JP6930837B2 - Environment simulation device - Google Patents

Description

The present invention relates to an environment simulation device.

There is known a hands-on competition relay device that enables a viewer who is watching a video of a player to experience the situation that the player is experiencing in real time (see, for example, Patent Document 1). sea bream).
[Prior art literature]
[Patent Document]
[Patent Document 1] Japanese Unexamined Patent Publication No. 2000-342713

The conventional experience-based competition relay device has a large scale of equipment, and it is necessary for the athlete to go to the place where the experience-based competition relay device is installed to carry out training.

In the first aspect of the present invention, an environment simulation device is provided. The environment simulation device described above includes, for example, one or more transportable housings. The above-mentioned environment simulation device may be arranged inside one or more housings, has a space for accommodating animals, and may include a hypoxic chamber in which the oxygen concentration in the space is adjusted. The environment simulating device may be arranged inside one or more housings and may include a hypoxic air supply unit that supplies hypoxic air to the hypoxic chamber.

In the above environment simulation device, the low oxygen chamber and the low oxygen air supply unit may be arranged inside the same housing. The environment simulating device may include a first partition member that separates the machine room in which the low oxygen air supply unit is arranged and the low oxygen room. In the above environment simulating device, the low oxygen chamber may be formed with an air supply port for sending the low oxygen air supplied by the low oxygen air supply unit into the inside of the low oxygen chamber. In the above environment simulating device, the hypoxic chamber may be formed with an exhaust port for discharging the air inside the hypoxic chamber to the outside of the hypoxic chamber. In the above environment simulation device, the air supply port may be arranged at a position higher than the exhaust port. In the above environment simulation device, the pressure loss at the exhaust port may be larger than the pressure loss at the air supply port.

The above environment simulation device may include training equipment arranged inside the hypoxic chamber. The above-mentioned environment simulation device may include a display unit for displaying an image. The above-mentioned environment simulation device may include a display control unit that controls an image to be displayed on the display unit according to the load of the training device or the history of the load. The environment simulation device described above may include a blower that blows air toward the training device. The environment simulating device may include a blow control unit that controls the blower so that the blower blows an amount of air according to the load or load history of the training equipment. The above-mentioned environment simulation device may include a vital data acquisition unit that acquires vital data of a user of the training device. The above-mentioned environment simulation device may include a training device control unit that controls the training device based on the vital data of the user of the training device acquired by the vital data acquisition unit.

The above environment simulation device may include an air conditioner that adjusts at least one of the temperature and humidity inside the low oxygen chamber. The above environment simulation device may include an air conditioning control unit that controls the air conditioning unit. The above environment simulation device may include an oxygen concentration control unit that controls a low oxygen air supply unit. The above-mentioned environment simulation device may include a usage status management unit that manages the usage status of the environment simulation device. In the above environment simulation device, the usage status may include information on the time when the environment simulation device is used and the oxygen concentration inside the hypoxic chamber at that time. In the above environment simulation device, the oxygen concentration control unit may control the low oxygen air supply unit based on the usage status.

In the above environment simulation device, each of the one or a plurality of housings may be a container or a prefabricated building that can be transported by a vehicle, a ship, or an aircraft. The environment simulating device may include a chassis for loading at least one of the one or more housings, and a chassis having wheels arranged on the chassis.

In the second aspect of the present invention, an environment simulation device is provided. The environment simulation device described above includes, for example, a container or prefabricated building that can be transported by vehicle. The above-mentioned environment simulation device may be arranged inside a container or a prefabricated building, has a space for accommodating humans, and may include a hypoxic chamber in which the oxygen concentration in the space is adjusted. The above environment simulation device may be arranged inside a container or a prefabricated building and may include a hypoxic air supply unit that supplies hypoxic air to a hypoxic chamber. The above environment simulation device may include training equipment arranged inside the hypoxic chamber. The above-mentioned environment simulation device may be arranged inside the hypoxic chamber and may include a display unit for displaying an image. The above-mentioned environment simulation device may include a display control unit that controls an image to be displayed on the display unit according to the load of the training device or the history of the load. The environment simulating device may include (i) a machine room in which a low oxygen air supply unit is arranged and (ii) a first partition member for partitioning the low oxygen room. The environment simulation device may include a second partition member that separates (i) a control room in which a display control unit is arranged and (ii) a hypoxic room.

The outline of the above invention does not list all the necessary features of the present invention. Sub-combinations of these feature groups can also be inventions.

An example of the hypoxic training unit 100 is shown schematically. An example of the appearance of the container 110 is shown schematically. An example of the internal configuration of the container 110 is shown schematically. An example of the internal configuration of the container 110 is shown schematically. An example of the internal configuration of the container 110 is shown schematically. An example of the system configuration of the hypoxic training unit 100 is shown schematically. An example of the system configuration of the control device 360 is shown schematically.

Hereinafter, the present invention will be described through embodiments of the invention, but the following embodiments do not limit the inventions that fall within the scope of the claims. Also, not all combinations of features described in the embodiments are essential to the means of solving the invention. In the drawings, the same or similar parts may be given the same reference number to omit duplicate explanations.

FIG. 1 schematically shows an example of a hypoxic training unit 100. In this embodiment, the hypoxic training unit 100 includes a container 110, a chassis 120, and a fixing device 130. The hypoxic training unit 100 may have a plurality of fixtures 130. In the present embodiment, a low oxygen chamber 112, a machine room 114, and a control room 116 are provided inside the container 110. In the present embodiment, the chassis 120 has a chassis frame 122, wheels 124, a connecting device 126, and auxiliary legs 128. The chassis 120 may have a plurality of wheels 124. The chassis 120 may have a plurality of auxiliary legs 128.

The hypoxia training unit 100 may be an example of an environment simulation device. The container 110 may be an example of a transportable housing. The vehicle frame 122 may be an example of a gantry.

In this embodiment, the container 110 can be transported, for example, using a vehicle, ship or aircraft. The vehicle may be an ordinary automobile or a towing vehicle such as a tractor. Examples of aircraft include airplanes, airships, helicopters, and the like.

The hypoxic chamber 112 has a space for accommodating animals. The hypoxic chamber 112 may have a space for accommodating a human. The hypoxic chamber 112 may have a space large enough for one or more humans to perform various trainings inside the hypoxic chamber 112.

In the present embodiment, the oxygen concentration in the air inside the low oxygen chamber 112 (sometimes referred to as indoor oxygen concentration) is adjusted. In order to adjust the indoor oxygen concentration of the hypoxic chamber 112, for example, at least one of (i) the oxygen concentration of the fluid supplied to the hypoxic chamber 112 and (ii) the atmospheric pressure of the hypoxic chamber 112 is adjusted. The set value of the indoor oxygen concentration of the low oxygen chamber 112 may be (i) smaller than the oxygen concentration in the air outside the low oxygen chamber 112, or (ii) smaller than the oxygen concentration in the atmosphere at normal temperature and pressure. good. The oxygen concentration in the atmosphere at normal temperature and pressure is about 21% by volume.

