CN221149049U - VR equipment is dressed to single - Google Patents

Abstract

The utility model provides VR equipment worn by a single person. This single VR equipment of wearing includes wear-type VR display device, backpack information transceiver processing equipment, air pump and wearing equipment. The wearable device includes a wearable vest and a wearable armband. The wearing vest is sequentially provided with a lining layer, an interlayer and a protective sheet layer from inside to outside. And a vent valve is arranged on the protective sheet layer. The head-mounted VR display device, the backpack information receiving and transmitting processing device and the power supply battery are separated, so that the burden of the head of a user can be reduced, the user can move the head more easily, and the pressure of the neck is reduced; the vest type design can more uniformly disperse the weight of the backpack type information receiving and transmitting processing equipment and the power supply battery, thereby improving the wearing comfort and reducing the discomfort and fatigue. The electromagnetic vibrator and the air bag provide dynamic tactile feedback, and the temperature regulating element responds to the temperature in the virtual world in a simulation manner, so that interactivity and dynamic sense are increased, and the quality of VR games, training and simulation experience is improved.

Description

VR equipment is dressed to single

Technical Field

The utility model relates to the technical field of virtual reality, in particular to VR equipment worn by a single person.

Background

VR (Virtual Reality) technology has made significant progress in the fields of entertainment, education, training, and medical, providing an exclamatory experience for users. However, existing VR glasses typically provide only visual and auditory immersion sensations, lacking physical tactile feedback. The user cannot feel physical stimulus such as temperature, touch, impact or vibration, which has a disadvantage in simulating interaction and perception in the virtual world.

Disclosure of utility model

The utility model aims to provide VR equipment worn by a single person so as to solve the problems in the prior art.

The technical scheme adopted for achieving the purpose of the utility model is that the VR equipment is worn by a single person and comprises a head-mounted VR display device, a backpack information receiving and processing device, an air pump and wearing equipment. The wearable device includes a wearable vest and a wearable armband.

The wearing vest is sequentially provided with a lining layer, an interlayer and a protective sheet layer from inside to outside. And a vent valve is arranged on the protective sheet layer. The interlayer is internally provided with a plurality of air bags which are arranged in a laminated way. The plurality of air bags are mutually independent. Each air bag comprises an air inlet and an air outlet. And the air inlet and the air outlet are respectively provided with an air inlet electromagnetic valve and an air outlet electromagnetic valve. The inner wall of the air bag is provided with a pressure sensor. One side of the ventilation valve is communicated with the air pump through an inflation pipe, and the other side of the ventilation valve is respectively communicated with an air inlet valve of the air bag through a plurality of ventilation branches. The back of the wearing vest is provided with a storage bag and a storage bag.

An electromagnetic vibrator is arranged in the wearing armband.

The backpack information receiving and transmitting processing equipment is accommodated in the accommodating bag. The air pump is accommodated in the accommodating bag. The head-mounted VR display device, the ventilation valve, the air pump, the electromagnetic vibrator, the air inlet electromagnetic valve and the air outlet electromagnetic valve are all connected with the backpack information receiving and transmitting processing device. The backpack information receiving and transmitting processing equipment controls the action of the ventilation valve, the air pump, the electromagnetic vibrator, the air inlet electromagnetic valve and the air outlet electromagnetic valve. The electromagnetic vibrator transmits vibration to the skin to generate a tactile sensation. Inflation of the corresponding bag may increase its internal air pressure, thereby exhibiting an increase in bag inflation, impact and stiffness, while deflation of the bag may decrease its internal air pressure, thereby exhibiting a decrease in collapse and stiffness. Because each air bag can be independently adjusted, the corresponding object and scene changes in the virtual environment displayed by the head-mounted VR display device 1 at different positions, and the user can obtain the touch feedback consistent with the virtual environment. The air bags and electromagnetic vibrators provide dynamic tactile feedback, respond to events and actions in the virtual world, and increase interactivity and dynamic sense of motion.

Further, the lining layer is made of flexible materials.

Further, the lining layer is made of one or more of polyurethane, sponge, latex, butyl rubber or silica gel.

Further, a temperature adjusting element is also included. The temperature regulating element is embedded within the backing layer.

Further, the temperature regulating element is one or more of a resistance wire heating element, a carbon fiber heating element, a carbon nanotube heating element, a graphene heating element or a semiconductor refrigerating sheet.

Further, the storage bag and the storage bag are sewn on the protective sheet layer II.

Further, the containing bag and the containing bag are detachably connected to the protective sheet layer II.

