playing equipment are in communication connection with a multimedia workstation, after the holding rod drives the gliding wing model to move by taking the universal joint as a fulcrum, the nine-axis sensor outputs signals to be transmitted to the multimedia workstation, and the multimedia workstation controls the display screen to play corresponding pictures according to the nine-axis sensor output signals and controls the audio playing equipment to play corresponding audio. This exhibition item device passes through the combination of virtual reality technique and flight equipment, makes experience person experience the enjoyment that the wing dress flies, avoids the potential safety hazard, strengthens the interest and the competitiveness of exhibition item.)

1. The utility model provides a simulation wing dress flight limit motion's exhibition item device which characterized in that: the exhibition device comprises a display screen, a multimedia workstation, a simulated gliding mechanism and an audio playing device, wherein the simulated gliding mechanism comprises a gliding wing model, a universal joint, a support, a holding rod and a nine-axis sensor, the universal joint is arranged on the top surface of the gliding wing model, the support is connected with the universal joint and enables the gliding wing model to be erected in front of the display screen, the holding rod is arranged on the bottom surface of the gliding wing model, the nine-axis sensor is embedded in the gliding wing model, the nine-axis sensor, the display screen and the audio playing device are in communication connection with the multimedia workstation, the holding rod drives the gliding wing model to move by taking the universal joint as a fulcrum, the nine-axis sensor outputs signals to be transmitted to the multimedia workstation, and the multimedia workstation controls the display screen to play corresponding pictures according to the nine-axis sensor output signals, and simultaneously controlling the audio playing device to play corresponding audio.

2. The apparatus for simulating wing-mounted extreme flight motions of claim 1, further comprising: the method is characterized in that: the nine-axis sensor comprises a three-axis acceleration sensor, a three-axis gyroscope and a three-axis electronic compass, and the multimedia workstation receives the output signals of the nine-axis sensor and obtains the motion state of the glide wing model after fusion.

3. A device for simulating wing-mounted extreme flight movements according to claim 1 or 2, characterized in that: the audio playing device comprises an audio processor, a power amplifier and a sound box which are sequentially connected, wherein the audio processor receives the audio signal output by the multimedia workstation and drives the sound box to play the corresponding audio through the power amplifier.

4. A device for simulating wing-mounted extreme flight motions according to claim 3, wherein: the display screen is an LED display screen or a liquid crystal splicing screen.

Technical Field

The invention relates to the technical field of exhibition items, in particular to an exhibition item device for simulating wing-mounted flight extreme motion.

Background

Wing dress flight is a limit motion, and its danger and degree of difficulty are all very big, and low-altitude flight is very big especially, because flight height is limited, and the time for adjusting the posture and opening the parachute is short in storage, even the wing dress pilot of occupation also is difficult to guarantee one hundred per cent life safety.

In the exhibition and display industry, the existing exhibition items are mainly passively received by vision, hearing and touch, and lack of interest and novelty, and an immersive interactive exhibition item device taking wing-mounted flight as a theme is not available at present.

Disclosure of Invention

The invention aims to solve the technical problem of providing an item exhibition device for simulating wing-mounted flight extreme movement, and the item exhibition device enables a common experiencer to experience the fun of wing-mounted flight without training through the combination of a virtual reality technology and flight equipment.

In order to solve the technical problems, the invention provides an item unfolding device for simulating wing-mounted flight limit movement, which comprises a display screen, a multimedia workstation, a simulated gliding mechanism and audio playing equipment, wherein the simulated gliding mechanism comprises a gliding wing model, a universal joint, a support, a holding rod and a nine-axis sensor, the universal joint is arranged on the top surface of the gliding wing model, the support is connected with the universal joint and enables the gliding wing model to be erected in front of the display screen, the holding rod is arranged on the bottom surface of the gliding wing model, the nine-axis sensor is embedded in the gliding wing model, the nine-axis sensor, the display screen and the audio playing equipment are in communication connection with the multimedia workstation, the holding rod drives the gliding wing model to move by taking the universal joint as a fulcrum, then the nine-axis sensor output signals are transmitted to the multimedia workstation, and the multimedia workstation controls the display screen to play corresponding pictures according to the nine-axis sensor output signals, and simultaneously controlling the audio playing device to play corresponding audio.

Furthermore, the nine-axis sensor comprises a three-axis acceleration sensor, a three-axis gyroscope and a three-axis electronic compass, and the multimedia workstation receives the output signals of the nine-axis sensor and obtains the motion state of the glide wing model after fusion.

Furthermore, the audio playing device comprises an audio processor, a power amplifier and a sound box which are connected in sequence, wherein the audio processor receives the audio signal output by the multimedia workstation and drives the sound box to play corresponding audio through the power amplifier.

Further, the display screen is an LED display screen or a liquid crystal splicing screen.