The room oxygen concentration of the hypoxic chamber 112 is adjusted to an arbitrary value or range, for example, in the range of 10% by volume to 21% by volume. The room oxygen concentration of the hypoxic chamber 112 is preferably adjusted to an arbitrary value or range within the range of 13% by volume to 21% by volume. For example, when reproducing the environment near the summit of Mt. Fuji inside the low oxygen chamber 112, the indoor oxygen concentration is adjusted to 13.6% by volume. When reproducing the environment near 0 m above sea level inside the low oxygen chamber 112, the indoor oxygen concentration is adjusted to 21.0% by volume.

When measuring the oxygen concentration in the sample gas using an oxygen concentration meter, the oxygen concentration meter may not be able to accurately measure the oxygen concentration in the sample gas when the sample gas contains a large amount of water. Therefore, for example, when the measurement accuracy of the oxygen concentration becomes a problem, the measured value of the oxygen concentration in the sample gas measured by using the oxygen concentration meter is corrected based on the water concentration in the sample gas. good. For example, the measured value of the oxygen concentration in the sample gas measured using an oxygen concentration meter is converted into the oxygen concentration in the dry air at normal temperature and pressure. The indoor oxygen concentration of the hypoxic chamber 112 may be adjusted based on the measured value by the oxygen densitometer, or may be adjusted based on the corrected value of the measured value by the oxygen densitometer.

According to one embodiment, air having an oxygen concentration lower than the oxygen concentration in the atmosphere (sometimes referred to as hypoxic air) is supplied to the inside of the hypoxic chamber 112. For example, by controlling at least one of (i) the amount of oxygen contained in the low oxygen air (for example, the oxygen concentration) and (ii) the supply amount of the low oxygen air, the indoor oxygen concentration of the low oxygen chamber 112 Is adjusted. Thereby, for example, a normal pressure low oxygen state can be reproduced inside the low oxygen chamber 112. In this case, the hypoxic chamber 112 may or may not have an airtight structure.

According to another embodiment, the air pressure in the hypoxic chamber 112 is adjusted. By controlling the air pressure inside the hypoxic chamber 112, the indoor oxygen concentration of the hypoxic chamber 112 is adjusted. In this case, the hypoxic chamber 112 preferably has an airtight structure.

The pressure inside the hypoxia chamber 112 may be (i) similar to the pressure or atmospheric pressure outside the hypoxia chamber 112, and (ii) smaller than the pressure outside or atmospheric pressure outside the hypoxia chamber 112. It may be higher than the pressure outside the (iii) hypoxic chamber 112 or the atmospheric pressure. When the pressure inside the hypoxia chamber 112 is comparable to the pressure outside the hypoxia chamber 112 or the atmospheric pressure (sometimes referred to as a normal pressure hypoxic environment), the user makes hypoxic training safer. Can be executed.

In the present embodiment, the machine room 114 is provided with equipment for adjusting the air pressure and the indoor oxygen concentration of the low oxygen chamber 112. For example, in the machine room 114, equipment for supplying air having an adjusted oxygen concentration is arranged in the low oxygen chamber 112. Equipment for controlling the operation of the hypoxic training unit 100 is arranged in the control room 116. For example, the control equipment arranged in the control room 116 controls the operation of the equipment arranged in the machine room 114 and the operation of the equipment arranged in the low oxygen chamber 112. As a result, the user can easily reproduce an arbitrary training environment in the hypoxic chamber 112 by using the control equipment arranged in the control chamber 116. Further, for example, at least one of the state of the hypoxia training unit 100 and the state of the inside of the hypoxia chamber 112 can be monitored from a remote location, and the hypoxia training unit 100 can be operated.

In the present embodiment, the chassis 120 is equipped with the container 110. For example, a plurality of wheels 124 are attached to the vehicle frame 122. As a result, the container 110 mounted on the vehicle frame 122 can be transported by using a towing vehicle or the like. In the present embodiment, the connecting device 126 connects the chassis 120 and the towing vehicle that pulls the chassis 120. The type of the coupling device 126 is not particularly limited, but the fifth wheel coupling can be exemplified as the coupling device 126.

In the present embodiment, the auxiliary legs 128 and the fixing device 130 fix the container 110 to the installation location after the container 110 is transported to the installation location. The auxiliary legs 128 and the fixing device 130 temporarily fix the container 110 by reducing the load applied to the wheels 124, for example. The fixing device 130 may be a rigid having an elevating member.

In the present embodiment, the case where the transportable housing is a container has been described. However, the transportable housing is not limited to the container. In other embodiments, the transportable housing may be a prefabricated building.

In the present embodiment, the case where the hypoxic chamber 112, the machine chamber 114, and the control chamber 116 are arranged inside a single container 110 has been described. However, the hypoxic training unit 100 is not limited to this embodiment. In another embodiment, the hypoxic chamber 112, the machine chamber 114 and the control chamber 116 are divided and arranged in a plurality of transportable enclosures. For example, the low oxygen chamber 112 is arranged in the first housing, and the machine room 114 and the control room 116 are arranged in the second housing. In this case, at least one of the plurality of housings may be mounted on the chassis.

In the present embodiment, the case where the internal space of the container 110 is used as the low oxygen chamber 112 has been described. However, the method of using the internal space of the container 110 is not limited to this embodiment. In other embodiments, the training unit may control at least one of the air pressure and oxygen concentration in the internal space of the container 110 to reproduce any environment. The environment reproduced by the training unit is normal pressure environment, normal pressure low oxygen environment, normal pressure high oxygen environment, low pressure environment, low pressure low oxygen environment, low pressure high oxygen environment, high pressure environment, high pressure low oxygen environment, high pressure high oxygen. The environment and the like can be exemplified.

The oxygen concentration in the internal space of the container 110 is adjusted to an arbitrary value or range, for example, in the range of 10% by volume to 30% by volume. The oxygen concentration in the internal space of the container 110 is preferably adjusted to an arbitrary value or range within the range of 12% by volume to 27% by volume. The oxygen concentration in the internal space of the container 110 may be adjusted to any value or range within the range of 14% by volume to 25% by volume.

The internal space of the container 110 (for example, the low oxygen chamber 112) may be an example of an environment adjustment chamber in which the environment of the space is adjusted. As the environment of the space, at least one of temperature, humidity, atmospheric pressure, oxygen concentration, and the amount of radiation of electromagnetic waves can be exemplified. As the electromagnetic wave, at least one of visible light, infrared rays, far infrared rays and ultraviolet rays can be exemplified.

In one embodiment, the interior space of the container 110 is supplied with air adjusted for at least one of temperature, humidity and oxygen concentration. For example, the oxygen concentration in the internal space of the container 110 is adjusted by adjusting at least one of the oxygen concentration and the supply amount of the air supplied to the internal space of the container 110. In other embodiments, at least one of the temperature, humidity and air pressure of the interior space of the container 110 is adjusted. For example, by adjusting the air pressure in the internal space of the container 110, the oxygen concentration in the internal space of the container 110 is adjusted.

The equipment for supplying the oxygen-adjusted air to the internal space of the container 110 may be an example of the regulated air supply unit and the environment adjustment unit. Examples of the regulated air supply unit include temperature control equipment, humidity control equipment, low oxygen air generation equipment, high oxygen air generation equipment, carbon dioxide removal equipment, carbon monoxide removal equipment, and the like. The adjusting air adjusting unit and the equipment for adjusting the air pressure in the internal space of the container 110 may be an example of the environmental adjusting unit.

