JP6860127B2 - Oxygen room - Google Patents

Description

The present invention relates to an oxygen chamber.

Conventionally, there is known an oxygen chamber that controls the atmospheric pressure to be higher than the standard atmospheric pressure and the atmospheric pressure to be lower than the standard atmospheric pressure (for example, Patent Document 1). In such an oxygen room, by setting the atmospheric pressure inside the accommodating portion in which the user is accommodated to be higher than the standard atmospheric pressure, effects on the health and beauty of the user can be expected. On the other hand, by setting the atmospheric pressure inside the accommodating section to be lower than the standard atmospheric pressure, it can be used as a training room assuming high altitude training.

Japanese Unexamined Patent Publication No. 2003-210637

However, such an oxygen chamber is likely to fail. If the oxygen chamber fails, the air pressure inside the accommodating portion may become too high or too low than the set air pressure. For example, if the air pressure inside the accommodating portion becomes too low, there is a risk of endangering the life of the user.

In view of these problems, an object of the present invention is to provide an oxygen room capable of ensuring the safety of the user.

In order to solve such a problem, the oxygen chamber according to the present invention has a metal accommodating portion capable of accommodating a user inside, an opening formed in the accommodating portion, and the inside of the accommodating portion. Measured by a low-pressure control unit that controls the atmospheric pressure to be lower than the standard atmospheric pressure, a door unit that can close the opening, a measuring unit that measures the atmospheric pressure inside the accommodating unit, and the measuring unit. The determination unit for determining whether or not the air pressure inside the accommodating portion has reached a predetermined threshold, and the determination unit have determined that the air pressure inside the accommodating portion has reached the predetermined threshold. In this case, the warning unit that gives a warning, the inner oxygen discharge valve that restores the air pressure inside the accommodation unit to the standard atmospheric pressure when operated by the user from the inside of the accommodation unit, and the determination unit. When it is determined that the atmospheric pressure inside the accommodating portion has reached the predetermined threshold value, the low pressure is provided with a repressurizing control unit that controls the atmospheric pressure inside the accommodating portion to be restored to the standard atmospheric pressure. The control unit controls the atmospheric pressure by opening and closing a plurality of on-off valves, and the recompression control unit controls the on-off valves when the predetermined threshold is reached, thereby controlling the accommodating unit. An oxygen chamber characterized in that the air pressure inside the air pressure is restored to the standard air pressure.

Further, in the oxygen chamber according to the present invention, the air pressure inside the metal accommodating portion capable of accommodating the user, the opening formed in the accommodating portion, and the internal air pressure of the accommodating portion is compared with the standard air pressure. A high-pressure control unit that controls the air pressure to be high, a door unit that can close the opening, a measuring unit that measures the air pressure inside the housing unit, and the inside of the housing unit that is measured by the measuring unit. A determination unit that determines whether or not the air pressure has reached a predetermined threshold, and a warning unit that warns when the determination unit determines that the air pressure inside the accommodating unit has reached the predetermined threshold. When operated by the user from the inside of the accommodating portion, the internal oxygen discharge valve that restores the air pressure inside the accommodating portion to the standard atmospheric pressure and the determination unit can reduce the air pressure inside the accommodating portion. When it is determined that the predetermined threshold value has been reached, the high pressure control unit includes a pressure recovery control unit that controls the pressure inside the housing unit to be restored to the standard air pressure, and the high pressure control unit has a plurality of on-off valves. The atmospheric pressure is controlled by opening and closing the air pressure, and when the pressure recovery control unit reaches the predetermined threshold value, the air pressure inside the accommodating unit is adjusted to the standard atmospheric pressure by controlling the on-off valve. An oxygen room characterized by re-atmospheric pressure.

According to the present invention, it is possible to provide an oxygen room capable of ensuring the safety of the user.

