JP7091088B2 - Gravity change experience simulation device and gravity change experience simulation system - Google Patents

Description

The present invention relates to a gravity change experience simulation device and a gravity change experience simulation system.

A simulator may be used for maneuvering training of aircraft and the like, and for tests to evaluate the airframe control system of aircraft and the like. In order to improve the training effect and the effectiveness of the test data in the flight training using the simulator and the test to evaluate the aircraft control system, the aircraft actually drives the feeling given to the operator of the aircraft etc. in the simulation. It is required to be close to the state of being.

Of the sensations given to the operator of an aircraft in simulation, as a device that simulates the change in gravity (simulation of force) felt by the operator due to the movement of the aircraft such as an aircraft, the cockpit on which the operator rides is conventionally hydraulically operated. A device (so-called motion device) has been used that allows the operator to experience the change in gravity by directly moving it by means of the like and giving acceleration to the operator.

However, in the motion device, when the member driving the cockpit reaches the drive limit range, the acceleration in the same direction cannot be generated. Therefore, the continuous gravity change amount and the gravity change time in the same direction are determined by the member. It depends on the drive range. Therefore, it may not be possible to sufficiently simulate continuous gravity changes in the same direction.

As a device that simulates a continuous change in gravity, there is a device that allows the operator to experience a continuous change in gravity due to centrifugal force by rotating the cockpit on which the operator is boarding along a circumferential orbit. However, such a device needs to be provided with a mechanism for rotating the cockpit, and the device itself becomes large and requires a space for rotating the cockpit, so that a large space is required for operation. There was a problem.

Further, as a device for simulating a change in gravity, there is also a device such as the device described in Patent Document 1 in which a person experiences simulated acceleration by applying attractive force and repulsive force from an arbitrary direction to a person in a stationary state by a magnetic force. It was being considered. Patent Document 1 describes a simulated acceleration experience device that installs a magnetic force generating portion that generates a magnetic force around a person wearing a clothing portion that reacts to the magnetic force.

Japanese Unexamined Patent Publication No. 7-44088

However, since the device described in Patent Document 1 uses a magnetic force, when the device described in Patent Document 1 is applied to an aircraft maneuvering simulator, the magnetic force generated from the magnetic force generating portion is mounted on the aircraft maneuvering simulator. May cause malfunction of electronic devices.
Further, in the apparatus described in Patent Document 1, when the distance between the magnetic force generating portion and the clothing portion changes, the magnetic force acting on the clothing portion also changes. Since the clothing portion moves with the movement of the person wearing the clothing portion, it may not be possible to apply a desired magnetic force to the clothing portion when the person moves. In other words, in order to generate a desired magnetic force, there is a possibility that the movement of the person wearing the clothing portion is restricted.
Further, since the device described in Patent Document 1 must be provided with a magnetic force generating portion, the device may become large in size. Therefore, for example, when applied to a closed place such as a cockpit, there may be restrictions on the arrangement of on-board equipment.

The present invention has been made in view of such circumstances, and it is possible for a subject to experience a desired change in gravity, prevent influence on other devices, and reduce restrictions on the subject. It is an object of the present invention to provide a gravity change experience simulation device and a gravity change experience simulation system capable of performing.

In order to solve the above problems, the gravity change experience simulation device and the gravity change experience simulation system of the present invention employ the following means.
The gravity change experience simulation device according to one aspect of the present invention is provided at a predetermined position of a wearing portion worn by a subject and the wearing portion, and holds a holding portion for holding a liquid and an amount of the liquid held by the holding portion. It includes a liquid amount adjusting unit for adjusting and a control unit for controlling the liquid amount adjusting unit.