An example of the container 110 will be described with reference to FIGS. 2 to 5. FIG. 2 schematically shows an example of the appearance of the container 110. FIG. 3 schematically shows an example of the internal configuration of the container 110. FIG. 4 schematically shows an example of the internal configuration of the container 110. FIG. 5 schematically shows an example of the internal configuration of the container 110.

As shown in FIGS. 2 and 4, in the present embodiment, the main body 210 of the container 110 is provided with a door 220 and a door 420. The main body 210 is provided with a duct 234, a duct 236, and an opening 240.

In this embodiment, the main body 210 has a substantially rectangular parallelepiped shape. However, the shape of the main body 210 is not limited to this embodiment. The material of the main body 210 is not particularly limited, but the main body 210 may be made of a steel plate. The container 110 may or may not have an airtight structure. The container 110 may have a structure for preventing the intrusion of rainwater.

In the present embodiment, the door 220 is used for entering the user's room into the machine room 114, leaving the user's room from the machine room 114, carrying in the equipment into the machine room 114, carrying out the equipment from the machine room 114, and the like. In the present embodiment, the door 420 is used for entering the user's room into the control room 116, leaving the user's room from the control room 116, carrying in the equipment into the control room 116, carrying out the equipment from the control room 116, and the like.

In this embodiment, the duct 234 is provided on the wall surface of the machine room 114. The duct 234 allows gas to flow between the inside of the machine room 114 and the outside of the machine room 114. In this embodiment, the duct 236 is provided on the wall surface of the control chamber 116. The duct 236 allows gas to flow between the inside of the control chamber 116 and the outside of the control chamber 116.

In the present embodiment, the case where the equipment for directly flowing the gas between the low oxygen chamber 112 and the outside of the container 110 is not provided in the low oxygen chamber 112 will be described. However, the hypoxic chamber 112 is not limited to this embodiment. In other embodiments, (i) normally suppresses the direct flow of gas between the hypoxic chamber 112 and the outside of the container 110, and (ii) in an emergency, the outside of the hypoxic chamber 112 and the container 110. A ventilation device for forcibly ventilating the gas by directly circulating the gas may be provided in the hypoxic chamber 112. The above-mentioned ventilation device may operate based on the instruction from the control equipment arranged in the control chamber 116, or may operate based on the instruction of the user existing inside the hypoxic chamber 112. ..

In this embodiment, the opening 240 is provided on the wall surface of the machine room 114. The opening 240 is used, for example, for (i) wiring such as a power cable and a communication cable, and (ii) piping such as a water supply pipe and a drain pipe. The drain pipe may be a drain pipe that connects the air conditioner of the low oxygen chamber 112 and the outdoor unit (not shown) of the air conditioner. The outdoor unit of the air conditioner is arranged at an appropriate position outside the container 110, for example. The outdoor unit of the air conditioner may be arranged inside the machine room 114.

In one embodiment, the opening 240 is sealed using a sealing member or the like. In another embodiment, the opening 240 may allow gas to flow between the inside of the container 110 and the outside of the container 110. The installation location and the number of openings 240 are not limited to this embodiment. In another embodiment, the opening 240 may be provided on the door 220 or on the wall surface of the hypoxic chamber 112 or the control chamber 116.

As shown in FIGS. 2 to 4, in the present embodiment, the distribution board 302 is arranged inside the container 110. In the present embodiment, the distribution board 302 receives electric power from an external power source. In the present embodiment, the distribution board 302 supplies electric power to each part of the low oxygen training unit 100. The external power source may be a system power source, a power generation facility, or a power storage facility.

In the present embodiment, a wall 304 and a wall 306 are arranged inside the container 110. The wall 304 separates the low oxygen chamber 112 from the machine chamber 114. The wall 304 may be a soundproof wall. The wall 306 separates the hypoxic chamber 112 from the control chamber 116. The wall 306 may be a soundproof wall. The wall 304 and the wall 306 divide the space inside the container 110 into three rooms, a low oxygen chamber 112, a machine room 114, and a control room 116.

In the present embodiment, the wall 304 is provided with an air supply port 305. In the present embodiment, the wall 306 is provided with an observation window 307, an exhaust port 408, and a door 422. The wall 304 may be an example of the first partition member. The wall 306 may be an example of the second partition member.

In the present embodiment, the air supply port 305 sends the low oxygen air supplied from the equipment arranged in the machine room 114 into the inside of the low oxygen room. The exhaust port 408 discharges the air inside the low oxygen chamber 112 to the outside of the low oxygen chamber 112. The air supply port 305 may be arranged at a position higher than the exhaust port 408. As a result, in the embodiment in which the indoor oxygen concentration of the low oxygen chamber 112 is adjusted by sending the low oxygen air from the air supply port 305 into the low oxygen chamber 112, the indoor oxygen concentration can be efficiently reduced. can. The pressure loss of the exhaust port 408 may be larger than the pressure loss of the air supply port 305. Thereby, the oxygen concentration of the air inside the low oxygen chamber 112 can be efficiently adjusted.

In the present embodiment, the observation window 307 is used, for example, for observing the inside of the low oxygen chamber 112 from the control chamber 116. In the present embodiment, the door 422 is used for entering the user into the low oxygen chamber 112, leaving the user from the low oxygen chamber 112, carrying in the equipment into the low oxygen chamber 112, carrying out the equipment from the low oxygen chamber 112, and the like. It will be used.

In the present embodiment, the wall 304 to which the air supply port 305 is arranged is not provided with a door for the user to enter and leave the hypoxic chamber 112. The user passes through the door 420 to enter the control room 116, and then passes through the door 422 to enter the hypoxic chamber 112. On the other hand, the low oxygen air is supplied to the low oxygen chamber 112 from the air supply port 305. Further, the air inside the low oxygen chamber 112 is discharged to the control chamber 116 from the exhaust port 408. According to the present embodiment, it is possible to suppress changes in the environment of the hypoxic chamber 112 due to the user's entry and exit, as compared with the case where the door for the user to enter and leave the hypoxic chamber 112 is arranged on the wall 304. In some cases.

The door 422 may be arranged so that the shortest distance between the air supply port 305 and the door 422 is longer than the shortest distance between the exhaust port 408 and the door 422. According to this embodiment, it may be possible to suppress changes in the environment of the hypoxic chamber 112 due to the entry and exit of the user.

In the present embodiment, the case where only one door 422 for entering / exiting the hypoxic chamber 112 is provided has been described. However, the arrangement of the door 422 is not limited to this embodiment. In another embodiment, doors 422 for entering and exiting the hypoxic chamber 112 may be provided at a plurality of locations in the hypoxic chamber 112. Even if the hypoxic chamber 112 has a plurality of doors 422, the minimum value of the shortest distance between the air supply port 305 and the plurality of doors 422 is between the exhaust port 408 and the plurality of doors 422, respectively. A plurality of doors 422 may be arranged at positions longer than the minimum value of the shortest distance of.