The technical scheme is adopted in the exhibition device for simulating wing-mounted flight limit movement, namely the simulated gliding mechanism of the device comprises a gliding wing model, a universal joint, a support, a holding rod and a nine-axis sensor, wherein the universal joint is arranged on the top surface of the gliding wing model, the support is connected with the universal joint, the gliding wing model is erected in front of a display screen, the holding rod is arranged on the bottom surface of the gliding wing model, the nine-axis sensor is embedded in the gliding wing model, the nine-axis sensor, the display screen and audio playing equipment are in communication connection with a multimedia workstation, after the holding rod drives the gliding wing model to move by taking the universal joint as a fulcrum, signals output by the nine-axis sensor are transmitted to the multimedia workstation, and the multimedia workstation controls the display screen to play corresponding pictures according to the signals output by the nine-axis sensor and controls the audio playing equipment to play corresponding audio. This exhibition item device passes through the combination of virtual reality technique and flight equipment, makes experience person experience the enjoyment that the wing dress flies, avoids the potential safety hazard, brings the interactive experience of emulation for experience person to strengthen the interest and the competitiveness of exhibition item.

Drawings

The invention is described in further detail below with reference to the following figures and embodiments:

FIG. 1 is a schematic structural diagram of a project-expanding device for simulating wing-mounted flight extreme motion according to the invention.

Detailed Description

For example, as shown in fig. 1, the exhibition device for simulating winged flight limit motions of the present invention includes a display screen 1, a multimedia workstation 2, a simulated gliding mechanism 3 and an audio playing device 4, wherein the simulated gliding mechanism 3 includes a gliding wing model 31, a universal joint 32, a support 33, a holding rod 34 and a nine-axis sensor 35, the universal joint 32 is disposed on the top surface of the gliding wing model 31, the support 33 is connected to the universal joint 32 and makes the gliding wing model 31 erect in front of the display screen 1, the holding rod 34 is disposed on the bottom surface of the gliding wing model 31, the nine-axis sensor 35 is embedded in the gliding wing model 31, the nine-axis sensor 35, the display screen 1 and the audio playing device 4 are in communication connection with the multimedia workstation 2, the holding rod 34 drives the gliding wing model 31 to move with the universal joint 32 as a fulcrum, and then the nine-axis sensor 35 outputs signals to the multimedia workstation 2, the multimedia workstation 2 controls the display screen 1 to play corresponding pictures according to the output signal of the nine-axis sensor 35, and controls the audio playing device 4 to play corresponding audio.

Preferably, the nine-axis sensor 35 includes a three-axis acceleration sensor, a three-axis gyroscope and a three-axis electronic compass, and the multimedia workstation 2 receives the output signal of the nine-axis sensor 35 and obtains the motion state of the glide wing model 31 after fusion.

Preferably, the audio playing device 4 includes an audio processor 41, a power amplifier 42 and a sound 43 connected in sequence, and the audio processor 41 receives the audio signal output by the multimedia workstation 2 and drives the sound 43 to play the corresponding audio through the power amplifier 42.

Preferably, the display screen 1 is an LED display screen or a liquid crystal splicing screen.

A tester holds a holding rod in a hand to drive a glide wing model to move by taking a universal joint as a fulcrum, the glide wing model swings by adjusting an angle, so that the flight of a simulation wing is simulated, a nine-axis sensor detects the motion state of the glide wing model and sends a signal to a multimedia workstation, the multimedia workstation fuses the signals output by the nine-axis sensor to acquire the motion state of the glide wing model, controls a display screen to play a picture matched with the motion state of the glide wing model, realizes interaction with the tester, and controls an audio playing device to play corresponding audio simultaneously to support the atmosphere of the flight of the wing.

The multimedia workstation in the exhibition device is responsible for receiving interactive data of the flight of the paraglider model simulation wing, classifying and identifying the motion state of the paraglider model, and finally sending the identification result to the display screen and the audio playing device to realize interaction with an experiencer.

The nine-axis sensor is a motion sensing tracking element commonly used in electronic products for interactive control. The acceleration sensor is used for measuring acceleration in all directions in space, the gravity block generates pressure to the X, Y, Z direction when the gliding wing model moves by utilizing the inertia of the gravity block, the piezoelectric crystal is utilized again to convert the pressure into an electric signal, the pressure in all directions is different along with the change of the movement, and the electric signal also changes, so that the acceleration direction and the speed of a measured object are judged.

The gyroscope is used for measuring angles and maintaining directions, and can completely monitor the displacement of the glider model in the flight game, so that various game operation effects are realized. The actual gyroscope and the acceleration sensor are all microelectronic elements, and the Coriolis force is utilized, the state of a circuit is changed through the motion deviation of a continuously vibrating vibrator in a rotating system, so that the change of relevant electrical parameters is caused, and the motion states such as left-right inclination, front-back inclination, left-right swinging and the like can be reflected.

The acceleration sensor and the gyroscope can be used for basically describing the complete motion state of the glider model, but accumulated deviation can be generated along with long-time motion, and the motion attitude cannot be accurately described, for example, the control picture is inclined. The electronic compass measures the earth magnetic field, corrects and compensates through the absolute pointing function, and can effectively solve the accumulated deviation, thereby correcting the motion direction, the attitude angle, the motion force, the speed and the like of the glide wing model.

The motion state of the glide wing model is accurately known through the nine-axis sensor, so that the simulated wing suit flight is more vivid, the performance of the wing suit flight device is effectively improved, the experience of the wing suit flight is improved, the participation of audiences to the exhibition item is improved, and the content of the exhibition item is enriched.