CN106422306B - Virtual-real interactive display module and entertainment ghost house - Google Patents

Abstract

The invention provides a virtual-real interaction display module and a ghost house for entertainment, relates to the technical field of display, and is used for solving the problem that the frightening effect of the ghost house is reduced because tourists know the 'plot' of the ghost house. The virtual-real interactive display module comprises a plurality of interactive windows and display devices in one-to-one correspondence with the positions of the interactive windows, wherein holographic screens are paved in part of the interactive windows and are used for receiving pictures displayed by the display devices in the positions corresponding to the positions of the interactive windows so as to enable the interactive windows to be virtual-view windows; the other part of the interactive window without the holographic screen is a real scene window; the virtual-real interactive display module further comprises a replacement device connected with the holographic screen, and the replacement device is used for adjusting the laying position of the holographic screen so as to replace the positions of the virtual scene window and the real scene window. The method is used for displaying and switching virtual and real images.

Description

Virtual-real interactive display module and entertainment ghost house

Technical Field

The invention relates to the technical field of display, in particular to a virtual-real interactive display module and an entertainment ghost house.

Background

At present, various entertainment facilities are arranged in each large amusement place, and some of the entertainment facilities such as a haunted house can bring thrilling experience to tourists. In the ghost house, the ornament with terrorism, strange and other frightening effects is usually adopted to dress up the staff and the internal scenery, and in this case, the staff in the ghost house performs frightening performance according to scene settings, such as prop placement, organ setting, light effect and the like, so as to perform interactive game with tourists and achieve the purpose of frightening the tourists.

Because at the beginning of the construction of the haunted house, the setting positions of the props, the performance positions of the workers, the setting positions of the organs and the like are set, the contents of the startle performance of the workers according to the props are limited. After the tourists enter the ghost house to finish one experience, because of being familiar with the game flow of the ghost house, the frightened performance content cannot attract the tourists to enter the ghost house again for playing. In addition, going out of the ghost house to communicate with the people who do not enter the ghost house reduces the pleasure of the people who do not enter the ghost house, and after the tourists know the 'plot', the frightening effect is reduced.

Disclosure of Invention

The embodiment of the invention provides a virtual-real interactive display module and a ghost house for entertainment, and aims to solve the problem that the frightening effect of the ghost house is reduced because tourists know the 'plot' of the ghost house.

In order to achieve the above purpose, the embodiment of the invention adopts the following technical scheme:

the embodiment of the invention provides a virtual-real interactive display module, which comprises a plurality of interactive windows and display devices in one-to-one correspondence with the positions of the interactive windows; a holographic screen is laid in part of the interactive window and is used for receiving pictures displayed by a display device corresponding to the position of the interactive window so that the interactive window is a virtual scene window; the other part of the interactive window without the holographic screen is a real scene window; the virtual-real interactive display module further comprises a replacement device connected with the holographic screen, and the replacement device is used for adjusting the laying position of the holographic screen so as to replace the positions of the virtual scene window and the real scene window.

Optionally, the replacement device includes a first installation part and a second installation part, which are respectively installed at the upper and lower ends of the holographic screen and are not overlapped in position.

Optionally, the holographic screen is a holographic film; the first installation part comprises a first guide rail and a first sliding block matched with the first guide rail, and the upper end of the holographic film is connected with the first sliding block; the second installation part comprises a second guide rail and a second sliding block matched with the second guide rail, and the lower end of the holographic film is connected with the second sliding block.

Optionally, the holographic screen is a holographic plate, and the holographic plate includes a holographic film and a first transparent substrate located on at least one side of the holographic film; the first installation part comprises a first guide rail, and the upper end of the holographic plate is positioned in the first guide rail; the second installation part comprises a second guide rail, and the lower end of the holographic plate is located in the second guide rail.

Furthermore, the virtual-real interactive display module further comprises a locking structure, wherein the locking structure comprises a spring and a bulge connected with the spring; at least a groove is arranged on the second guide rail, and the spring is arranged in the groove.