[Overview of training equipment]
As shown in FIGS. 3 to 5, in the present embodiment, the treadmill 310 is arranged inside the low oxygen chamber 112. The treadmill 310 may be a treadmill for animals or humans to walk or run, or may be a treadmill for skiing, roller skating, skating, roller skating, roller blades, bicycles and the like. .. The treadmill 310 may be a self-propelled treadmill in which (i) an animal, a human, or the like is driven by the belt of the treadmill, and (ii) a drive source such as an electric motor or a motor is used. It may be a driven treadmill that drives the belt of the red mill. The treadmill 310 may be an example of training equipment. Other examples of training equipment include rowing machines, ergometers and the like.

The treadmill 310 may have an operation panel 312 for operating the treadmill 310. The operation panel 312 may have a display device that displays the status of the treadmill 310. In one embodiment, the treadmill 310 can adjust the load. For example, the treadmill 310 can adjust the traveling speed. In other embodiments, the treadmill 310 can be tilted.

The treadmill 310 may adjust at least one of the load and the tilt based on the instructions of the control device 360. The treadmill 310 may be switched ON / OFF based on the instruction of the control device 360. The treadmill 310 may transmit information indicating the state of the treadmill 310 to the control device 360.

In this embodiment, the treadmill 310 is installed on a tilting table 314. The upper surface of the tilting table 314 has an inclination with respect to the horizontal. Depending on the treadmill 310, it may be possible to reproduce the uphill slope, but not the downhill slope. Further, depending on the treadmill 310, the range of the slope rate of the down slope that can be set may be smaller than the range of the slope rate of the up slope that can be set. Even in such a case, when the set value of the gradient ratio of the treadmill 310 is 0%, the treadmill 310 is placed on the inclined table 314 so that the treadmill 310 has a downward gradient with respect to the horizontal. By installing the treadmill, the downhill slope can be sufficiently reproduced.

In the present embodiment, safety equipment 316 for ensuring the safety of the user using the treadmill 310 may be arranged inside the low oxygen chamber 112. The safety equipment 316 may be a lifeline, a combination of a lifeline and a winch for winding the lifeline, or a combination of a lifeline and a pulley. The safety equipment 316 may adjust the tension of the lifeline based on the instruction of the control device 360. The safety equipment 316 may transmit information indicating the state of the safety equipment 316 to the control device 360.

In the present embodiment, the user staying inside the hypoxic chamber 112 is equipped with a vital sensor 318 that acquires the vital data of the user. The vital sensor 318 may be worn on the user's finger, on the user's wrist, or on the user's chest. As vital data, information on heart rate, blood oxygen concentration, body temperature, blood pressure, and the like can be exemplified. The vital sensor 318 may transmit the acquired vital data to the control device 360. The vital sensor 318 may be an example of a vital data acquisition unit.

[Outline of equipment that reproduces the training environment]
As shown in FIGS. 3 to 5, in the present embodiment, one or more display equipment 322, one or more fixing members 324, and one or more lighting equipment 326 are inside the low oxygen chamber 112. Is arranged. For example, three display devices 322 are arranged so as to surround the treadmill 310. In the present embodiment, the temperature control equipment 332, the humidity control equipment 334, the blower equipment 336, and the sensor unit 338 are arranged inside the low oxygen chamber 112. As a result, the hypoxic training unit 100 can reproduce an arbitrary training environment inside the hypoxic chamber 112.

In the present embodiment, the low oxygen air generation equipment 352, the pipe 354, and the compressed air generation equipment 356 are arranged inside the machine room 114. In the present embodiment, the control device 360 is arranged inside the control chamber 116.

The display equipment 322 may be an example of a display unit. The temperature control equipment 332 may be an example of an air conditioner unit. The humidity control equipment 334 may be an example of an air conditioner. The blower equipment 336 may be an example of a blower unit. The hypoxic air generation facility 352 may be an example of a hypoxic air supply unit. The control device 360 may be an example of a display control unit, an air conditioning control unit, a ventilation control unit, a training equipment control unit, an oxygen concentration control unit, or a usage status management unit. The control device 360 may be an example of the control equipment arranged in the control room 116.

An imaging device (not shown) that captures an image of a user staying inside the hypoxic chamber 112 may be arranged inside the hypoxic chamber 112 or the control chamber 116. The image pickup apparatus may have at least one of a camera and an infrared camera. The imaging device may record the image in association with the time when the image was captured. This makes it possible to associate the training situation with the user's situation. The image may be a moving image or a still image.

The imaging device may transmit image data or data associated with the image and the time when the image was captured to the control device 360. The control device 360 may store the data acquired from the image pickup device. The control device 360 associates (i) the image of the user captured by the imaging device, (ii) the time when the image was captured, and (iii) the vital data acquired by the vital sensor 318 at the time. May be stored.

In the present embodiment, the display equipment 322 displays an image. For example, the display equipment 322 displays an image of the traveling course. This makes it possible to reproduce any training environment. The display equipment 322 may be a stationary display device, or may be a portable or wearable display device. Examples of the display equipment 322 include image display devices such as a liquid crystal display, a plasma display, an organic EL display, and a head-mounted display. The display equipment 322 may have a speaker that outputs sound. The display equipment 322 may have an audio output terminal for outputting audio information.

The display equipment 322 may display an image based on the instruction of the control device 360. In one embodiment, the display equipment 322 acquires video data of a video to be presented to the user from the control device 360. The display equipment 322 displays an image based on the acquired image data. In another embodiment, the display equipment 322 stores video data of video to be presented to the user. The display equipment 322 acquires information indicating an image to be presented to the user from the control device 360. The display equipment 322 displays an image based on the acquired information. The display equipment 322 may output audio based on the instruction of the control device 360. The display equipment 322 may switch ON / OFF of the display equipment 322 based on the instruction of the control device 360. The display equipment 322 may transmit information indicating the state of the display equipment 322 to the control device 360.

In the present embodiment, the fixing member 324 fixes the corresponding display equipment 322 at an arbitrary position. For example, the fixing member 324 fixes the display equipment 322 to the wall surface of the low oxygen chamber 112. In one embodiment, the fixing member 324 can adjust the angle between the display equipment 322 and the wall surface of the low oxygen chamber 112 to an arbitrary angle.

In the present embodiment, the lighting equipment 326 can adjust at least one of the color and brightness of the lighting. This makes it possible to reproduce any training environment. Lighting equipment 326 may have a visible light illuminator. The visible light illuminator may have an LED bulb. The lighting equipment 326 may have at least one of an infrared irradiation device, a far-infrared irradiation device, and an ultraviolet irradiation device in place of the visible light illumination device or in addition to the visible light illumination device. This makes it possible to more faithfully reproduce any training environment.

The lighting equipment 326 may adjust at least one of the color and brightness of the lighting based on the instruction of the control device 360. The lighting equipment 326 may switch ON / OFF of at least one of the visible light illumination device, the infrared irradiation device, the far infrared irradiation device, and the ultraviolet irradiation device based on the instruction of the control device 360. The lighting equipment 326 may transmit information indicating the state of the lighting equipment 326 to the control device 360.