It is a figure which shows an example of the external perspective view of an oxygen room. It is a figure which shows an example of the cross-sectional view of the internal structure of the accommodation part of an oxygen room. It is a figure which shows an example of the block diagram of an oxygen room. It is a figure which shows an example of the processing in the atmospheric pressure control part. It is a figure which shows an example of an interrupt process. It is a figure which shows an example of the graph which shows the transition of the atmospheric pressure from the pressure drop to the return pressure. It is a figure which shows an example of the graph which shows the transition of the atmospheric pressure at the time of a step-down failure. It is a figure which shows an example of the graph which shows the transition of the atmospheric pressure from the boosting to the recovery pressure. It is a figure which shows an example of the graph which shows the transition of the atmospheric pressure at the time of a boost failure. It is a figure which shows an example of the display mode of the warning device at the time of a step-down failure. It is a figure which shows an example of the display mode of the warning device at the time of a boost failure.

Hereinafter, embodiments of the present invention will be specifically described with reference to the drawings.

(Exterior perspective view of oxygen room 1)
First, the configuration of the oxygen chamber 1 in the present invention will be specifically described with reference to FIGS. 1 and 2. FIG. 1 is an external perspective view of the oxygen chamber 1 in a state where the opening 3 is open. Further, FIG. 2 is a cross-sectional view showing the internal structure of the accommodating portion 2 of the oxygen chamber.

(Oxygen room 1)
The oxygen chamber 1 in the present invention is composed of an accommodating unit 2, an atmospheric pressure control unit 6, and a concentrated oxygen device 7.

(Accommodation part 2)
The accommodating portion 2 includes a plate-shaped bottom plate provided on the bottom surface of the accommodating portion 2, a plate-shaped left side plate provided on the front left surface of the accommodating portion 2, and a front-view right side surface of the accommodating portion 2. The plate-shaped right side plate provided in, the plate-shaped front plate provided on the front side of the accommodating portion 2, the plate-shaped back plate provided on the back side of the accommodating portion 2, and the accommodating portion. It is composed of a plate-shaped ceiling plate provided on the ceiling side of No. 2, and is formed in a box shape by being joined by welding, screwing, or the like. Further, the accommodating unit 2 has an internal space capable of accommodating a user who uses the oxygen room 1.

Further, the material of the accommodating portion 2 is made of metal having excellent strength (for example, steel or iron). As a result, the pressure resistance and impact resistance of the accommodating portion 2 are improved, so that the safety of the user inside the accommodating portion 2 is improved. The material of the accommodating portion 2 may be any material as long as it has excellent strength.

Here, in the present embodiment, the ceiling plate is provided with metal ceiling plate reinforcing columns for reinforcing the ceiling plate in a grid pattern. As a result, for example, even when the reinforcing bar or the steel frame structure collides from above due to an earthquake or the like, the reinforcing bar or the steel frame structure collides with the ceiling plate reinforcing column before colliding with the ceiling plate. The safety of the oxygen room 1 is improved. The ceiling plate reinforcing columns are connected to the ceiling plate by welding, screwing, or the like.

Similarly, the front plate is provided with metal front plate reinforcing columns for reinforcing the front plate in a grid pattern, and the bottom plate is provided with metal bottom plate reinforcing columns for reinforcing the bottom plate. Are provided in a grid pattern.

Further, in the present embodiment, the right side plate is provided with a metal right side plate reinforcing column for reinforcing the right side plate. As a result, for example, even when the reinforcing bar or the steel frame structure collides from the right side due to an earthquake or the like, the reinforcing bar or the steel frame structure collides with the right side plate reinforcing column before colliding with the right side plate. The safety of the oxygen room 1 is improved. The right side plate reinforcing column is connected to the right side plate by welding, screwing, or the like.

Similarly, the left side plate is provided with a metal left side plate reinforcing column for reinforcing the left side plate, and the back plate is provided with a metal back plate reinforcing column for reinforcing the back plate. ing.