In the above configuration, the weight of the holding portion provided on the wearing portion can be increased by holding the liquid in the holding portion. By increasing the weight of the holding portion, the subject wearing the wearing portion can experience gravity greater than its own weight.
Further, since the amount of liquid held by the holding portion can be adjusted by the liquid amount adjusting portion, the weight of the holding portion can be changed as desired. Therefore, the subject can experience the desired change in gravity.
Further, as a means for increasing the weight, a liquid having no specific shape is used. As a result, the amount of liquid held by the holding portion can be adjusted more precisely. Therefore, the subject who wears the wearing part can experience the weight change more faithfully. Further, for example, when a liquid having no magnetic force such as water is used, it is possible to prevent the influence of the magnetic force on other devices.
Further, in the above configuration, a holding portion is provided on the wearing portion. As a result, it is possible to accurately experience the change in gravity even when the subject is moving. In this way, since it is possible to move while experiencing the change in gravity, it is possible to reduce the restrictions on the subject.
Further, since the change in gravity is experienced by holding the liquid in the holding portion provided in the wearing portion, a large device or the like is not required in the vicinity of the subject. Therefore, for example, even in a closed place such as the cockpit of an aircraft, the subject can experience the change in gravity.

Further, the gravity change experience simulation device according to one aspect of the present invention includes a supply pipe communicating with the holding portion and a supply pump for supplying the liquid to the holding portion via the supply pipe, and the liquid. The amount adjusting unit may have a supply valve provided in the supply pipe and adjusting the amount of the liquid supplied to the holding unit.

In the above configuration, the supply pipe for supplying the liquid to the holding portion is provided with a supply valve for adjusting the amount of the liquid. This makes it possible to adjust the amount of liquid held by the holding portion before it is supplied to the holding portion. Therefore, the amount of liquid held by the holding portion can be adjusted more precisely.

Further, the gravity change experience simulation device according to one aspect of the present invention includes a discharge pipe communicating with the holding portion and a discharge pump for discharging the liquid from the holding portion via the discharge pipe. The amount adjusting unit may have a discharge valve provided in the discharge pipe and adjusting the amount of the liquid discharged from the holding unit.

In the above configuration, the weight of the holding portion can be reduced by discharging the liquid from the holding portion. As a result, for example, from the state where the liquid is held in the holding part, the liquid is discharged from the holding part and the weight of the holding part is reduced, so that the direction in which gravity acts on the subject wearing the wearing part is determined. You can experience the load in the opposite direction (feeling like floating). That is, the subject wearing the wearing portion can experience the load in the direction opposite to the direction in which gravity acts because the weight of the wearing portion is relatively reduced.

Further, in the gravity change experience simulation device according to one aspect of the present invention, the control unit may control the liquid amount adjusting unit based on the result of the simulation of the aircraft motion.

In the above configuration, the amount of liquid held by the holding portion can be adjusted based on the result of the simulation of the airframe movement. As a result, the subject can experience the change in gravity according to the movement of the aircraft.

The gravity change experience simulation system according to one aspect of the present invention includes the above-mentioned gravity change experience simulation device and an airframe motion calculation unit that performs the simulation.

According to the present invention, the subject can experience the desired change in gravity, the influence on other devices can be prevented, and the restriction on the subject can be reduced.

It is an overall schematic diagram of the gravity change experience simulation system which concerns on embodiment of this invention.

Hereinafter, an embodiment of the gravity change experience simulation device and the gravity change experience simulation system according to the present invention will be described with reference to the drawings.
As shown in FIG. 1, the gravity change experience simulation system 1 is based on the simulation results of the airframe motion calculation device (airframe motion calculation unit) 2 for simulating the airframe motion in an aircraft and the airframe motion calculation device 2. It is equipped with a gravity change experience simulation device 3 that can be moved. The gravity change experience simulation system 1 is a system that allows the subject 4 to experience the change in gravity due to the change in the attitude of the aircraft acting on the passengers of the aircraft.

The airframe motion calculation device 2 is a device that simulates gravity and gravity changes acting on the operator of an aircraft in response to the motion of the airframe of the aircraft when the aircraft is in operation. That is, when the attitude of the aircraft changes, the gravity acting on the operator and the change in gravity are simulated. The aircraft motion calculation device 2 transmits the simulation result to the control device 15 provided in the gravity change experience simulation device 3, which will be described later.