In the present embodiment, the temperature control equipment 332 adjusts the temperature inside the low oxygen chamber 112. This makes it possible to reproduce any training environment. Examples of the temperature control equipment 332 include an air conditioner, a hot air blower, a cold air blower, a fan heater, and a stove. The temperature control equipment 332 may adjust the temperature inside the low oxygen chamber 112 based on the instruction of the control device 360. The temperature control equipment 332 may switch ON / OFF of the temperature control equipment 332 based on the instruction of the control device 360. The temperature control equipment 332 may transmit information indicating the state of the temperature control equipment 332 to the control device 360.

In the present embodiment, the humidity control equipment 334 adjusts the humidity inside the low oxygen chamber 112. This makes it possible to reproduce any training environment. Examples of the humidity control equipment 334 include an air conditioner, a humidifier, and a dehumidifier. The humidity control equipment 334 may adjust the humidity inside the low oxygen chamber 112 based on the instruction of the control device 360. The humidity control equipment 334 may switch ON / OFF of the humidity control equipment 334 based on the instruction of the control device 360. The humidity control equipment 334 may transmit information indicating the state of the humidity control equipment 334 to the control device 360.

In this embodiment, the blower equipment 336 blows air toward the treadmill 310. This makes it possible to reproduce the training environment. As the blower equipment 336, a blower fan or the like can be exemplified. The blower equipment 336 may adjust at least one of the air volume and the wind direction based on the instruction of the control device 360. The blower equipment 336 may switch ON / OFF based on the instruction of the control device 360. The blower equipment 336 may transmit information indicating the state of the blower equipment 336 to the control device 360.

In the present embodiment, the sensor unit 338 measures various physical property values related to the environment inside the hypoxic chamber 112. The sensor unit 338 measures, for example, at least one of the pressure, temperature, humidity, and oxygen concentration of the air inside the hypoxic chamber 112. The sensor unit 338 may transmit the measurement data to the control device 360. The sensor unit 338 may be composed of a plurality of sensors. For example, the sensor unit 338 includes a sensor for measuring temperature, humidity, and atmospheric pressure, and a sensor for measuring oxygen concentration.

In the present embodiment, the low oxygen air generation equipment 352 supplies the low oxygen air to the low oxygen chamber 112. The low oxygen air generation facility 352 uses, for example, the compressed air generated by the compressed air generation facility 356 to generate air having an adjusted oxygen concentration. In one embodiment, the hypoxic air generation facility 352 produces hypoxic air. In another embodiment, it produces air having a higher oxygen concentration than the oxygen concentration in the atmosphere (sometimes referred to as high oxygen air).

The hypoxic air generation equipment 352 may adjust at least one of the supply amount and the oxygen concentration of the hypoxic air based on the instruction of the control device 360. The low oxygen air generation equipment 352 may switch ON / OFF of the low oxygen air generation equipment 352 based on the instruction of the control device 360. The hypoxic air generation equipment 352 may transmit information indicating the state of the hypoxic air generation equipment 352 to the control device 360.

In the present embodiment, the pipe 354 connects the low oxygen air generation equipment 352 and the air supply port 305. The pipe 354 supplies, for example, the low oxygen air generated by the low oxygen air generation facility 352 to the air supply port 305.

In the present embodiment, the compressed air generation facility 356 generates compressed air. The compressed air generation facility 356 supplies the generated compressed air to the low oxygen air generation facility 352. The compressed air generation equipment 356 may adjust the supply amount of the compressed air based on the instruction of the control device 360. The compressed air generation equipment 356 may be switched ON / OFF based on the instruction of the control device 360. The compressed air generation equipment 356 may transmit information indicating the state of the compressed air generation equipment 356 to the control device 360.

[Overview of control device 360]
In this embodiment, the control device 360 controls the operation of the hypoxic training unit 100. The control device 360 may manage the usage status of the hypoxic training unit 100. Specific information processing in the control device 360 will be described later. The control device 360 can send and receive information to and from each part of the hypoxia training unit 100 via a communication network (not shown).

In the present embodiment, the communication network may be a transmission line for wired communication, a transmission line for wireless communication, or a combination of a transmission line for wireless communication and a transmission line for wired communication. The communication network may include a wireless packet communication network, the Internet, a P2P network, a dedicated line, a VPN, a power line communication line, and the like. The communication network may include (i) a mobile communication network such as a mobile phone network, (ii) wireless MAN (eg, WiMAX®), wireless LAN (eg, WiFi®). ), Bluetooth®, Zigbee®, NFC (Near Field Communication) and other wireless communication networks may be included.

[Specific configuration of each part of the control device 360]
Each part of the control device 360 may be realized by hardware, may be realized by software, or may be realized by hardware and software. At least a part of each part of the control device 360 may be realized by a single server or may be realized by a plurality of servers. At least a part of each part of the control device 360 may be realized on a virtual server or a cloud system. At least a part of each part of the control device 360 may be realized by a personal computer or a mobile terminal. Examples of the mobile terminal include a mobile phone, a smartphone, a PDA, a tablet, a notebook computer or a laptop computer, a wearable computer, and the like. The control device 360 may store information by using a distributed ledger technology such as a blockchain or a distributed network.

When at least a part of the components constituting the control device 360 is realized by software, the components realized by the software define the operation related to the components in the information processing device having a general configuration. It may be realized by invoking software or a program. The above-mentioned information processing devices include (i) a data processing device having a processor such as a CPU and GPU, a ROM, a RAM, and a communication interface, and (ii) a keyboard, a touch panel, a camera, a microphone, various sensors, a GPS receiver, and the like. An input device, an output device such as (iii) display device, speaker, and vibration device, and a storage device (including an external storage device) such as (iv) memory and HDD may be provided.

In the information processing device, the data processing device or the storage device may store the software or the program. The software or program is executed by the processor to cause the information processing apparatus to execute the operation specified by the software or program. The above software or program may be stored on a non-temporary computer-readable recording medium. The above software or program may be a program for causing the computer to function as a control device 360.

In this embodiment, the operating terminal 362 provides a user interface for the control device 360. Examples of the operation terminal 362 include a personal computer and a mobile terminal. Examples of the mobile terminal include a mobile phone, a smartphone, a PDA, a tablet, a notebook computer or a laptop computer, a wearable computer, and the like.

In the present embodiment, the oxygen concentration in the air inside the low oxygen chamber 112 in which the tread mill 310 is installed is higher than the oxygen concentration in the air outside the low oxygen chamber 112 or the oxygen concentration in the atmosphere. The case of small size was explained. However, the oxygen concentration in the room where the treadmill 310 is installed is not limited to this embodiment. In another embodiment, the oxygen concentration in the air inside the room in which the treadmill 310 is installed may be higher than the oxygen concentration in the air outside the room or the oxygen concentration in the atmosphere.

An example of the control device 360 will be described with reference to FIGS. 6 and 7. FIG. 6 schematically shows an example of the system configuration of the hypoxic training unit 100. FIG. 7 schematically shows an example of the system configuration of the control device 360.

In the present embodiment, the treadmill 310 includes an operation panel 312, a controller 612, a drive unit 614, and an inclination adjusting unit 616. In this embodiment, the controller 612 controls the operation of each part of the treadmill 310. The controller 612 may control each part of the treadmill 310 based on the instruction from the control device 360. In this embodiment, the drive unit 614 drives the treadmill 310. The drive unit 614 may be a motor that drives a belt on which the user travels. In the present embodiment, the inclination adjusting unit 616 adjusts the inclination of the treadmill 310.