Further, a power supply battery is also included. The back of the wearing vest is provided with a battery storage bin. The power supply battery is accommodated in the battery accommodating bin. The power supply battery is connected with the head-mounted VR display device, the ventilation valve, the air pump, the electromagnetic vibrator, the air inlet electromagnetic valve and the air outlet electromagnetic valve, and the backpack type information receiving and transmitting processing device.

Further, a heart rate monitoring device is included.

The technical effects of the utility model are undoubted:

1. the head-mounted VR display device, the backpack information receiving and transmitting processing device and the power supply battery are separated, so that the burden of the head of a user can be reduced, the user can move the head more easily, and the pressure of the neck is reduced; the vest type design can more uniformly disperse the weight of the backpack type information receiving and transmitting processing equipment and the power supply battery, thereby improving the wearing comfort and reducing the discomfort and fatigue;

2. The backpack information receiving and transmitting processing equipment adjusts the working states of the electromagnetic vibrator and the air bag in real time according to the changes of objects and scenes in the virtual environment displayed by the head-mounted VR display equipment, so that a user obtains haptic feedback of temperature, hug, touch, impact or vibration and the like consistent with the virtual environment;

3. The electromagnetic vibrator and the air bag provide dynamic tactile feedback, and the temperature regulating element responds to the temperature in the virtual world in a simulation manner, so that interactivity and dynamic sense are increased, and the quality of VR games, training and simulation experience is improved.

Drawings

Fig. 1 is a schematic diagram of a VR device worn by a single person;

FIG. 2 is a schematic diagram of an interlayer;

FIG. 3 is a schematic illustration of a wearable vest;

fig. 4 is a schematic diagram of a temperature regulating element.

In the figure: the wear-type VR display device 1, a wear-type vest 2, a lining layer 201, an interlayer 202, a protection sheet layer 203, a storage bag 204, a storage bag 205, a battery storage bin 206, a wear-type armband 3, a ventilation valve 4, an air bag 5, an air pump 6, an air inflation tube 7, an electromagnetic vibrator 8, a temperature adjusting element 9 and a heart rate monitoring device 10.

Detailed Description

The present utility model is further described below with reference to examples, but it should not be construed that the scope of the above subject matter of the present utility model is limited to the following examples. Various substitutions and alterations are made according to the ordinary skill and familiar means of the art without departing from the technical spirit of the utility model, and all such substitutions and alterations are intended to be included in the scope of the utility model.

Example 1:

the embodiment provides a single wearing VR equipment, including wear-type VR display device 1, backpack information transceiver processing equipment, air pump 6 and wearing equipment. The wearing device comprises a wearing vest 2 and a wearing armband 3.

The wearing vest 2 is provided with a lining layer 201, an interlayer 202 and a protective sheet layer 203 from inside to outside. The vent valve 4 is provided on the protector layer 203. The interlayer 202 has a plurality of air bags 5 stacked therein. The plurality of air bags 5 are independent of each other. Each airbag 5 includes an air inlet and an air outlet. And the air inlet and the air outlet are respectively provided with an air inlet electromagnetic valve and an air outlet electromagnetic valve. The inner wall of the air bag 5 is provided with a pressure sensor. One side of the ventilation valve 4 is communicated with the air pump 6 through an inflation tube 7, and the other side of the ventilation valve is respectively communicated with an air inlet valve of the air bag 5 through a plurality of ventilation branches. The back of the wearable vest 2 is provided with a storage bag 204 and a storage bag 205.

An electromagnetic vibrator 8 is arranged in the wearing armband 3.

The backpack information-transceiving processing device is housed in the storage bag 204. The air pump 6 is accommodated in the accommodating bag 205. The head-mounted VR display device 1, the ventilation valve 4, the air pump 6, the electromagnetic vibrator 8, the air inlet electromagnetic valve and the air outlet electromagnetic valve are all connected with the backpack information receiving and transmitting processing device. The backpack information receiving and transmitting processing equipment controls the action of the ventilation valve 4, the air pump 6, the electromagnetic vibrator 8, the air inlet electromagnetic valve and the air outlet electromagnetic valve. The electromagnetic vibrator transmits vibration to the skin to generate a tactile sensation. Inflation of the corresponding bag 5 may increase its internal air pressure, thereby exhibiting an increase in inflation, impact and rigidity of the bag 5, and deflation of the bag 5 may decrease its internal air pressure, thereby exhibiting a decrease in collapse and rigidity. Since each air bag 5 can be independently adjusted, the object and scene in the virtual environment displayed by the head-mounted VR display device 1 at different positions can be changed, and the user can obtain the haptic feedback consistent with the virtual environment. The air bag 5 and the electromagnetic vibrator provide dynamic tactile feedback, and increase interactivity and dynamic sense of motion in response to events and actions in the virtual world.