Optionally, the holographic screen is a holographic film; the first installation part comprises a scroll for winding the holographic film, and the upper end of the holographic film is fixed on the scroll; the second installation part comprises a positioning piece for fixing the lower end of the holographic film.

The embodiment of the invention provides an entertainment ghost house, which comprises a ghost house body, a channel arranged in the ghost house body, and any one of the virtual-real interactive display modules positioned on at least one side of the channel.

Optionally, when the replacing device includes a first installing part and a second installing part, a second transparent substrate is arranged on the top surface of the ghost house body, and the first installing part is fixed on the second transparent substrate; the ghost house is characterized in that a third transparent substrate is arranged on the ground of the ghost house body, and the second installation part is fixed on the third transparent substrate.

Furthermore, the non-display side of the virtual-real interactive display module is provided with a shading curtain.

Optionally, a plurality of the virtual-real interactive display modules arranged side by side form a display group, and the display group is arranged on at least one side of the channel; the entertainment ghost house further comprises light sources which are respectively arranged on two sides of the display group.

The embodiment of the invention provides a virtual-real interactive display module and an entertainment ghost house. The virtual-real interactive display module is internally provided with a plurality of interactive windows. Wherein, the holographic screen has been laid in the mutual window of part among these a plurality of mutual windows, and the holographic screen can receive display device's display image to reflect this display image, reflection light passes through the holographic screen transmission to holographic screen one side that deviates from the plane of reflection and forms the virtual image, makes the user that is located this holographic screen plane of reflection one side can see the virtual image of display image, and under this condition, the above-mentioned mutual window of laying the holographic screen is virtual scene window. In addition, the holographic screen is not laid in part of the interactive windows, at this time, the display light emitted by the display device cannot be imaged in the interactive windows where the holographic screen is not laid, and the interactive windows are used for presenting a real scene, so that a real scene window is formed. On the basis, the virtual-real interactive display module further comprises a replacement device, and the replacement device is used for adjusting the laying position of the holographic screen so as to replace the positions of the virtual scene window and the real scene window.

Under this condition, after being applied to the amusement ghost house with above-mentioned virtual reality interaction display module assembly, above-mentioned virtual reality interaction display module assembly can carry out the virtual image according to the performance "scenario" of amusement ghost house and show at virtual scene window, and the staff can carry out the real person performance at real scene window. On the basis, after the content of the performance 'scenario' is changed by the staff, the positions of the virtual scene window and the real scene window can be replaced through the replacement device, so that the performance position of the staff can be adjusted at any time according to the changed 'scenario'. Therefore, after the tourists enter the ghost house to complete one-time experience, the tourists cannot be familiar with the game flow of the ghost house, so that the probability that the tourists enter the ghost house again to play is improved, and the problem that the frightening effect of the ghost house is reduced because the tourists know the 'plot' of the ghost house is solved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a virtual-real interactive display module according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of another virtual-real interactive display module according to an embodiment of the present invention;

FIG. 3 is a schematic diagram illustrating a display principle of a holographic screen in the virtual-real interactive display module shown in FIG. 1 or FIG. 2;

fig. 4a is a schematic view of a holographic screen laid on an interactive window according to an embodiment of the present invention;

FIG. 4b is a schematic diagram of a hologram screen not laid on an interactive window according to an embodiment of the present invention;

FIG. 4c is a schematic diagram of another holographic screen not laid on the interactive window according to the embodiment of the present invention;

FIG. 5 is a schematic diagram of an installation position of a holographic screen and a display device according to an embodiment of the present invention;

FIG. 6 is a schematic diagram of an installation position of another holographic screen and display device according to an embodiment of the present invention;

FIG. 7 is a schematic view of an arrangement of the display device when the holographic screen is tilted;

FIG. 8 is a schematic view of a first mount and a second mount when the holographic screen is a holographic film;

FIG. 9 is a schematic view of a shape of a contact surface between a guide rail and a slider according to an embodiment of the present invention;