In the present embodiment, the sensor unit 338 includes an oxygen concentration meter 622, a temperature sensor 624, and a humidity sensor 626. The oxygen concentration meter 622 measures the oxygen concentration of the air in the hypoxic chamber 112. In one embodiment, the oxygen concentration meter 622 outputs a value obtained by correcting the measured value of the oxygen concentration based on the humidity in the room. In another embodiment, the oxygen concentration meter 622 outputs the measured value of the oxygen concentration. In this case, the sensor unit 338 or the control device 360 may correct the oxygen concentration value. The control device 360 may execute various controls based on the measured value of the oxygen concentration measured by the oxygen concentration meter 622.

The temperature sensor 624 measures the temperature of the air in the hypoxic chamber 112. The humidity sensor 626 measures the humidity of the air in the hypoxic chamber 112. The sensor unit 338 is not limited to this embodiment. In another embodiment, the sensor unit 338 may have a barometric pressure sensor (not shown) for measuring the pressure of air in the hypoxic chamber 112.

In the present embodiment, the control device 360 includes a control unit 710, a schedule management unit 720, and a storage unit 730. In the present embodiment, the control unit 710 includes an input / output control unit 712, a treadmill control unit 714, an audiovisual information control unit 716, and an indoor environment control unit 718. In the present embodiment, the storage unit 730 includes a course information storage unit 732, a training condition storage unit 734, a training history storage unit 736, a schedule information storage unit 742, and an environmental control information storage unit 744.

The input / output control unit 712 may be an example of a vital data acquisition unit. The treadmill control unit 714 may be an example of a training device control unit. The audiovisual information control unit 716 may be an example of a display control unit. The indoor environment control unit 718 may be an example of a ventilation control unit, an air conditioning control unit, or an oxygen concentration control unit.

In the present embodiment, the control unit 710 controls the operation of each unit of the hypoxia training unit 100. In the present embodiment, the input / output control unit 712 controls the input / output between the control device 360 and each unit of the hypoxia training unit 100. The input / output control unit 712 acquires information on the state of each part of the hypoxia training unit 100 from each part of the hypoxia training unit 100.

For example, the input / output control unit 712 acquires vital data from the vital sensor 318. The input / output control unit 712 may acquire measurement data from the sensor unit 338. The input / output control unit 712 may acquire information regarding the instruction or input of the user or the administrator from the input unit of the control device 360. The input / output control unit 712 may acquire information regarding a user's instruction or input from the operation terminal 362.

The input / output control unit 712 may transmit information indicating the state of each part of the hypoxia training unit 100 to the output unit of the control device 360 and have the user or the administrator present the information. The input / output control unit 712 transmits information indicating the state of the user during training (for example, vital data acquired by the vital sensor 318) to the output unit of the control device 360, and manages the information by the user. You may let the person present it. The input / output control unit 712 may transmit information indicating the state of each part of the hypoxia training unit 100 to the operation terminal 362 and have the user present the information to the user existing inside the hypoxia chamber 112. The input / output control unit 712 transmits information indicating the state of the user during training (for example, vital data acquired by the vital sensor 318) to the operation terminal 362, and transmits the information to the inside of the low oxygen chamber 112. It may be presented to a user who exists in.

In this embodiment, the treadmill control unit 714 controls the treadmill 310. In one embodiment, the treadmill control unit 714 controls the treadmill 310 based on an instruction from the user received by the input / output control unit 712. For example, the treadmill control unit 714 controls the treadmill 310 based on the training conditions stored in the training condition storage unit 734.

In another embodiment, the treadmill control unit 714 controls the treadmill 310 based on the vital data acquired by the input / output control unit 712 from the vital sensor 318. For example, the treadmill control unit 714 reduces the load on the user when the blood oxygen concentration of the user becomes smaller than a predetermined value. As a method for reducing the load on the user, a method such as slowing down the traveling speed of the treadmill 310 or loosening the inclination of the treadmill 310 can be exemplified.

In still another embodiment, the treadmill control unit 714 analyzes the image of the user captured by the image pickup apparatus and determines the state of the user. For example, the treadmill control unit 714 analyzes the user's image captured by the imaging device and determines the user's state based on the user's facial expression, the user's posture, the user's body shaking, and the like. The treadmill control unit 714 may analyze the infrared image of the user captured by the imaging device and determine the state of the user based on the body temperature of the user or the temperature of a specific part of the body of the user. The treadmill control unit 714 may control the treadmill 310 and adjust the load of the user based on the determination result regarding the state of the user.

In the present embodiment, the treadmill control unit 714 controls the safety equipment 316 based on the vital data acquired from the vital sensor 318 by the input / output control unit 712. For example, when the blood oxygen concentration of the user becomes smaller than a predetermined value, the tension of the lifeline is increased to reduce the load on the user. In another embodiment, the treadmill control unit 714 analyzes the image of the user captured by the image pickup apparatus and determines the state of the user. The treadmill control unit 714 may control the safety equipment 316 and adjust the load of the user based on the determination result regarding the state of the user.

In the present embodiment, the audiovisual information control unit 716 controls the display equipment 322. For example, the audiovisual information control unit 716 controls the image to be displayed on the display equipment 322. The audiovisual information control unit 716 may control the image to be displayed on the display equipment 322 according to the load of the treadmill 310 or the history of the load. For example, the image displayed on the display equipment 322 is controlled so that the image at an appropriate position is displayed according to the traveling speed or the traveling distance of the user.

The audiovisual information control unit 716 may display the training conditions on the display equipment 322. The audiovisual information control unit 716 may cause the display equipment 322 to display information on the progress of training. The audiovisual information control unit 716 may display vital data on the display equipment 322. The audiovisual information control unit 716 may cause the display equipment 322 to display the image of the user or another user.

In the present embodiment, the audiovisual information control unit 716 may control the lighting equipment 326. The audiovisual information control unit 716 may control at least one of the color and brightness of the illumination of the lighting equipment 326 according to the load of the treadmill 310 or the history of the load. For example, the lighting equipment 326 is controlled so that an appropriate lighting effect can be obtained according to the traveling speed or the traveling distance of the user.

In the present embodiment, the indoor environment control unit 718 controls at least one of the temperature control equipment 332, the humidity control equipment 334, the blower equipment 336, the low oxygen air generation equipment 352, and the compressed air generation equipment 356, and controls the low oxygen chamber. Adjust the indoor environment of 112. In one embodiment, the indoor environment control unit 718 adjusts the indoor environment of the low oxygen chamber 112 based on the instruction from the user received by the input / output control unit 712. In another embodiment, the indoor environment control unit 718 adjusts the indoor environment of the hypoxic chamber 112 based on the training conditions stored in the training condition storage unit 734. In yet another embodiment, the indoor environment of the hypoxic chamber 112 is adjusted according to the load history of the treadmill 310. As a result, the indoor environment control unit 718 can reproduce how the weather conditions change as the vehicle travels.