The ceiling plate reinforcing column, the front plate reinforcing column, the bottom plate reinforcing column, the right side plate reinforcing column, the left side plate reinforcing column, and the back plate reinforcing column are collectively referred to as "reinforcing columns".

Here, in the present embodiment, the accommodating portion 2 has a size of about 120 cm in depth (D), 260 cm in width (W), and 150 cm in height (H), and has a plurality of users of the oxygen room 1. Although it is possible to accommodate a person, the size of the accommodating portion 2 may be any size as long as it can accommodate at least one user.

(Opening 3)
The opening 3 is provided on the front plate of the accommodating portion 2, and is formed in a size that allows the user of the oxygen room 1 to enter and exit the inside of the accommodating portion 2. Here, the size of the opening 3 may be any size as long as the user can enter and exit. Further, the position where the opening 3 is provided may be provided at a position other than the front plate. For example, the opening 3 may be provided in the left side plate, the right side plate, the back plate, or the ceiling plate.

(Door part 4)
The door portion 4 is provided on the front plate of the accommodating portion 2, and is provided so that the opening 3 can be opened and closed. Specifically, the door portion 4 has an inner door for pressurization that can be opened by moving in the internal direction of the accommodating portion 2 and an outer door for decompression that can be opened by moving in the outward direction of the accommodating portion 2. It is composed of and. Here, the size of the door portion 4 in the present embodiment is larger than that of the opening portion 3.

Further, the position where the door portion 4 is provided may be provided at a different position according to the position where the opening portion 3 is provided. In the present embodiment, the door portion 4 is a hinged door, but the door portion 4 is not limited to this, and may be, for example, a sliding door or a folding door.

(Window 5)
The window portion 5 is provided on the front plate of the accommodating portion 2, and is provided so that the inside of the accommodating portion 2 can be visually recognized from the outside of the accommodating portion 2. Further, by providing the window portion 5, it is possible to reduce the feeling of blockage of the user inside the accommodating portion 2. Here, the window portion 5 may be provided at a position other than the front plate (for example, the left side plate, the right side plate, the back plate), or a plurality of windows 5 may be provided. The size of the window portion 5 may be any size.

(Atmospheric pressure control unit 6)
The atmospheric pressure control unit 6 is connected to the accommodating unit 2 and the concentrated oxygen device 7, and is provided to control the air pressure inside the accommodating unit 2. The atmospheric pressure control unit 6 will be described in detail later with reference to FIG.

(Concentrated oxygen device 7)
The concentrated oxygen device 7 is connected to the atmospheric pressure control unit 6 and has a zeolite (not shown) for removing nitrogen and carbon dioxide in the air.

(Outer oxygen discharge valve 8)
The outer oxygen discharge valve 8 is provided on the front plate, and is provided to set the atmospheric pressure inside the accommodating portion 2 to the standard atmospheric pressure. Here, by operating the outer oxygen discharge valve 8 from the outside of the accommodating portion 2, the atmospheric pressure inside the accommodating portion 2 returns to the standard atmospheric pressure (“1.0” atmospheric pressure).

(Inner oxygen discharge valve 9)
The inner oxygen discharge valve 9 is provided on the front plate, and is provided for discharging oxygen inside the accommodating portion 2 like the outer oxygen discharge valve 8. Here, the user operates the inner oxygen discharge valve 9 from the inside of the accommodating portion 2, so that the air pressure inside the accommodating portion 2 returns to the standard atmospheric pressure.

(Oxygen concentration meter 17)
The oxygen concentration meter 17 is provided inside the accommodating portion 2, and is provided for measuring the oxygen concentration inside the accommodating portion 2. Although the oxygen concentration meter 17 is provided inside the accommodating portion 2, it may be provided anywhere as long as the oxygen concentration inside the accommodating portion 2 can be measured.