FIG. 10 is a schematic view of a first mount and a second mount when the holographic screen is a holographic plate;

FIG. 11 is a schematic view of a locking structure according to an embodiment of the present invention;

FIG. 12 is another schematic view of the first and second mount portions when the holographic screen is a holographic film;

fig. 13 is a schematic structural diagram of another holographic screen provided in the embodiment of the present invention, which is not laid on the interactive window;

FIG. 14 is a schematic view of an entertainment ghost house according to an embodiment of the present invention;

FIG. 15 is a schematic view of another embodiment of an amusement haunted house;

fig. 16 is a schematic view of another entertainment ghost house according to the embodiment of the present invention.

Reference numerals:

01-virtual-real interactive display module; 10-a display device; 20-an interactive window; 21-virtual scene window; 22-live-action window; 23-a light source; 30-a holographic screen; 40-a displacement device; 401-a first mounting portion; 4011-a first guide rail; 4012-first slide; 402-a second mounting portion; 4021-a second guide rail; 4022-a second slider; 50-a locking structure; 501-a spring; 60-a reel; 61-a positioning element; 70-ghost house body; 80-a light-shielding curtain; 90-display group; 101-a first transparent substrate; 102-a second transparent substrate; 103-a third transparent substrate; 104-a holographic film; 201-support.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The embodiment of the invention provides a virtual-real interactive display module 01 as shown in fig. 1. The virtual-real interactive display module 01 includes a plurality of interactive windows 20 and display devices 10 corresponding to the positions of the interactive windows 20. Wherein the display light emitted from each display device 10 can be incident into the interactive window 20 corresponding to the position of the display device 10.

On the basis, a holographic screen 30 is laid in a part of the interactive windows 20 in the plurality of interactive windows 20 as shown in fig. 2. The holographic screen 30 is used to receive the picture displayed by the display device 10 corresponding to the position of the interactive window 20. In this case, as shown in fig. 3, after the display picture of the display device 10 is received by the reflection surface a of the holographic screen 30, the display picture may be reflected, and the reflected light is transmitted through the holographic screen 30 to the side of the holographic screen 30 away from the reflection surface a and forms a virtual image, so that a user positioned on the side of the reflection surface a of the holographic screen 30 can see the virtual image of the display picture. In this case, the interactive window on which the holographic screen 30 is laid is the virtual scene window 21.

In addition, another part of the interactive window 20 on which the holographic screen 30 is not laid is not provided, and the display light emitted from the display device 10 cannot be imaged in the interactive window 20 to display a virtual image, so that the interactive window 20 is used to present a real scene, thereby constituting the real scene window 22.

It should be noted that, in the embodiment of the present invention, when the holographic screen 30 laid in the interactive window 20 is capable of receiving the display light emitted by the display device 10 corresponding to the position of the interactive window 20 and presenting a complete virtual image as shown in fig. 4a, the holographic screen 30 is laid in the interactive window 20. If the holographic screen 30 does not completely cover an interactive window 20 in the vertical direction as shown in fig. 4b, or if the holographic screen 30 does not completely cover an interactive window 20 in the horizontal direction as shown in fig. 4c, so that the holographic screen 30 in the interactive window 20 cannot present a complete virtual image, the holographic screen 30 is not laid on the interactive window 20.

Based on this, as shown in fig. 2, the virtual-real interactive display module 01 further includes a replacing device 40 connected to the holographic screen 30, and the replacing device 40 is configured to adjust the laying position of the holographic screen 30 to replace the positions of the virtual view window 21 and the real view window 22.

Thus, after the virtual-real interactive display module 01 is applied to the entertainment ghost house, the virtual-real interactive display module 01 can perform virtual image display in the virtual view window 21 according to the "scenario" of the entertainment ghost house. Specifically, the display device 10 corresponding to the virtual view window 21 is opened, the holographic screen 30 in the virtual view window 21 receives the display image of the display device 10 and displays a virtual image, and the guest can see the virtual image of the display image on the side of the reflection surface a of the holographic screen 30. Meanwhile, the worker may perform a live performance within the live action window 22.

