KR102319030B1 - A vertual reality video chair - Google Patents

Abstract

The present invention relates to a chair having left and right rotating shafts at the lower part and
Position detection like a gyro sensor can be combined with a position sensor.
A video monitor that is combined with a position sensor and
A horizontal support provided to rotate the monitor up and down, an up and down rotation means comprising an up and down rotation shaft and a handle, and
It is composed of a support having an up and down rotation shaft.
By directly coupling the support to the chair structure itself, the volume of the overall device configuration is minimized and
It is characterized in that the chair and the monitor simultaneously rotate left and right, while the monitor rotates up and down by the handle to provide an image of the viewing angle sensed by the position sensor 9 .

Description

Chair for virtual reality image {A VERTUAL REALITY VIDEO CHAIR}

The present invention relates to a chair for virtual reality video, in which a position sensor for discriminating the image position, a monitor, an up and down rotation function, and a left and right 360° rotation function are combined, but the It relates to a chair for an educational virtual reality image, characterized in that it is possible to enjoy a virtual reality image of the corresponding angle.

Virtual reality (VR=VIRTUAL REALITY) video refers to providing an image with the same effect as if it were in the field while rotating an image of more than 60° up and down by 360° left and right.

To provide a virtual reality image, a 360-degree full image is input, and a position detection sensor such as a gyro sensor moves up, down, left, and right based on the viewing range of a certain viewing range, which is a part of it, and has a corresponding viewing angle.

The need to use these virtual reality images for education or training is emerging.

However, the main means of viewing these virtual reality images is a headset (HMD=Head Mounted Device) structure that covers the front of the eyes and views the cervical vertebrae by rotating the cervical vertebrae and viewing 360 degrees left and right.

In addition, the human eye needs to use a magnifying lens to view an object or image within 30 cm of the visual distance because it is out of focus and the viewing distance must be shortened.

Since images viewed through these magnifying lenses cause myopia, problems such as fixation of myopia in adolescents occur.

In addition, this is a Korean patent Application No. 10-2015-0112406 The seesaw structure consists of a large screen on one side in both rooms and a chair structure on the other side, but with a rotating shaft connected to the weight vertex of the seesaw stand. It cannot be installed in buildings of educational facilities such as institutions.

In view of the above problems, the present invention prevents cervical vertebrae injuries when rotating to be suitable for educational purposes, enables sufficient image observation without a magnifying lens, and minimizes the volume within the occupied area of the existing chair desk, so that each student can use it We would like to suggest a structure that can be installed in many classrooms or small business places.

1, 2, 3, and 4, the present invention includes a chair 1 having left and right rotating shafts 2 provided at the lower part thereof, as shown in FIGS.

A position detection such as a gyro sensor is performed with the position sensor 9

A video monitor (8) configured to be combined with a position sensor (9) and

The monitor 8 includes a horizontal support 7 provided to rotate up and down, an up and down rotation means consisting of an up and down rotation shaft 5 and a handle 6, and

It consists of a support (7) having an upper and lower rotating shaft (5),

By directly coupling the support 7 to the chair 1 structure itself, the volume of the entire device configuration is minimized and

The chair 1 and the monitor 8 rotate left and right simultaneously while the monitor 8 is rotated up and down by the handle 6 to provide an image of the viewing angle sensed by the position sensor 9 .

According to the present invention, by providing a monitor at a visual distance of 30 cm or more from the image in a seated chair, it is possible to observe a virtual reality image without visual disturbance factors such as myopia induction.

The monitor connected to the chair rotates 360° left and right by the user's own power.

Since it rotates up and down by the handle structure, the cervical spine risk, which is a problem of the conventional HMD, is fundamentally eliminated.

In addition, since the support 7 is directly coupled to the structure of the chair 1 itself, the volume of the entire device is minimized and the present invention is configured within the area occupied by the area of the chair and the desk, so that it can be installed for individual students in a school classroom, It is highly effective for educational purposes such as classrooms and educational institutions.

1 is a configuration explanatory diagram of the present invention;
Figure 2 is a cross-sectional view of Figure 1
3 is an explanatory view of the up and down rotation of the monitor;
4 is an explanatory view of the left and right 360° rotation of the chair structure and the monitor structure.
Figure 5 (a) is an explanatory view when the monitor structure is replaced with a projector and a screen
Fig. 5 (b) is an explanatory view of the stereoscopic monitor structure;
Figure 5 (c) is an explanatory view of the augmented reality monitor

1, 2, 3, and 4 as shown in the present invention, a chair 1 having left and right rotating shafts 2 at the lower portion thereof and

A position sensor 9 provided with a sensor for position detection, such as a gyro sensor, and

A video monitor (8) configured to be combined with a position sensor (9) and

Up and down rotation means consisting of an up and down rotation shaft (5) and a handle (6) so that the monitor (8) rotates up and down;

This up-and-down rotation means is composed of a support (7) coupled to the chair (1), but

By directly coupling the support (7) to the chair (1) structure itself, the volume of the overall configuration is minimized and

The position sensor 9 is coupled to the monitor 8 so that the chair 1 and the monitor 8 rotate at the same time to the left and right, and the monitor 8 rotating left and right is moved up and down by the handle 6 It is characterized in that when the monitor 8 rotates up, down, left, and right, the image of the corresponding position is sensed and the image of the corresponding viewing angle is provided.