(Warning device 29)
The warning device 29 is provided inside the accommodating unit 2, and when the oxygen concentration inside the accommodating unit 2 reaches a predetermined threshold value, or when the air pressure inside the accommodating unit 2 reaches a predetermined threshold value. , Is provided to give a warning. Here, the warning device 29 in the present embodiment includes a liquid crystal display unit and a speaker, and a warning is given by a warning display and a warning sound.

(Block diagram of barometric pressure control unit 6)
Next, a block diagram of the atmospheric pressure control unit 6 will be described with reference to FIG.

The barometer control unit 6 includes a CPU 6a, a ROM 6b, a RAM 6c, a power key unit 10, a start button 11, an end button 12, a pause button 13, an emergency stop button 14, a touch panel 15, and a barometer 16. , The handset 18, the liquid crystal display device 19, the pressure on-off valve 20, the pressure reducing on-off valve 21, the atmospheric pressure on-off valve 22, the first on-off valve 23, the second on-off valve 24, and the third on-off valve 25. And a fourth on-off valve 26.

Further, the barometric pressure control unit 6 is connected to the concentrated oxygen device 7, the oxygen concentration meter 17, the pressurizing pump 27, the depressurizing pump 28, and the warning device 29.

(CPU6a)
The CPU 6a is provided to control the pressure pressure control unit 6, and by reading the program stored in the ROM 6b and performing a predetermined arithmetic process, the concentrated oxygen device 7, the handset 18, the pressurizing pump 27, and the like. A predetermined signal is transmitted to the decompression pump 28 and the warning device 29.

Further, the CPU 6a reads the program stored in the ROM 6b and performs a predetermined arithmetic process to perform the receiver 18, the liquid crystal display device 19, the pressurized on-off valve 20, the decompression on-off valve 21, the atmospheric opening valve 22, and the first. The on-off valve 23, the second on-off valve 24, the third on-off valve 25, and the fourth on-off valve 26 are controlled.

Further, the CPU 6a inputs a predetermined signal from the concentrated oxygen device 7, the power key unit 10, the start button 11, the end button 12, the pause button 13, the emergency stop button 14, the touch panel 15, the barometer 16, and the oxygen concentration meter 17. Then, processing is performed according to the input signal.

(ROM6b)
The ROM 6b is provided to store a control program executed by the CPU 6a, a data table, a concentrated oxygen device 7, a handset 18, a pressurizing pump 27, a depressurizing pump 28, data for transmitting a signal to the warning device 29, and the like. ing. Here, the ROM 6b stores the threshold value of the oxygen concentration, the threshold value at the time of pressurization, and the threshold value at the time of depressurization.

(RAM 6c)
The RAM 6c is provided to store various data determined by executing the program by the CPU 6a. Further, the RAM 6c is provided with a status storage area indicating the operating state of the atmospheric pressure control unit 6.

(Power key section 10)
The power key unit 10 is provided to detect an operation of supplying electric power to the atmospheric pressure control unit 6. Further, the power key unit 10 turns on the power by detecting an operation in which a key (not shown) is inserted and rotated in a predetermined direction. On the other hand, in a state where a key (not shown) is inserted and rotated in a predetermined direction, the power is turned off by detecting an operation of rotating in the direction opposite to the predetermined direction.

(Start button 11)
The start button 11 is provided to start step-up or step-down with respect to the set atmospheric pressure. Further, the start button 11 includes a start switch (not shown).

(End button 12)
The end button 12 is provided to detect an operation of ending the control of the air pressure inside the accommodating unit 2 while the air pressure control unit 6 is controlling the air pressure inside the accommodating unit 2. Further, the end button 12 includes an end switch (not shown).

(Pause button 13)
The pause button 13 is for detecting an operation of raising or lowering the internal air pressure of the accommodating unit 2 or pausing the air pressure reduction while the air pressure control unit 6 is increasing or decreasing the internal air pressure of the accommodating unit 2. It is provided in. Further, the pause button 13 includes a pause switch (not shown).