The real person performance of the operator in the live-action window 22 may be the same as or different from the display screen of the display device 10, and the present invention is not limited thereto. According to the 'plot' setting of the entertainment ghost house, when the real performance is the same as the display picture, the same virtual-scene picture and real performance are displayed in the plurality of interactive windows 20, so that the magic effect of the entertainment ghost house is increased; when the real performance is different from the display picture, the virtual scene window 21 displays the virtual scene, and the staff performs real interaction in the real scene window 22 to make sudden startle stimulation, thereby increasing the startle effect of the entertainment ghost house.

On the basis, after the staff changes the content of the performance "scenario", the positions of the virtual scene window 21 and the real scene window 22 can be replaced by the replacing device 40, so that the performance position of the staff can be adjusted at any time according to the changed "scenario". Therefore, after the tourists enter the ghost house to complete one-time experience, the tourists cannot be familiar with the game flow of the ghost house, so that the probability that the tourists enter the ghost house again to play is improved, and the problem that the frightening effect of the ghost house is reduced because the tourists know the 'plot' of the ghost house is solved.

In order to realize the virtual image display, the display device 10 is disposed at a certain inclination angle with respect to the holographic screen 30. Specifically, as shown in fig. 5, the holographic screen 30 is disposed perpendicularly to the ground when the display device 10 is installed, that is, the holographic screen 30 is disposed at an angle α of 90 ° with respect to the ground, and the display device 10 is disposed obliquely by the bracket 201 such that an angle β between the display light emitted from the display device 10 and the holographic screen 30 is an acute angle, for example, β of 45 °.

In another arrangement of the display device 10 and the holographic screen 30, as shown in fig. 6, the display light emitted by the display device 10 is perpendicular to the ground, and the holographic screen 30 is inclined at an angle α with respect to the ground, so that an included angle β between the display light emitted by the display device 10 and the holographic screen 30 is an acute angle, for example, β is 45 °. However, when the display device 10 and the holographic screen 30 are mounted by the first mounting method, the light emitting direction of the display device 10 needs to be adjusted by the bracket 201, and the mounting process is complicated.

In order to simplify the mounting process, it is preferable that the replacement device 40 includes a first mounting portion 401 and a second mounting portion 402 which are mounted on the upper and lower ends of the hologram screen 30, respectively, and do not overlap with each other in position, as shown in fig. 6. Thus, since the first installation part 401 and the second installation part 402 are not overlapped, that is, the first installation part 401 and the second installation part 402 are not on the same horizontal plane, when the upper end of the holographic screen 30 is installed on the first installation part 401 and the lower end is installed on the second installation part 402, the holographic screen 30 is inclined by a certain angle, and the angle α between the holographic screen 30 and the ground is not required to be adjusted.

On this basis, the installation position of the display device 10 will be described below when the hologram screen 30 is tilted.

Specifically, for example, as shown in fig. 6, when the angle α between the reflection surface a of the holographic screen 30 and the ground is an acute angle, the display device 10 is located below the holographic screen 30. In this case, the display device 10 emits the display light upward, the reflection surface a of the hologram screen 30 receives the display light and reflects the display light, and the reflection light is transmitted to the side of the hologram screen 30 away from the reflection surface a through the hologram screen 30 and forms a virtual image, so that the user positioned on the side of the reflection surface a of the hologram screen 30 can see the virtual image of the display screen.

Alternatively, for example, as shown in fig. 7, when the angle α between the reflection surface a of the hologram screen 30 and the ground is an obtuse angle, the display device 10 is located above the hologram screen 30. In this case, the display device 10 emits the display light downward, the reflection surface a of the hologram screen 30 receives the display light and reflects the display light, and the reflection light is transmitted to the side of the hologram screen 30 away from the reflection surface a through the hologram screen 30 and forms a virtual image, so that the user positioned on the side of the reflection surface a of the hologram screen 30 can see the virtual image of the display screen.