The gravity change experience simulation device 3 is attached to a clothing portion (wearing portion) 6 worn by the subject 4, a tubular holding portion 7 provided at a predetermined position of the clothing portion 6 to hold water (liquid), and a holding portion 7. A supply pipe 8 that communicates with the supply pipe 8, a supply pump 9 that supplies water to the holding portion 7 via the supply pipe 8, a supply side adjusting valve (supply valve) 10 provided in the supply pipe 8, and a discharge that communicates with the holding portion 7. The pipe 11, the discharge pump 12 that discharges water from the holding portion 7 via the discharge pipe 11, the discharge side adjusting valve (discharge valve) 13 provided in the discharge pipe 11, and the water collected by the discharge pump 12 are temporarily discharged. It is provided with a reservoir 14 that stores the stored water and supplies the stored water to the supply pump 9, and a control device (control unit) 15 that controls the supply pump 9 and the like.

The clothing portion 6 is a clothing-like member having a shape that follows the shape of the human body, and is formed so as to be able to closely cover substantially the entire area below the neck of the human body of the subject 4.

The holding portion 7 is a tubular member having a predetermined inner diameter and length, and is provided along the human body of the subject 4 who wears the clothing portion 6. The holding portion 7 may be provided on the inner surface or the outer surface of the clothing portion 6, or may be provided so as to be embedded between the inner surface and the outer surface of the clothing portion 6.
Further, a plurality of holding portions 7 are provided. The number of holding portions 7 and the arrangement of each holding portion 7 are determined by the rate of change and the amount of change in the gravity change to be simulated. That is, each holding portion 7 is arranged so that the subject 4 wearing the clothing portion 6 can more faithfully experience the change in gravity based on the change in the attitude of the aircraft. The plurality of holding portions 7 may be provided on a specific part of the human body of the subject 4 who wears the clothes part 6 (for example, four places of both arm parts and both feet parts), and may be provided in substantially the entire area of the clothes part 6. It may be provided so as to be stretched over.
Further, the thickness of each holding portion 7 (cross-sectional area of the flow path) and the length of each holding portion 7 also depend on the rate of change and the amount of change in the gravity change to be simulated, similar to the number of holding portions 7 and the arrangement of the holding portions 7. decide. Further, the thickness of the holding portion 7 may or may not be constant.

Further, each holding unit 7 is provided with a sensor (not shown) for measuring the amount of water held by the holding unit 7. The sensor transmits the acquired information (the amount of water held by the holding unit 7) to the control device 15. The sensor may be a flow rate measuring instrument that measures the flow rate of water flowing through the holding unit 7.

The supply pipe 8 is a tubular member through which water flows, and connects the supply pump 9 and one end of the holding portion 7 to communicate the supply pump 9 and the holding portion 7. The number of supply pipes 8 is the same as the number of holding portions 7, and each of the supply pipes 8 communicates with a plurality of holding portions 7. That is, the plurality of supply pipes 8 have a one-to-one correspondence with the plurality of holding portions 7. As shown in FIG. 1, the plurality of supply pipes 8 may branch from one pipe extending from the supply pump 9, or each may communicate with the supply pump 9.

The supply pump 9 pumps out the water stored in the reservoir 14, and supplies the pumped water to the supply pipe 8 in a state where a predetermined pressure is applied. That is, water is supplied to the holding portion 7 via the supply pipe 8. A plurality of supply pumps 9 may be provided so as to have a one-to-one correspondence with a plurality of supply pipes 8.

The supply side adjusting valve 10 is provided in each supply pipe 8. Each supply-side adjusting valve 10 is a valve whose opening degree can be adjusted, and adjusts the opening degree to adjust the flow rate of water flowing inside the supply pipe 8. The supply side adjusting valve 10 can adjust the amount of water supplied to the holding portion 7 by adjusting the flow rate of the water flowing inside the supply pipe 8. That is, the amount of water held by the holding portion 7 can be adjusted. In addition, in FIG. 1, due to the relationship of illustration, a plurality of supply-side control valves 10 are not shown, but are shown together.

The discharge pipe 11 is a tubular member through which water flows, and connects the discharge pump 12 and the other end of the holding portion 7 to communicate the discharge pump 12 and the holding portion 7. The number of discharge pipes 11 is the same as the number of holding portions 7, and each of the discharge pipes 11 communicates with a plurality of holding portions 7. That is, the plurality of discharge pipes 11 have a one-to-one correspondence with the plurality of holding portions 7. As shown in FIG. 1, the plurality of discharge pipes 11 may join one pipe connected to the discharge pump 12, or each may communicate with the discharge pump 12.