(Emergency stop button 14)
The emergency stop button 14 is provided to detect an operation of urgently stopping the control of the air pressure inside the accommodating unit 2 while the air pressure control unit 6 is controlling the air pressure inside the accommodating unit 2. Further, the emergency stop button 14 includes an emergency stop switch (not shown).

(Touch panel 15)
The touch panel 15 is provided on the front surface and / or the back surface of the liquid crystal display device 19, and is used for selecting the air pressure inside the accommodating unit 2 and selecting the operating time of the air pressure control unit 6. It is provided to detect an operation for selecting a step-up time, an operation for selecting a step-down time, and the like.

(Barometer 16)
The barometer 16 is provided to measure the atmospheric pressure inside the accommodating portion 2. Here, in the present embodiment, the barometer 16 is provided in the vicinity of the pressurizing on-off valve 20 and the depressurizing on-off valve 21, but may be at a position where the atmospheric pressure inside the accommodating portion 2 can be measured. If so, it may be provided anywhere. For example, it may be provided inside the accommodating portion 2.

(Handset 18)
The handset 18 is provided for communicating with a handset provided inside the accommodating portion 2.

(Liquid crystal display device 19)
The liquid crystal display device 19 is provided to display an initial screen, a mode selection screen, and the like.

(Pressurized on-off valve 20)
The pressurizing on-off valve 20 is opened when the pressurizing pump 27 is moved to increase the air pressure inside the accommodating portion 2, and when the depressurizing pump 28 is operated to reduce the air pressure inside the accommodating portion 2. Is blocked.

(Decompression on-off valve 21)
The pressure reducing on-off valve 21 is opened when the pressure reducing pump 28 is moved to lower the air pressure inside the accommodating portion 2, and when the pressure pump 27 is moved to increase the air pressure inside the accommodating unit 2. It is blocked.

(Atmospheric release valve 22)
The atmosphere release valve 22 is closed when the power is turned on, and is opened when the power is turned off or when the emergency stop button 14 is operated. Further, when the atmospheric release valve 22 is opened, the atmospheric pressure inside the accommodating portion 2 is restored to the standard atmospheric pressure.

(1st on-off valve 23)
The first on-off valve 23 is provided to correct the air pressure inside the accommodating portion 2 when controlling the step-up, the step-down, the pressure holding, and the pressure recovery.

(2nd on-off valve 24)
Like the first on-off valve 23, the second on-off valve 24 is provided to correct the air pressure inside the accommodating portion 2 when controlling the step-up, the step-down, the pressure holding, and the pressure recovery.

(Third on-off valve 25)
Similar to the first on-off valve 23 and the second on-off valve 24, the third on-off valve 25 is used to correct the air pressure inside the accommodating portion 2 when controlling the step-up, the step-down, the pressure holding, and the pressure recovery. It is provided in.

(4th on-off valve 26)
The fourth on-off valve 26, like the first on-off valve 23 to the third on-off valve 25, is used to correct the air pressure inside the accommodating portion 2 when controlling the step-up, the step-down, the pressure holding, and the pressure recovery. It is provided in.

(Pressurized pump 27)
The pressurizing pump 27 is provided to pressurize the air pressure inside the accommodating portion 2 when controlling the boosting and pressure holding.

(Decompression pump 28)
The pressure reducing pump 28 is provided to reduce the air pressure inside the accommodating portion 2 when controlling the pressure reduction and pressure holding.

(Processing in barometric pressure control unit 6)
Next, the process in the atmospheric pressure control unit 6 will be described with reference to FIG.

(Step S1)
In step S1, the CPU 6a performs a process of determining whether or not the power is turned on. Specifically, the CPU 6a performs a process of determining whether or not a key (not shown) is inserted into the power key unit 10 and an operation of rotating in a predetermined direction is detected. Then, when it is determined that the power is turned on (step S1 = YES), the process proceeds to step S2. On the other hand, if it is determined that the power is not turned on (step S1 = NO), the process of step S1 is repeatedly executed until the power is turned on.