It should be noted that the structure of the holographic screen 30 is not limited in the present invention, and may be, for example, a holographic film; or a hologram plate including the hologram film described above and further including a transparent substrate, such as a glass substrate or a transparent resin substrate, disposed on at least one side surface of the hologram film may be used in order to increase the rigidity of the hologram screen 30.

Hereinafter, the configurations of the first and second mounting portions 401 and 402 will be described in detail with respect to the hologram screen 30 having different configurations.

Specifically, for example, when the holographic screen 30 is a holographic film, in order to avoid the phenomenon that the holographic film is damaged due to the fact that the holographic film is directly fixed on the first installation part 401 and the second installation part 402, as shown in fig. 8, the first installation part 401 includes at least one pair of first guide rails 4011 and a first slider 4012 matched with the first guide rails 4011, and the upper end of the holographic film is connected with the first slider 4012. In addition, the second mounting portion 402 includes at least a pair of second guide rails 4021 and a second slider 4022 engaged with the second guide rails 4021, and the lower end of the hologram film is connected to the second slider 4022.

Therefore, when the positions of the virtual window 21 and the real window 22 are replaced, the holographic film moves along the extending direction of the first guide rail 4011 and the second guide rail 4021 by the cooperation of the first slide block 4012 and the first guide rail 4011 and the cooperation of the second slide block 4022 and the second guide rail 4021, and the position of the holographic film in the interactive window 20 is adjusted. After the position adjustment, the window with the holographic film laid thereon is a virtual window 21, and the window without the holographic film laid thereon is a real window 22. On the basis of the above, the staff can change the position of the performance according to the position change of the virtual scene window 21 and the real scene window 22.

Note that the contact surface between the first slider 4012 and the first guide 4011, and the contact surface between the second slider 4022 and the second guide 4021 may be rectangular as shown in fig. 8. However, when the contact surfaces of the first guide rail 4011 and the first slider 4012 and the second guide rail 4021 and the second slider 4022 are rectangular, in the process of installing the guide rail and the sliders, the guide rail may cause a certain damage to the sliders due to sharp corners on the contact surfaces, and further the matching effect between the first guide rail 4011 and the first slider 4012 and between the second guide rail 4021 and the second slider 4022 is affected. In order to solve the above problem, it is preferable that the contact surface between the first slider 4012 and the first guide 4011, the second slider 4022, and the second guide 4021 is a circular arc shape as shown in fig. 9.

For another example, when the holographic screen 30 is a holographic plate, the holographic plate may be a transparent substrate. In order to improve the effect of the holographic display, as shown in fig. 10, the hologram plate includes a hologram film 104 having high transmittance and reflectance; in addition, in order to further increase the rigidity of the hologram film 104, the hologram plate further includes a first transparent substrate 101 on at least one side of the hologram film 104. In this case, first mount section 401 includes first guide rail 4011, the upper end of the hologram plate is located in first guide rail 4011, second mount section 402 includes second guide rail 4021, and the lower end of the hologram plate is located in second guide rail 4021.

In this case, when the positions of the virtual view window 21 and the real view window are replaced, the position of the hologram film needs to be adjusted in the direction of the arrow shown in fig. 10, the upper end of the hologram plate is engaged with the first guide rail 4011, the lower end of the hologram plate is engaged with the second guide rail 4021, and the hologram plate is moved leftward or rightward, thereby adjusting the position of the hologram plate in the interactive window 20. After the position adjustment, the window laid with the holographic plate is a virtual window 21, and the window not laid with the holographic plate is a real window 22. On the basis of the above, the staff can change the position of the performance according to the position change of the virtual scene window 21 and the real scene window 22.

In the process of moving the hologram plate, since the joints between the upper end of the hologram film and the first guide rail 4011 and between the lower end of the hologram film and the second guide rail 4021 are smooth, when the hologram screen 30 moves to a designated position, the hologram screen 30 continues to move and cannot be fixed at the designated position.