The discharge pump 12 sucks out the water in the discharge pipe 11 and supplies the sucked water to the reservoir 14. That is, water is discharged from the holding portion 7 via the discharge pipe 11. A plurality of discharge pumps 12 may be provided so as to have a one-to-one correspondence with a plurality of discharge pipes 11.

The discharge side adjusting valve 13 is provided in each discharge pipe 11. Each discharge side adjusting valve 13 is a valve whose opening degree can be adjusted, and by adjusting the opening degree, the flow rate of water flowing inside the discharge pipe 11 is adjusted. Further, the discharge side adjusting valve 13 can adjust the amount of water discharged from the holding portion 7 by adjusting the flow rate of the water flowing inside the discharge pipe 11. That is, the amount of water held by the holding portion 7 can be adjusted. In addition, in FIG. 1, due to the relationship of illustration, the plurality of discharge side adjusting valves 13 are not shown, but are shown together.

The reservoir 14 is provided between the discharge pump 12 and the supply pump 9 in the flow of the water circulation, and stores water.

As described above, in the gravity change experience simulation device 3 in the present embodiment, the water supplied from the reservoir 14 to the supply pump 9 is the supply pump 9, the supply pipe 8, the holding portion 7, the discharge pipe 11, the discharge pump 12, and the reservoir. A circulation flow path that circulates in the order of 14 is formed.

The control device 15 controls the supply pump 9, the discharge pump 12, the supply side adjustment valve 10, and the discharge side adjustment valve 13 so as to adjust the amount of water held by the holding unit 7. The control device 15 receives information from the airframe motion calculation device 2 and the sensor.
Further, the control device 15 controls the operating state (whether it is in the drive state or the stop state) of the supply pump 9 and the discharge pump 12 by transmitting a signal to the supply pump 9 and the discharge pump 12. Further, the control device 15 controls the opening degree of the supply side adjustment valve 10 and the discharge side adjustment valve 13 by transmitting a signal to the supply side adjustment valve 10 and the discharge side adjustment valve 13. The opening degree of the supply side adjusting valve 10 and the discharging side adjusting valve 13 is controlled between the opening degree of 0% (fully closed state) and the opening degree of 100% (fully open state).
The control device 15 allows the subject 4 wearing the clothing portion 6 to experience the gravity change (gravity change amount and gravity change rate) according to the movement of the aircraft body, which is simulated by the body motion calculation device 2. The supply pump 9, the discharge pump 12, the supply side adjustment valve 10 and the discharge side adjustment valve 13 are controlled so that each holding unit 7 holds a predetermined amount of water.

The control device 15 is composed of, for example, a CPU (Central Processing Unit), a RAM (Random Access Memory), a ROM (Read Only Memory), a computer-readable storage medium, and the like. As an example, a series of processes for realizing various functions are stored in a storage medium or the like in the form of a program, and the CPU reads this program into a RAM or the like to execute information processing / arithmetic processing. As a result, various functions are realized. The program is installed in a ROM or other storage medium in advance, is provided in a state of being stored in a computer-readable storage medium, or is distributed via a wired or wireless communication means. Etc. may be applied. The computer-readable storage medium is a magnetic disk, a magneto-optical disk, a CD-ROM, a DVD-ROM, a semiconductor memory, or the like.

Next, the operation of the gravity change experience simulation system 1 in the present embodiment will be described.
First, the processing performed by the airframe motion calculation device 2 and the control device 15 will be described. In FIG. 1, the airframe motion information transmitted from the airframe motion calculation device 2 is illustrated by a one-dot chain line arrow, and the control signal transmitted from the control device 15 is illustrated by a broken line arrow.
First, the airframe motion calculation device 2 performs a process of simulating the change in gravity acting on the operator of the aircraft according to the motion of the airframe of the aircraft when the aircraft is in operation. The airframe motion calculation device 2 transmits the simulated result as the airframe motion information to the control device 15.