(Step S2)
In step S2, the CPU 6a performs a power-on processing. Specifically, the CPU 6a performs a process of displaying the initial screen on the liquid crystal display device 19 and then a process of displaying the mode selection screen. Further, in the power-on processing, the CPU 6a performs a process of closing the atmosphere release valve 22 and a process of setting "1 (stop)" in the status storage area provided in the RAM 6c. Then, when the process of step S2 is completed, the process shifts to step S3.

(Step S3)
In step S3, the CPU 6a performs a process of determining whether or not the power is turned off. Specifically, the CPU 6a performs a process of determining whether or not a key (not shown) is inserted into the power key unit 10 and an operation of rotating in a direction opposite to a predetermined direction is detected. Then, when it is determined that the power is turned off (step S3 = YES), the process proceeds to step S4. On the other hand, if it is determined that the power supply is not turned off (step S3 = NO), the process proceeds to step S5.

(Step S4)
In step S4, the CPU 6a performs a power cutoff process. Specifically, the CPU 6a performs a process of opening the atmosphere release valve 22 and a process of setting "1 (stop)" in the status storage area provided in the RAM 6c. Then, when the process of step S4 is completed, the process shifts to step S1.

(Step S5)
In step S5, the CPU 6a performs a process of determining whether or not the status is "1 (stop)". Specifically, the CPU 6a performs a process of determining whether or not the value of the status storage area provided in the RAM 6c is "1 (stop)". Then, when it is determined that the status is "1 (stop)" (step S5 = YES), the process proceeds to step S6. On the other hand, if it is determined that the status is not "1 (stop)" (step S5 = NO), the process shifts to step S7.

(Step S6)
In step S6, the CPU 6a performs a stop processing. Specifically, in the state where the mode selection screen is displayed on the liquid crystal display device 19, the CPU 6a uses the touch panel 15 to select a pressure (atmospheric pressure), an operation time, a step-up time, and a step-down time. Performs processing to detect the operation to select. Further, when the pressure (atmospheric pressure), the operation time, and the boosting time are selected, the CPU 6a displays "2 (boost)" in the status storage area provided in the RAM 6c when the setting completion operation is detected. And the process of storing the set pressure (atmospheric pressure), operating time, and boosting time in the RAM 6c. Further, when the pressure (atmospheric pressure), the operation time, and the step-down time are selected, the CPU 6a sets "3 (step-down)" in the status storage area provided in the RAM 6c when the setting completion operation is detected. And the process of storing the set pressure (atmospheric pressure), operating time, and step-down time in the RAM 6c. Then, when the process of step S6 is completed, the process shifts to step S3.

(Step S7)
In step S7, the CPU 6a performs a process of determining whether or not the status is "2 (boost)". Specifically, the CPU 6a performs a process of determining whether or not the value of the status storage area provided in the RAM 6c is "2 (boost)". Then, when it is determined that the status is "2 (boost)" (step S7 = YES), the process shifts to step S8. On the other hand, if it is determined that the status is not "2 (boost)" (step S7 = NO), the process proceeds to step S9.

(Step S8)
In step S8, the CPU 6a performs the step-up processing. Specifically, the CPU 6a drives the pressurizing pump 27 to pressurize the air pressure inside the accommodating portion 2. Further, when the atmospheric pressure inside the accommodating portion 2 reaches the set pressure (atmospheric pressure), the CPU 6a performs a process of setting "4 (pressure holding)" in the status storage area provided in the RAM 6c. Further, when the operation of the end button 12 is detected, the CPU 6a performs a process at the time of the end button operation for setting "5 (recovery pressure)" in the status storage area provided in the RAM 6c, and temporarily performs the process. When the operation of the stop button 13 is detected, the temporary stop button operation process for maintaining the air pressure inside the accommodating unit 2 is performed, and when the operation of the emergency stop button 14 is detected, the atmosphere release valve 22 is performed. Is released, and "1 (stop)" is set in the status storage area provided in the RAM 6c. The emergency stop button operation process is performed, and when a setting change operation is detected, the RAM 6c is provided. Performs processing to set "6 (pressurization adjustment)" in the status storage area. Performs processing when a setting change operation is detected. Then, when the process of step S8 is completed, the process shifts to step S3.