In order to solve the above problem, as shown in fig. 11 (a cross-sectional view cut along a-a' of fig. 10), the virtual-real interactive display module 01 further includes a locking structure 50, where the locking structure 50 includes a spring 501 and a protrusion connected to the spring 501, and at least a groove is provided on the second rail 4021, and the spring 501 is installed in the groove.

Therefore, a groove is arranged in the region of the second guide rail 4021 corresponding to the virtual window 21, when the holographic screen 30 moves to the region, the protrusion of the locking structure 50 is clamped in the groove of the second guide rail 4021, so that the holographic screen 30 is fixed in the virtual window 21, and the holographic screen 30 does not move continuously without being pushed by an external force. When the position of the holographic screen 30 needs to be changed to replace the virtual window 21 and the real window 22, since the locking structure 50 includes the spring 501, when the pushing force on the holographic screen 30 is increased, the spring 501 itself will generate a certain reaction force, so that the holographic screen 30 is separated from the locking structure 50.

For another example, when the hologram screen 30 is a hologram film, as shown in fig. 12, the first mounting part 401 includes a reel 60 for winding the hologram film, an upper end of the hologram film is fixed to the reel 60, and the second mounting part 402 includes a positioning member 61 for fixing a lower end of the hologram film. The positioning member 61 may be a clip, and when the holographic film on the pull-down reel 60 is laid in an interactive window 20 to form a virtual window 21, the positioning member 61 clips the holographic film to be fixed on the second mounting portion 402.

It should be noted that the hologram film is laid on one interactive window 20, as shown in fig. 12, the hologram film on the reel 60 of the interactive window 20 is pulled down, and the lower end of the hologram film is fixed on the second mounting portion 402 through the positioning member 61, and when the hologram screen 30 in the interactive window 20 can receive the display light emitted by the display device 10 corresponding to the position of the interactive window 20 and presents a complete virtual image as shown in fig. 4a, the hologram screen 30 is laid in the interactive window 20. When the holographic film is not pulled down on the reel 60 of an interactive window 20, the display light emitted from the display device 10 cannot be imaged in the interactive window 20 to display a virtual image, so that the interactive window 20 is used to present a real scene, thereby constituting a real scene window 22.

In addition, when the lower end of the pulled-down hologram film is not fixed to the second mounting portion 402 as shown in fig. 13, the interactive window 20 is still the live view window 22 because the display light emitted from the display device 10 cannot present a complete virtual image as shown in fig. 4a in the interactive window 20.

Based on this, the virtual window 21 and the real window 22 can be replaced by controlling the scrolling and pulling of the holographic film, and further, the position of the performance can be changed by the staff according to the position change of the virtual window 21 and the real window 22.

The embodiment of the invention provides an entertainment ghost house, which comprises a ghost house body 70 as shown in fig. 14, a channel arranged in the ghost house body 70 along the arrow direction, and any one of the virtual-real interactive display modules 01 located on at least one side of the channel.

Based on this, the virtual-real interactive display module 01 can perform virtual image display in the virtual scene window 21 according to the "scenario" of the virtual house, specifically, the display device 10 corresponding to the virtual scene window 21 is turned on, the holographic screen 30 in the virtual scene window 21 performs virtual image display after receiving the display picture of the display device 10, and the guest can see the virtual image of the display picture on the side of the reflection surface a of the holographic screen 30. Meanwhile, the worker may perform a live performance within the live action window 22.

On the basis, after the staff changes the content of the performance "scenario", the positions of the virtual scene window 21 and the real scene window 22 can be replaced by the replacing device 40, so that the performance position of the staff can be adjusted at any time according to the changed "scenario". Therefore, after the tourists enter the ghost house to complete one-time experience, the tourists cannot be familiar with the game flow of the ghost house, so that the probability that the tourists enter the ghost house again to play is improved, and the problem that the frightening effect of the ghost house is reduced because the tourists know the 'plot' of the ghost house is solved.