In the present invention, the position sensor 9 refers to a sensor that mainly searches for and determines the position of an image, such as a gyro sensor, an acceleration sensor, a geomagnetic sensor, and a GPS sensor.

Therefore, the position sensor 9 detects the partial viewing angle range specified in the virtual reality image of all viewing angles of 360 degrees input to the monitor as the range of the viewing angle at which the monitor 8 is rotated and provides the image of the corresponding viewing angle to the monitor 8. will be.

The position sensor 9 is built into the monitor itself or is separately separated, but rotates vertically and horizontally at the same time as the monitor 8 to provide a virtual reality image of the reagent angle controlled by the position sensor 9 .

Therefore, the present invention, as shown in FIGS. 1 and 2, according to the present invention, constitutes the left and right rotary shafts 2 under the chair 1 and includes the rotary pedestal 3 under the left and right rotary shafts 2, so that the chair 1 ) is configured to rotate the rotating support (3) by 360° around the main axis.

A monitor 8 is provided in front of the chair 1, and a vertical rotation means is provided so that the monitor 8 rotates up and down.

These up and down rotation means are provided with horizontal supports 7 in the front and rear directions at the front end of the chair 1, and are formed in a right angle shape at the middle of the horizontal support 7, and are configured in the left and right directions. The horizontal support (7) of the direction forms a handle (6) in the direction at right angles to the lower end.

The middle part of the horizontal support 7 is configured inside the upper and lower rotation shafts 5 as shown in FIG. 1 .

The upper and lower rotation shafts 2 are coupled to the support 7 again, and the support 7 is coupled to one side of the chair 1 again.

At this time, the chair 1 and the connection part are not particularly limited, but the support 7 should be configured to rotate left and right together with the chair in combination with the position above the lower left and right rotation shafts 2 of the chair 1 .

The shape of the support (4) structure, the upper and lower rotation shaft (5) structure, and the horizontal support (7) structure are not particularly limited.

However, when the user 100 is seated on the chair 1 and the structure of the chair 1 is not made by the user 100, it is difficult to rotate the floor around the left and right rotary shafts 2 with their own power, not with the power of a motor, etc. In principle, the chair 1 and the monitor 8 are rotated left and right at the same time, and the user 100 is configured in a structure and shape that does not cause discomfort when leaving the chair 1 .

In the present invention configured in this way, when the chair 1 is rotated, the chair 1, the user 100, and the monitor rotate left and right at the same time, and when the handle 6 is rotated up and down, the monitor by the up and down rotation shafts 5 (8) rotates up and down.

The length of the horizontal support 7 of the present invention can be configured to be adjustable.

In addition, the shape of the horizontal support 7 and the upper and lower rotation shafts 5 may be variously configured within the range that can achieve the object of the present invention.

Therefore, as shown in FIGS. 3 and 4 , in the present invention, when the user 100 rotates the chair 1 by its own power in the sitting position, the user 100, the chair 1, the monitor 8, and the monitor 8 are imaged. All of the means for rotating up and down rotate at the same time 360° in the left and right directions, and when the user 100 rotates the handle 6 up and down while rotating, the monitor 8 rotates left and right while simultaneously rotating up and down. rotates downwards.

The range of the image displayed on the monitor 8 is mainly in the range of 30 degrees up and down, and 60 degrees left and right.

When the monitor 8 rotates 360° left and right and up and down, it detects and calculates the range of the viewing angle at which the monitor 8 rotates out of the 360 degree image range, and provides an image of the corresponding range.

Therefore, the user 100 sits on the chair and rotates the chair and the handle 6 to observe the virtual reality image of 360 degrees up, down, left and right.

Such a handle 6 may be provided with various types of image adjustment devices such as a mouse structure capable of adjusting the image of the monitor 8 on the handle 6 or a shooting button.

That is, for example, sitting on a chair in a school classroom, you can experience outer space and famous canyons as if they were in the field, and VR educational games and VR learning games will also be possible.

In general, the floor area where chairs and desks can be installed in educational places such as schools is usually at least 1.5M in width and 1.5M in length, that is, an area of 2.25m2 per student is required.

As a result of carrying out the present invention as shown in FIG. 2, the distance A in FIG. 2 is 0.5 m and the total length is less than 1 m.

In this case, the distance from the sitting position of the actual user 100 to the image becomes 0.7 m, so that the clear distance is secured twice or more, so it is possible to observe the image of the monitor 8 without an auxiliary device that impairs vision, such as a special magnifying lens.