For example, the indoor environment control unit 718 controls the temperature control equipment 332 to adjust the temperature of the air in the room of the low oxygen chamber 112. The indoor environment control unit 718 controls the humidity control equipment 334 to adjust the humidity of the air in the room of the low oxygen chamber 112. This makes it possible to reproduce arbitrary weather conditions.

The indoor environment control unit 718 may control the ventilation equipment 336 to adjust the air volume and the wind direction of the wind that hits the user. Thereby, a head wind or a tail wind can be reproduced. In one embodiment, when there is only one blower equipment 336, the indoor environment control unit 718 reproduces a head wind or a tail wind by controlling the rotation direction of the blades of the blower equipment 336. In another embodiment, when there are a plurality of blower equipment 336s, the indoor environment control unit 718 sets at least one of (i) ON / OFF, (ii) air volume and (iii) wind direction of each of the blower equipment 336s. By controlling, a headwind or a tailwind is reproduced.

The indoor environment control unit 718 may control the blower equipment 336 so that the blower equipment 336 blows an amount of air according to the load of the treadmill 310 or the history of the load. For example, the indoor environment control unit 718 controls the blower equipment 336 so that the air volume or speed of the wind blowing from the front of the user toward the user increases as the traveling speed of the treadmill 310 increases. This makes it possible to reproduce the headwind that accompanies the running.

The indoor environment control unit 718 may control at least one of the low oxygen air generation facility 352 and the compressed air generation facility 356 to adjust the oxygen concentration of the air in the room of the low oxygen chamber 112. For example, the indoor environment control unit 718 may control the supply amount and oxygen concentration of the low oxygen air generated by the low oxygen air generation equipment 352.

In one embodiment, the indoor environment control unit 718 controls the supply amount and oxygen concentration of the low oxygen air generated by the low oxygen air generation facility 352 based on the instruction from the user received by the input / output control unit 712. In another embodiment, the indoor environment control unit 718 controls the supply amount and oxygen concentration of the low oxygen air generated by the low oxygen air generation facility 352 based on the training conditions stored in the training condition storage unit 734.

In still another embodiment, the indoor environment control unit 718 determines the supply amount and oxygen concentration of the low oxygen air generated by the low oxygen air generation facility 352 based on the vital data acquired by the input / output control unit 712 from the vital sensor 318. You may control it. For example, when the oxygen concentration in the blood of the user becomes smaller than a predetermined value, the supply amount and oxygen concentration of the hypoxic air generated by the hypoxic air generation facility 352 may be increased.

The indoor environment control unit 718 may control at least one of the low oxygen air generation equipment 352 and the compressed air generation equipment 356 according to the usage status of the low oxygen training unit 100 managed by the schedule management unit 720. As a result, the user can adjust the oxygen concentration of the air in the hypoxia chamber 112 to a value desired by the user at the time when the hypoxia training unit 100 is used.

In the present embodiment, the schedule management unit 720 manages the usage status of the hypoxia training unit 100. The usage status may include information on the time when the hypoxia training unit 100 is used and the environment of the hypoxia chamber 112 at that time. As the information on the environment of the hypoxic chamber 112, information on temperature, humidity, atmospheric pressure, indoor oxygen concentration and lighting can be exemplified. The usage status may include information about the time and position at which the hypoxia training unit 100 is used, and the environment of the hypoxia chamber 112 at that time.

For example, a user who wishes to use the hypoxia training unit 100 can use the desired time of use and information on the desired environment (with reservation information) via a website for reserving the hypoxia training unit 100, an application program, or the like. (Sometimes referred to as) is transmitted to the schedule management unit 720. When the schedule management unit 720 receives the above reservation information, the schedule management unit 720 determines whether or not the reservation is possible by referring to the information regarding the usage schedule of the hypoxia training unit 100 stored in the schedule information storage unit 742. When the reservation is possible, the schedule management unit 720 stores the received reservation information in the schedule information storage unit 742. If the reservation is not possible, the schedule management unit 720 notifies the user to that effect.

In the present embodiment, the storage unit 730 stores various types of information. The course information storage unit 732 stores information about the running course. For example, the course information storage unit 732 stores images at each position of the traveling course. The course information storage unit 732 may store inclination information at each position of the traveling course. The course information storage unit 732 may store weather information at each position of the traveling course.

In one embodiment, the course information storage unit 732 includes position information of a plurality of positions on the running course and information indicating an image of the traveling course at each position (for example, information indicating a frame position of the image). And are stored in association with each other. In another embodiment, the course information storage unit 732 includes position information of a plurality of positions on the running course, information indicating an image of the running course at each position, and at least one of inclination information and weather information at each position. And are stored in association with each other. In still another embodiment, the course information storage unit 732 stores the position information of a plurality of arbitrary positions on the traveling course, the inclination information at each position, and the weather information at each position in association with each other. The position information of each position may be latitude / longitude information.

The training condition storage unit 734 stores the setting conditions related to training. Examples of the above setting conditions include a running course, a running plan, and training conditions. As the training conditions, conditions related to the training load, the target value of vital data, the indoor environment of the hypoxic chamber 112, and the like can be exemplified. The training conditions are (i) the time since the start of the trail and at least one of the positions on the running course, and (ii) the training load, the target value of vital data, and the room of the hypoxic chamber 112. The information may be associated with conditions related to the environment and the like. The conditions relating to the indoor environment of the hypoxic chamber 112 may be meteorological conditions to be reproduced. The above setting conditions may be stored in association with the position information on the running course and the information regarding at least one of the video and the training conditions at the position.

The training history storage unit 736 stores information related to the training history. The training history storage unit 736 may store information on the training history for each user. The schedule information storage unit 742 stores information regarding the usage schedule of the hypoxia training unit 100. The environmental control information storage unit 744 stores control information for the indoor environment control unit 718 to adjust the indoor environment of the hypoxic chamber 112. As the control information, information on the amount of feedback, parameter values of the PID controller, and the like can be exemplified.

Although the present invention has been described above using the embodiments, the technical scope of the present invention is not limited to the scope described in the above embodiments. It will be apparent to those skilled in the art that various changes or improvements can be made to the above embodiments. Further, to the extent that there is no technical contradiction, the matters described for the specific embodiment can be applied to other embodiments. It is clear from the description of the claims that such modified or improved forms may also be included in the technical scope of the present invention.

The order of execution of operations, procedures, steps, steps, etc. in the devices, systems, programs, and methods shown in the claims, specification, and drawings is particularly "before" and "prior to". It should be noted that it can be realized in any order unless the output of the previous process is used in the subsequent process. Even if the scope of claims, the specification, and the operation flow in the drawings are explained using "first", "next", etc. for convenience, it means that it is essential to carry out in this order. It's not a thing.

In the specification of the present application, for example, the following items are described.
[Item A]
With one or more transportable enclosures
An environment adjustment room that is arranged inside one or more housings, has a space for accommodating animals, and adjusts the environment of the space.
An environment adjustment unit that is arranged inside one or more housings and adjusts the environment of the environment adjustment room.
An environment simulation device equipped with.
[Item B]
Containers or prefabricated buildings that can be transported by vehicle,
An environment adjustment room that is arranged inside a container or prefabricated building, has a space for accommodating humans, and adjusts the environment of the space.
A regulated air supply unit that is located inside a container or prefabricated building and supplies regulated air to the environmental conditioning room.
Training equipment located inside the environmental adjustment room,
A display unit that is located inside the environment adjustment room and displays images,
A display control unit that controls the image to be displayed on the display unit according to the load or load history of the training equipment.
(I) The machine room where the adjustment air supply unit is arranged and (ii) the first partition member that partitions the environment adjustment room,
(I) A control room in which a display control unit is arranged, and (ii) a second partition member for partitioning an environment adjustment room.
An environment simulation device equipped with.