The circuit connection according to this embodiment is a conventional method adopted by those skilled in the art, and the technical teaching can be obtained through limited tests, which belongs to the widely used prior art.

Example 2:

The main content of this embodiment is the same as that of embodiment 1, wherein the liner layer 201 is made of a flexible material. In practical production, the material of the lining layer 201 is one or a combination of several of polyurethane, sponge, latex, butyl rubber, or silica gel.

Example 3:

This embodiment is mainly the same as embodiment 1 or 2, and further includes a temperature adjusting element 9. The temperature regulating element 9 is embedded within the backing layer 201. In actual production, the temperature adjusting element 9 is one or more of a resistance wire heating element, a carbon fiber heating element, a carbon nanotube heating element, a graphene heating element or a semiconductor refrigerating sheet.

Example 4:

The main points of this embodiment are the same as those of any one of embodiments 1 to 3, wherein the storage bag 204 and the storage bag 205 are sewn to the cover sheet layer ii 2023.

Example 5:

The main content of this embodiment is the same as any one of embodiments 1 to 3, wherein the storage bag 204 and the storage bag 205 are detachably connected to the protective sheet layer ii 2023.

Example 6:

The main content of this embodiment is the same as any one of embodiments 1 to 5, wherein a power supply battery is further included. The back of the wearable vest 2 is provided with a battery storage compartment 206. The power supply battery is accommodated in the battery accommodation compartment 206. The power supply battery is connected with the head-mounted VR display device 1, the ventilation valve 4, the air pump 6, the electromagnetic vibrator 8, the air inlet electromagnetic valve and the air outlet electromagnetic valve, and the backpack information receiving and transmitting processing device.

Example 7:

This embodiment is the same as any one of embodiments 1 to 3, and further includes a heart rate monitoring device 10.

Example 8:

Referring to fig. 1, the present embodiment provides a VR device worn by a single person, including a head-mounted VR display device 1, a backpack-type information transceiver device, an air pump 6, a temperature adjusting element 9, a power supply battery, and a wearing device. The wearing device comprises a wearing vest 2 and a wearing armband 3.

Referring to fig. 2, the wearing vest 2 is provided with a lining layer 201, an interlayer 202 and a protective sheet layer 203 in sequence from inside to outside. The lining layer 201 is made of flexible materials. In practical production, the material of the lining layer 201 is one or a combination of several of polyurethane, sponge, latex, butyl rubber, or silica gel. The vent valve 4 is provided on the protector layer 203. The interlayer 202 has a plurality of air bags 5 stacked therein. The plurality of air bags 5 are independent of each other. Each airbag 5 includes an air inlet and an air outlet. And the air inlet and the air outlet are respectively provided with an air inlet electromagnetic valve and an air outlet electromagnetic valve. The inner wall of the air bag 5 is provided with a pressure sensor. One side of the ventilation valve 4 is communicated with the air pump 6 through an inflation tube 7, and the other side of the ventilation valve is respectively communicated with an air inlet valve of the air bag 5 through a plurality of ventilation branches. Referring to fig. 3, the back of the wearable vest 2 is provided with a storage bag 204, a storage bag 205, and a battery storage bin 206. The receiving bag 204, the receiving bag 205 and the battery receiving compartment 206 are sewn or detachably attached to the protective sheet layer ii 2023.

An electromagnetic vibrator 8 is arranged in the wearing armband 3.

The backpack information-transceiving processing device is housed in the storage bag 204. The air pump 6 is accommodated in the accommodating bag 205. The power supply battery is accommodated in the battery accommodation compartment 206. The power supply battery is connected with the head-mounted VR display device 1, the ventilation valve 4, the air pump 6, the electromagnetic vibrator 8, the temperature adjusting element 9, the air inlet electromagnetic valve and the air outlet electromagnetic valve and the backpack information receiving and transmitting processing device.