It should be noted that the virtual-real interactive display module 01 is disposed on at least one side of the channel. For example, as shown in fig. 14, the virtual-real interactive display module 01 is disposed at one side of the channel, so that the tourists can watch frightened performance at one side of the channel, and can hide from the side away from the virtual-real interactive display module 01 when the tourists are afraid. When as shown in fig. 15, when the virtual-real interactive display module 01 is arranged on both sides of the tourist passage, the tourists can watch the frightening performance on both sides of the passage, and when the tourists are afraid, the virtual-real interactive display module 01 is arranged on both sides of the passage, so that the tourists can not hide on both sides of the passage, and the frightening effect of the recreational haunted house is improved.

As shown in fig. 16, when the replacement device 40 includes a first attachment portion 401 and a second attachment portion 402, the second transparent substrate 102 is provided on the top surface of the ghost house body, the first attachment portion 401 is fixed to the second transparent substrate 102, the third transparent substrate 103 is provided on the floor surface of the ghost house body, and the second attachment portion 402 is fixed to the third transparent substrate 103.

The tilt directions of the second transparent substrate 102 and the third transparent substrate 103 coincide with the tilt direction of the hologram screen 30. In order to reduce the visual difference of the whole haunted house, the second transparent substrate 102 and the third transparent substrate 103 are preferably made of transparent glass.

Based on this, since the third transparent substrate 103 is disposed on the ground, when the visitor is frightened to attack the staff, the third transparent substrate 103 can be used as a protection frame to form physical isolation between the staff and the visitor; on the other hand, the holographic screen 30 has high transmittance and reflectance, and the second and third transparent substrates 102 and 103 can maintain their consistency in visual effect with the holographic screen 30.

Further, as shown in fig. 14, a light shielding curtain 80 is disposed on the non-display side of the virtual-real interactive display module 01. After the positions of the virtual scene window 21 and the real scene window 22 are replaced by the replacing device 40, the worker adjusts his or her position after the shade 80 to move to the position of the real scene window 22 for performing. Thus, the guest cannot see the above process in the process of adjusting the position of the guest due to the shielding effect of the light shielding curtain 80, thereby preventing the guest from seeing the movement of the guest and reducing the startle effect.

In addition, since the ghost house body 70 is large, the conventional manufacturing process cannot manufacture the virtual-real interactive display module 01 satisfying the ghost house body 70, and therefore, as shown in fig. 14 or 15, a plurality of virtual-real interactive display modules 01 are arranged side by side to form a display set 90, and the display set 90 is disposed on at least one side of the channel.

Based on this, the staff can utilize a plurality of virtual reality interactive display module assemblies 01 that constitute the display group 90, through the virtual image picture display of virtual scene window 21 and the interactive performance of real scene window 22, realized the free switching between virtual reality like this, increased the interest and the frightening effect of amusement ghost house.

In the entertainment ghost house, in order to enhance the effect of holographic display, the entertainment ghost house is distributed and controlled in a dark environment. When the staff performs a performance in the live-action window 22, it may happen that the guest cannot see the performance because of too dark light.

In order to solve the above problem, it is preferable that the embodiment of the present invention, as shown in fig. 15, is respectively disposed at both sides of the display set 90 for providing the background light to the hologram screen 30. The light brightness of the light source 23 should not be too high, and the specific method for adjusting the light brightness is that, after the display device 10 of the real-view window 22 is closed, if a worker stands on the real-view window 22, the feeling given to the guest should be consistent with the brightness of the virtual image corresponding to the virtual-view window 21, and a large contrast cannot be generated. Preferably, the light source 23 is normally open.