100 low oxygen training unit, 110 container, 112 low oxygen room, 114 machine room, 116 control room, 120 chassis, 122 chassis frame, 124 wheels, 126 coupling device, 128 auxiliary legs, 130 fixtures, 210 main body, 220 doors, 234 Duct, 236 duct, 240 opening, 302 distribution board, 304 wall, 305 air supply port, 306 wall, 307 observation window, 310 tread mill, 312 operation panel, 314 tilting table, 316 safety equipment, 318 vital sensor, 322 Display equipment, 324 fixing parts, 326 lighting equipment, 332 temperature control equipment, 334 humidity control equipment, 336 blower equipment, 338 sensor units, 352 low oxygen air generation equipment, 354 piping, 356 compressed air generation equipment, 360 control equipment, 362 Operation terminal, 408 exhaust port, 420 door, 422 door, 612 controller, 614 drive unit, 616 tilt adjustment unit, 622 oxygen concentration meter, 624 temperature sensor, 626 humidity sensor, 710 control unit, 712 input / output control unit, 714 Red mill control unit, 716 audiovisual information control unit, 718 indoor environment control unit, 720 schedule management unit, 730 storage unit, 732 course information storage unit, 734 training condition storage unit, 736 training history storage unit, 742 schedule information storage unit, 744 Environmental control information storage unit

Claims (15)

With one or more transportable enclosures
A hypoxic chamber arranged inside the one or more housings, having a space for accommodating animals, and adjusting the oxygen concentration in the space.
A hypoxic air supply unit that is arranged inside the one or more housings and supplies hypoxic air to the hypoxic chamber.
The training equipment arranged inside the hypoxic chamber and
A vital data acquisition unit that acquires vital data including measurement results of blood oxygen concentration of the user of the training device, and a vital data acquisition unit.
A training device control unit that controls the load that the training device gives to the user based on the blood oxygen concentration of the user of the training device acquired by the vital data acquisition unit.
With
The hypoxic air supply unit generates the hypoxic air and supplies the generated hypoxic air to the hypoxic chamber.
In the hypoxic chamber
An air supply port that sends the low oxygen air supplied by the low oxygen air supply unit into the inside of the low oxygen chamber, and
An exhaust port that exhausts the air inside the hypoxic chamber to the outside of the hypoxic chamber, and
Is formed,
The air supply port is arranged at a position higher than the exhaust port.
Environment simulation device. The pressure loss of the exhaust port is larger than the pressure loss of the air supply port.
The environment simulation device according to claim 1. With one or more transportable enclosures
A hypoxic chamber arranged inside the one or more housings, having a space for accommodating animals, and adjusting the oxygen concentration in the space.
A hypoxic air supply unit that is arranged inside the one or more housings and supplies hypoxic air to the hypoxic chamber.
Training equipment located inside the hypoxic chamber (excluding differential pneumatic systems that utilize changes in air pressure to provide positive or negative weight support for training and rehabilitation systems and programs).
A lifeline for ensuring the safety of users of the training equipment,
A vital data acquisition unit that acquires vital data of users using the training equipment, and
On the basis of vital before data acquisition unit has acquired the vital data of cut for business, and a tension adjusting unit for adjusting the tension of the lifeline,
An environment simulation device equipped with. The vital data include information on blood oxygen levels.
The tension adjusting unit increases the tension of the lifeline when the blood oxygen concentration of the user becomes smaller than a predetermined value.
The environment simulation device according to claim 3. Based on the vital data of a user of the training device before Symbol vital data acquisition unit has acquired, further comprising a training device control unit for controlling the training equipment,
The environment simulation device according to claim 3 or 4. A display unit that displays images and
A display control unit that controls an image to be displayed on the display unit according to the load or load history of the training device.
Further prepare,
Environmental simulation device according to any one of claims 1 to 5. A blower that blows air toward the training equipment,
A blower control unit that controls the blower so that the blower blows an amount of air according to the load or load history of the training device.
Further prepare,
Environmental simulation device according to any one of claims 1 to 6. The low oxygen chamber and the low oxygen air supply unit are arranged inside the same housing.
The environment simulation device according to any one of claims 1 to 7. A first partition member for partitioning the machine room in which the low oxygen air supply unit is arranged and the low oxygen chamber is further provided.
The environment simulation device according to claim 8. An air conditioner that adjusts at least one of the temperature and humidity inside the low oxygen chamber,
An air conditioning control unit that controls the air conditioning unit and
Further prepare,
The environment simulation device according to any one of claims 1 to 9. An oxygen concentration control unit for controlling the low oxygen air supply unit is further provided.
The environment simulation device according to any one of claims 1 to 10. It is further equipped with a usage status management unit that manages the usage status of the environment simulation device.
The usage status includes information on the time when the environment simulation device is used and the oxygen concentration inside the hypoxic chamber at that time.
The oxygen concentration control unit controls the low oxygen air supply unit based on the usage status.
The environment simulation device according to claim 11. Each of the one or more housings is a container or prefabricated building that can be transported by vehicle, ship or aircraft.
The environment simulation device according to any one of claims 1 to 12. A chassis for loading at least one of the one or a plurality of housings and a chassis having wheels arranged on the chassis is further provided.
The environment simulation device according to any one of claims 1 to 13. Containers or prefabricated buildings that can be transported by vehicle,
A hypoxic chamber that is arranged inside the container or prefabricated building, has a space for accommodating humans, and the oxygen concentration of the space is adjusted.
A hypoxic air supply unit that is arranged inside the container or prefabricated building and supplies hypoxic air to the hypoxic chamber.
The training equipment arranged inside the hypoxic chamber and
A display unit that is arranged inside the hypoxic chamber and displays images,
A display control unit that controls an image to be displayed on the display unit according to the load or load history of the training device.
A vital data acquisition unit that acquires vital data including measurement results of blood oxygen concentration of the user of the training device, and a vital data acquisition unit.
A training device control unit that controls the load that the training device gives to the user based on the blood oxygen concentration of the user of the training device acquired by the vital data acquisition unit.
(I) A machine room in which the low oxygen air supply unit is arranged, and (ii) a first partition member for partitioning the low oxygen room.
(I) A control chamber in which the display control unit is arranged, and (ii) a second partition member that separates the hypoxic chamber.
With
The hypoxic air supply unit generates the hypoxic air and supplies the generated hypoxic air to the hypoxic chamber.
In the hypoxic chamber
An air supply port that sends the low oxygen air supplied by the low oxygen air supply unit into the inside of the low oxygen chamber, and
An exhaust port that exhausts the air inside the hypoxic chamber to the outside of the hypoxic chamber, and
Is formed,
The air supply port is arranged at a position higher than the exhaust port.
Environment simulation device.

Images