Since the installation area of the present invention is 1 m X 1 m = 1 m 2 per unit, the present invention can be installed in an area less than 1/2 of the 2.25 m 2 that is the conventional chair desk installation area, so that one unit can be installed per student in the conventional classroom. do.

This effect is possible by combining the upper and lower rotation means and the left and right rotation means at the same time to the structure of the chair 1 itself.

This invention

As shown in Fig. 5 (a), the structure of the image monitor 8 is replaced with the structure of the projector 8b and the image screen 8a, and the position sensor 9 is attached to the back surface of the screen 8a.

In this structure, since the position sensor 9 detects the moving direction and angle of the screen 8a and inputs the corresponding image to the projector, it is possible to provide a virtual reality image.

Since the weight of the screen 8a is relatively light compared to the monitor 8, it is effective in configuration.

As shown in (b) of FIG. 5 , the present invention comprises a translucent mirror 10 having a transmittance versus a reflectance of 5:5 in a square shape, and the semi-transparent mirror 10 is configured in a square shape, and is placed in a straight transmission position of the semi-transparent mirror 10 . 1st monitor 8c The 2nd monitor 8d is provided in the translucent mirror 10 orthogonal reflection position.

When the stereoscopic left eye image L is input to the first monitor 8c and the stereoscopic right eye image R is input to the second monitor 8d, the left and right eye images L and R are simultaneously viewed. can do.

As shown in Figure 5 (c), the present invention is provided with a semi-transparent mirror 10 with a reflectance: transmittance ratio ranging from 8:2 to 2:8 in a square shape on the upper portion of the case 10, and inside the case 11 at the lower portion. A monitor ( 8 ) and a separate position sensor ( 9 ) or a position sensor ( 9 ) combined with a monitor ( 8 ) and a separate position sensor ( 9 ) or a position sensor ( 9 ) provided at a right angle reflection position of the reflector ( 10a ) in a rectangular parallel with the upper translucent mirror ( 10 ) 8) is provided.

This configuration can be used as an MR (Mixer Reality) box by mixing an external real scene or image background and a virtual reality image.

That is, as shown in FIG. 5( c ), when the actual external foreground or screen image 12 is presented as a background, and the MR box structure is rotated, the position sensor 9 calculates the position of the background and corresponds to the corresponding position. An image is provided to the monitor 8 .

Therefore, since it is small in volume, it can be installed in various places such as schools, academies, homes, coffee shops, and game rooms to enjoy virtual reality, AR, and MR images.

It can solve the problems of neck injury and myopic visual impairment of the conventional HMD, and its use effect is great especially for education.

1. Chair 2, Left and Right Rotating Shafts 3. Rotating Stand 4. Support
5. Up and down rotation shaft 5a. Fixing device 6. Handle 7. Horizontal support
8. Video monitor 9. Position sensor 10. Translucent mirror 100, user
10a. reflector 8b. projector

Claims (4)

In the chair for virtual reality video
A chair (1) having left and right rotating shafts (2) provided at the lower portion and rotating in left and right directions; and
An image monitor 8 to which a position sensor 9 provided with a sensor for detecting a position, such as a gyro sensor, is coupled; and
Up and down rotation shafts 5 for rotating the image monitor 8 in the up and down directions by the handle 6; and
By including a; support (4) provided to couple the upper and lower rotation shafts (5) and the image monitor (8) to the structure of the chair (1)
The left and right rotating shafts (2), the upper and lower rotating shafts (5), the image monitor (8), and the position sensor (9) are for a virtual reality image, characterized in that the single chair (1) is configured chair 2. The method of claim 1
A chair for virtual reality image having the structure of the image monitor 8 as a projector 8b and a screen 8a, but comprising the position sensor 9 on one side of the projector 8b 2. The method of claim 1
In the configuration of the image monitor 8, a translucent mirror 10 having a transmittance to reflectance of 5:5 is formed in a square shape, and a first monitor 8c is provided at a straight transmission position of the translucent mirror 10, and the translucent mirror 10 is provided. (10) equipped with a second monitor (8d) at the orthogonal reflection position,
Virtual reality, characterized in that stereoscopic image observation can be performed by inputting a stereoscopic left-eye image (L) to the first monitor (8c) and an stereoscopic right-eye image (R) to the second monitor (8d) chair for video 2. The method of claim 1
The configuration of the video monitor 8 is provided with a semi-transparent mirror 10 with a reflectance: transmittance ratio ranging from 8:2 to 2:8 in a square shape on the upper portion of the case 13,
A reflective mirror 10a is provided in a rectangular shape parallel to the translucent mirror 10 inside the case 13 and
A chair for virtual reality image, characterized in that it is composed of an image monitor in which a position sensor 9 is coupled to a right angle reflection position of the reflector 10a

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