On the basis, in the ghost house body 70, the position of the holographic screen 30 is adjusted by the replacing device 40, the virtual view window 21 and the real view window 22 are replaced, and the brightness of the background light provided by the light source 23 and the state of the display device 10 are adjusted, so that different scenes can be embodied, and the frightening effect is increased. For example, when the display device 10 is turned on, the guest can see a virtual image of the display screen in the virtual view window 21 in cooperation with the backlight; the display device 10 is closed, the position of the holographic screen 30 is adjusted, the original virtual scene window 21 is replaced by the real scene window 22, the tourists can see the real performance of the staff by matching with the background light, and at the moment, the staff can perform interactive performance in the real scene window 22 to increase the frightening effect. In addition, when the display device 10 is in a state of alternately turning on and off, i.e., a flashing state, the display device 10 is turned on, the virtual image of the display screen can be seen by the tourists, and when the display device 10 is turned on, the display screen disappears, so that a picture effect is created for the tourists, and the frightening effect of the recreational haunted house is enhanced.

The above description is only for the specific embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art can easily conceive of the changes or substitutions within the technical scope of the present invention, and all the changes or substitutions should be covered within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the appended claims.

Claims (9)

1. A virtual-real interactive display module is characterized by comprising a plurality of interactive windows and display devices which are in one-to-one correspondence with the positions of the interactive windows;

a holographic screen is laid in part of the interactive window and is used for receiving pictures displayed by a display device corresponding to the position of the interactive window so that the interactive window is a virtual scene window; the other part of the interactive window without the holographic screen is a real scene window;

the virtual-real interactive display module also comprises a replacement device connected with the holographic screen, wherein the replacement device is used for adjusting the laying position of the holographic screen so as to replace the positions of the virtual scene window and the real scene window;

the placement position of the display device and the holographic screen have an inclination angle;

the replacement device comprises a first installation part and a second installation part which are respectively installed at the upper end and the lower end of the holographic screen and are not overlapped in position.

2. The virtual-real interactive display module of claim 1, wherein the holographic screen is a holographic film;

the first installation part comprises a first guide rail and a first sliding block matched with the first guide rail, and the upper end of the holographic film is connected with the first sliding block;

the second installation part comprises a second guide rail and a second sliding block matched with the second guide rail, and the lower end of the holographic film is connected with the second sliding block.

3. The virtual-real interactive display module as claimed in claim 1, wherein the holographic screen is a holographic plate, the holographic plate comprises a holographic film and a first transparent substrate on at least one side of the holographic film;

the first installation part comprises a first guide rail, and the upper end of the holographic plate is positioned in the first guide rail;

the second installation part comprises a second guide rail, and the lower end of the holographic plate is located in the second guide rail.

4. The virtual-real interactive display module according to claim 2 or 3, further comprising a locking structure, wherein the locking structure comprises a spring and a protrusion connected with the spring;

at least a groove is arranged on the second guide rail, and the spring is arranged in the groove.

5. The virtual-real interactive display module of claim 1, wherein the holographic screen is a holographic film;

the first installation part comprises a scroll for winding the holographic film, and the upper end of the holographic film is fixed on the scroll;

the second installation part comprises a positioning piece for fixing the lower end of the holographic film.

6. An entertainment ghost house, comprising a ghost house body, a channel arranged in the ghost house body, and the virtual-real interaction display module according to any one of claims 1-5 positioned on at least one side of the channel.

7. The recreational haunted house of claim 6, wherein, in a case where the replacement device includes a first mounting portion and a second mounting portion, a second transparent substrate is provided on the top surface of the haunted house body, the first mounting portion being fixed to the second transparent substrate; the ghost house is characterized in that a third transparent substrate is arranged on the ground of the ghost house body, and the second installation part is fixed on the third transparent substrate.

8. The fun haunted house according to claim 7, wherein the non-display side of the virtual-real interactive display module is provided with a light-blocking curtain.

9. The funny haunted house according to claim 6, wherein a plurality of said virtual-real interactive display modules arranged side by side constitute a display group, said display group being arranged on at least one side of said channel; the entertainment ghost house further comprises light sources which are respectively arranged on two sides of the display group.

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