Upon receiving the simulation result, the control device 15 adjusts the opening degree of each supply side adjustment valve 10 and / or each discharge side adjustment valve 13 so that the subject 4 can experience the change in gravity according to the simulation result. A process of adjusting the amount of water held by each holding unit 7 is performed. That is, by adjusting the opening degree of each supply side adjustment valve 10 and / or each discharge side adjustment valve 13, the flow rate of water supplied to each holding unit 7 and the flow rate of water discharged from each holding unit 7 can be adjusted. By adjusting, the amount of water held by each holding portion 7 is adjusted. By adjusting the amount of water held by each holding portion 7, the mass of the clothing portion 6 is adjusted.
At this time, in the control device 15, each holding unit 7 holds a predetermined amount of water according to the gravity simulated by the airframe motion calculation device 2, and the subject 4 performs a gravity change according to the simulation result. The opening degree of each supply side adjustment valve 10 and / or each discharge side adjustment valve 13 may be controlled so as to be experienced. Further, the control device 15 increases or decreases the amount of water held by each holding unit 7 at a predetermined rate of change (increase / decrease amount of water per unit time) according to the gravity simulated by the aircraft motion calculation device 2. Then, the opening degree of each supply side adjustment valve 10 and / or each discharge side adjustment valve 13 may be controlled so that the subject 4 can experience the change in gravity according to the simulation result.

Further, the control device 15 constantly receives information from the sensors provided in each holding unit 7 and monitors the amount of water held by each holding unit 7. The control device 15 adjusts the opening degree of each supply side adjustment valve 10 and / or each discharge side adjustment valve 13 based on the information from the sensor. In FIG. 1, the sensor information transmitted from the sensor is illustrated by a two-dot chain arrow.

In the gravity change experience simulation system 1 of the present embodiment, the weight distribution of the clothing portion 6 in close contact with the human body of the subject 4 is continuously changed in this way, and the mass is changed to act on the subject 4. It is possible to simulate the change in gravity. Therefore, the subject 4 can experience the change in gravity in a simulated manner.

Next, the flow of circulating water will be described. In FIG. 1, the flow of water is indicated by a solid arrow.
The water stored in the reservoir 14 is pumped out by the supply pump 9 driven by the control device 15. The supply pump 9 circulates the pumped water into the supply pipe 8 at a predetermined pressure. The flow rate of the water flowing in the supply pipe 8 is adjusted by the supply side adjusting valve 10. The water in the supply pipe 8 whose flow rate has been adjusted flows into the holding portion 7 whose inlet side end communicates with the supply pipe 8. The water that has flowed into the holding portion 7 is held by the holding portion 7 and circulates in the holding portion 7. The water flowing through the holding portion 7 flows into the discharge pipe 11 communicating with the outlet side end portion of the holding portion 7. The flow rate of the water flowing in the discharge pipe 11 is adjusted by the discharge side adjusting valve 13. The water in the discharge pipe 11 whose flow rate is adjusted is sucked out by the discharge pump 12. The water sucked out by the discharge pump 12 is sent to the reservoir 14 and temporarily stored in the reservoir 14. In this embodiment, water circulates in this way.

According to this embodiment, the following effects are exhibited.
In the present embodiment, by holding the water in the holding portion 7, the weight of the holding portion 7 can be increased, and the weight of the clothing portion 6 provided with the holding portion 7 can be increased. By increasing the weight of the clothing portion 6, the subject 4 wearing the clothing portion 6 can experience gravity equal to or greater than its own weight.
Further, since the control device 15 can adjust the amount of water held by the holding unit 7 by controlling the supply side adjusting valve 10 and the discharging side adjusting valve 13, the weight of each holding unit 7 can be changed as desired. can. That is, the weight of the clothing portion 6 can be changed as desired. Therefore, the subject 4 who wears the clothing portion 6 can experience a desired change in gravity.
Further, in the present embodiment, the clothing portion 6 has a plurality of holding portions 7 arranged along a predetermined portion of the human body of the subject 4, and the supply pipes 8 are independent of each holding portion 7. And the discharge pipe 11 is connected, and a valve is provided in each supply pipe 8 and each discharge pipe 11. As a result, the amount of water held by the plurality of holding portions 7 can be different from each other, so that the weight balance of the clothing portions 6 can be a desired balance. Therefore, the subject 4 who wears the clothing portion 6 can more faithfully experience the change in gravity in a simulated manner.