The head-mounted VR display device 1, the ventilation valve 4, the air pump 6, the electromagnetic vibrator 8, the air inlet electromagnetic valve and the air outlet electromagnetic valve are all connected with the backpack information receiving and transmitting processing device. The backpack information receiving and transmitting processing equipment controls the action of the ventilation valve 4, the air pump 6, the electromagnetic vibrator 8, the air inlet electromagnetic valve and the air outlet electromagnetic valve. The electromagnetic vibrator transmits vibration to the skin to generate a tactile sensation. Inflation of the corresponding bag 5 may increase its internal air pressure, thereby exhibiting an increase in inflation, impact and rigidity of the bag 5, and deflation of the bag 5 may decrease its internal air pressure, thereby exhibiting a decrease in collapse and rigidity. Since each air bag 5 can be independently adjusted, the object and scene in the virtual environment displayed by the head-mounted VR display device 1 at different positions can be changed, and the user can obtain the haptic feedback consistent with the virtual environment. The air bag 5 and the electromagnetic vibrator provide dynamic tactile feedback, and increase interactivity and dynamic sense of motion in response to events and actions in the virtual world.

The temperature regulating element 9 is embedded within the backing layer 201. In this embodiment, referring to fig. 4, the temperature adjusting element 9 is a semiconductor refrigerating plate. The semiconductor refrigeration sheet, also called thermoelectric refrigeration sheet, is a heat pump. Its advantages are no slide parts, limited space, high reliability and no pollution to refrigerant. By utilizing the Peltier effect of the semiconductor materials, when direct current passes through a couple formed by connecting two different semiconductor materials in series, heat can be absorbed and released at two ends of the couple respectively, and the purpose of refrigeration can be realized. In this embodiment, the semiconductor refrigeration sheet is selected to be in a sheet shape, and heat transfer from one surface to the other surface occurs during operation, so that a temperature difference is generated, and a cold/hot surface is formed.

Claims (9)

1. VR equipment, its characterized in that are dressed to single: the device comprises a head-wearing VR display device (1), a backpack information receiving and transmitting device, an air pump (6) and a wearing device; the wearing equipment comprises a wearing vest (2) and a wearing armband (3);

The wearing vest (2) is sequentially provided with a lining layer (201), an interlayer (202) and a protective sheet layer (203) from inside to outside; a vent valve (4) is arranged on the protective sheet layer (203); the interlayer (202) is internally provided with a plurality of air bags (5) which are arranged in a laminated way; the air bags (5) are mutually independent; each air bag (5) comprises an air inlet and an air outlet; the air inlet and the air outlet are respectively provided with an air inlet electromagnetic valve and an air outlet electromagnetic valve; a pressure sensor is arranged on the inner wall of the air bag (5); one side of the ventilation valve (4) is communicated with the air pump (6) through an air charging pipe (7), and the other side of the ventilation valve is respectively communicated with an air inlet valve of the air bag (5) through a plurality of ventilation branches; a storage bag (204) and a storage bag (205) are arranged on the back of the wearing vest (2);

an electromagnetic vibrator (8) is arranged in the wearing armband (3);

the backpack information receiving and transmitting processing equipment is accommodated in a storage bag (204); the air pump (6) is accommodated in the accommodating bag (205); the head-mounted VR display device (1), the ventilation valve (4), the air pump (6), the electromagnetic vibrator (8), the air inlet electromagnetic valve and the air outlet electromagnetic valve are all connected with the backpack information receiving and transmitting processing device.

2. The single person wearable VR device of claim 1, wherein: the lining layer (201) is made of flexible materials.

3. The single person wearable VR device of claim 2, wherein: the lining layer (201) is made of one of polyurethane, sponge, latex, butyl rubber or silica gel.

4. The single person wearable VR device of claim 1, wherein: also comprises a temperature regulating element (9); the temperature regulating element (9) is embedded within the backing layer (201).

5. The single person wearable VR device of claim 4, wherein: the temperature regulating element (9) is one of a resistance wire heating element, a carbon fiber heating element, a carbon nano tube heating element, a graphene heating element or a semiconductor refrigerating sheet.

6. The single person wearable VR device of claim 4, wherein: the storage bag (204) and the storage bag (205) are sewn to the protective sheet layer II (2023).

7. The single person wearable VR device of claim 4, wherein: the containing bag (204) and the containing bag (205) are detachably connected to the protective sheet layer II (2023).

8. The single person wearable VR device of claim 1, wherein: the power supply battery is also included; a battery storage bin (206) is arranged at the back of the wearing vest (2); the power supply battery is accommodated in a battery accommodating bin (206); the power supply battery is connected with the head-mounted VR display device (1), the ventilation valve (4), the air pump (6), the electromagnetic vibrator (8), the air inlet electromagnetic valve, the air outlet electromagnetic valve and the backpack information receiving and transmitting processing device.

9. The single person wearable VR device of claim 1, wherein: a heart rate monitoring device (10) is also included.