Further, as a means for increasing the weight, water having no specific shape is used. Thereby, the amount of water held by each holding portion 7 can be adjusted more precisely. Therefore, the subject 4 who wears the clothing portion 6 can more faithfully experience the change in gravity in a simulated manner. In addition, water that does not have a magnetic force is used to experience the change in gravity. As described above, since the member that does not generate a magnetic force is used, it is possible to prevent the influence of the magnetic force on other devices.

Further, in the present embodiment, the holding portion 7 is provided on the clothing portion 6. That is, the change in gravity is simulated by the change in the weight of the clothing portion 6 worn by the subject 4. In this way, since the member that allows the subject 4 to experience the change in gravity is in close contact with the subject 4, the change in gravity can be accurately experienced even when the subject 4 is moving. In this way, since it is possible to move while experiencing the change in gravity, it is possible to reduce the restrictions on the subject 4. Further, since the change in gravity is experienced by holding the water in the holding portion 7 provided in the clothing portion 6, a large device or the like is not required in the vicinity of the subject 4. Therefore, for example, even in a closed place such as the cockpit of an aircraft, the subject 4 can experience the change in gravity. Further, for example, it can be easily combined with another simulation device such as a motion device.

Further, in the present embodiment, the supply side adjusting valve 10 for adjusting the flow rate of water is provided in the supply pipe 8 for supplying water to the holding portion 7. As a result, the amount of water held by the holding unit 7 can be adjusted before the water is supplied to the holding unit 7. Therefore, the amount of water held by the holding portion 7 can be adjusted more precisely.

Further, in the present embodiment, the weight of the holding portion 7 can be reduced by discharging water from the holding portion 7. As a result, for example, from the state where the water is held in the holding portion 7, the water is discharged from the holding portion 7 and the weight of the holding portion 7 is reduced, so that the subject 4 wearing the clothing portion 6 is subjected to gravity. You can experience the load (feeling of floating upward) in the direction opposite to the direction in which the water acts. That is, the subject 4 wearing the clothing portion 6 can experience the load in the direction opposite to the direction in which gravity acts because the weight of the clothing portion 6 worn is relatively reduced.

In the present embodiment, the amount of water held by the holding unit 7 is adjusted based on the simulation result of the airframe motion calculation unit that simulates the airframe movement of the aircraft. As a result, the subject 4 can experience the change in gravity according to the movement of the aircraft.

Further, since the sensor is provided in the holding portion 7, the amount of water held by the holding portion 7 can be accurately grasped. As a result, the holding portion 7 can hold a desired amount of water more precisely, so that the subject 4 can experience the desired gravity change more precisely.

The present invention is not limited to the invention according to the above embodiment, and can be appropriately modified without departing from the gist thereof.
For example, in the above embodiment, the example in which the clothing portion 6 is formed so as to be able to cover substantially the entire area below the neck of the human body of the subject 4 in close contact with each other has been described, but the present invention is not limited thereto. For example, the clothing portion 6 may be formed so as to cover only the portion of the human body to which the holding portion 7 is desired to be provided. For example, if it is desired to provide the holding portions 7 for both arms and both feet, a plurality of clothing portions 6 that cover only both arms and both feet may be provided.
Further, when it is desired to provide the holding portion 7 with respect to the head of the subject 4, the clothing portion 6 may have a member (for example, a helmet or the like) that covers the head of the subject 4. By providing the holding portion 7 on the member covering the head, the subject 4 can experience the change in gravity of the head.

Further, in the above embodiment, an example in which inexpensive and easy-to-handle water is used as the liquid held by the holding portion 7 has been described, but the present invention is not limited thereto. The liquid held by the holding portion 7 does not have to be water, and for example, a liquid having a heavier specific gravity than water may be used. By using a liquid with a heavier specific density than water, the range of gravitational change can be wider than that of water. Further, if the range of the weight change is not widened, the gravity change can be simulated with a smaller amount of liquid than water, so that the holding portion 7 can be miniaturized.

Further, in the above embodiment, an example in which the holding portion 7 is a tubular member has been described, but the present invention is not limited thereto. The holding portion 7 may have a structure capable of holding a certain amount of water, and may have a bag shape, for example.

Further, in the above embodiment, an example in which the control device 15 adjusts the amount of water held by the holding unit 7 by controlling the supply side adjusting valve 10 and the discharging side adjusting valve 13 has been described. Not limited to. For example, the control device 15 controls the supply side adjustment valve 10 and the discharge side adjustment valve 13, and controls the rotation speeds of the supply pump 9 and the discharge pump 12 to adjust the amount of water held by the holding unit 7. You may. With this configuration, the amount of water held by the holding unit 7 can be adjusted more precisely.

Further, a simulation device such as a flight simulator capable of simulating the operation of an aircraft may be combined with the gravity change experience simulation system 1 according to the present embodiment. As a specific example, the following combinations may be made.
The simulated device includes a simulated cockpit that imitates the cockpit of an aircraft, and the simulated cockpit is provided with a seat on which the subject 4 sits. The aircraft motion calculation device 2 calculates the reaction of the aircraft based on the operation signal of the control device provided in the simulated control room by the subject 4 seated in the seat, and displays the view image based on the calculation result on the image display unit. At the same time, the subject 4 may experience the gravity change based on the calculation result by the gravity change experience device. With such a configuration, since the view image and the gravity change can be linked, the subject 4 can more faithfully experience the gravity change according to the aircraft movement of the aircraft.
Further, since the gravity change device according to the present embodiment simulates the gravity change by the clothing portion 6 worn by the subject 4, as described above, a large device or the like is not required in the vicinity of the subject 4. That is, it is possible to simulate only by introducing the clothes portion 6 and the supply pipe 8 and the discharge pipe 11 connected to the clothes portion 6 into the simulated control room. Therefore, it is possible to reduce the occupied space in the simulated control room which is closed.

In addition, a device (so-called motion device) that allows the operator to experience the change in gravity by directly moving the cockpit on which the operator rides by hydraulic pressure or the like to give acceleration to the operator, and a device for experiencing the change in gravity according to the present embodiment. It may be combined with the system 1.

Further, the simulation device, the motion device, and the gravity change experience simulation system 1 according to the present embodiment may be combined.

1 Gravity change experience simulation system 2 Airframe motion calculation device (Aircraft motion calculation unit)
3 Gravity change experience simulation device 4 Subject 6 Clothing part (wearing part)
7 Holding part 8 Supply pipe 9 Supply pump 10 Supply side adjustment valve (supply valve)
11 Discharge pipe 12 Discharge pump 13 Discharge side adjustment valve (exhaust valve)
14 Reservoir 15 Control device (control unit)

Claims (5)

A wearing part worn by the subject, a holding part provided at a predetermined position of the wearing part, and a holding part for holding the liquid,
A liquid amount adjusting unit that adjusts the amount of the liquid held by the holding unit,
A control unit that controls the liquid amount adjusting unit is provided .
By controlling the liquid amount adjusting unit, the control unit adjusts the mass of the wearing portion so that the subject wearing the wearing portion can experience the gravity change according to the movement of the aircraft. Device. A supply pipe communicating with the holding portion and
A supply pump for supplying the liquid to the holding portion via the supply pipe is provided.
The gravity change experience simulation device according to claim 1, wherein the liquid amount adjusting unit is provided in the supply pipe and has a supply valve for adjusting the amount of the liquid supplied to the holding unit. The discharge pipe that communicates with the holding part and
A discharge pump for discharging the liquid from the holding portion via the discharge pipe is provided.
The gravity change experience simulation device according to claim 1 or 2, wherein the liquid amount adjusting unit is provided in the discharge pipe and has a discharge valve for adjusting the amount of the liquid discharged from the holding unit. The gravity change experience simulation device according to any one of claims 1 to 3, wherein the control unit controls the liquid amount adjusting unit based on the result of a simulation of airframe motion. The gravity change experience simulation device according to claim 4,
A gravity change experience simulation system including an airframe motion calculation unit that performs the simulation.

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