(Step S9)
In step S9, the CPU 6a performs a process of determining whether or not the status is "3 (lowering)". Specifically, the CPU 6a performs a process of determining whether or not the value of the status storage area provided in the RAM 6c is "3 (lowering)". Then, when it is determined that the status is "3 (lowering)" (step S9 = YES), the process shifts to step S10. On the other hand, if it is determined that the status is not "3 (lowering)" (step S9 = NO), the process proceeds to step S11.

(Step S10)
In step S10, the CPU 6a performs a step-down process. Specifically, the CPU 6a drives the decompression pump 28 to reduce the air pressure inside the accommodating portion 2. Further, when the atmospheric pressure inside the accommodating portion 2 reaches the set pressure (atmospheric pressure), the CPU 6a performs a process of setting "4 (pressure holding)" in the status storage area provided in the RAM 6c. Further, when the operation of the end button 12 is detected, the CPU 6a performs a process at the time of the end button operation for setting "5 (recovery pressure)" in the status storage area provided in the RAM 6c, and temporarily performs the process. When the operation of the stop button 13 is detected, the temporary stop button operation process for maintaining the air pressure inside the accommodating unit 2 is performed, and when the operation of the emergency stop button 14 is detected, the atmosphere release valve 22 is performed. Is released, and "1 (stop)" is set in the status storage area provided in the RAM 6c. The emergency stop button operation process is performed, and when a setting change operation is detected, the RAM 6c is provided. Performs processing to set "7 (decompression adjustment)" in the status storage area. Performs processing when a setting change operation is detected. Then, when the process of step S10 is completed, the process shifts to step S3.

(Step S11)
In step S11, the CPU 6a performs a process of determining whether or not the status is "4 (pressure holding)". Specifically, the CPU 6a performs a process of determining whether or not the value of the status storage area provided in the RAM 6c is "4 (pressure holding)". Then, when it is determined that the status is "4 (pressure holding)" (step S11 = YES), the process proceeds to step S12. On the other hand, if it is determined that the status is not "4 (pressure holding)" (step S11 = NO), the process proceeds to step S13.

(Step S12)
In step S12, the CPU 6a performs the pressure holding process. Specifically, the CPU 6a performs a process of setting "5 (recovery)" in the status storage area provided in the RAM 6c when the set operation time has elapsed. Further, when the operation of the end button 12 is detected, the CPU 6a performs a process at the time of the end button operation for setting "5 (recovery pressure)" in the status storage area provided in the RAM 6c, and temporarily performs the process. When the operation of the stop button 13 is detected, the temporary stop button operation process for maintaining the air pressure inside the accommodating unit 2 is performed, and when the operation of the emergency stop button 14 is detected, the atmosphere release valve 22 is performed. Is released, and "1 (stop)" is set in the status storage area provided in the RAM 6c. The emergency stop button is operated, and the set atmospheric pressure is set when the atmospheric pressure is higher than the standard atmospheric pressure. When a change operation is detected, a process of setting "6 (pressurization adjustment)" in the status storage area provided in the RAM 6c is performed. A pressure setting change operation detection process is performed and the set atmospheric pressure is set. When is lower than the standard atmospheric pressure and a setting change operation is detected, a process of setting "7 (decompression adjustment)" in the status storage area provided in the RAM 6c is performed. I do. Then, when the process of step S12 is completed, the process shifts to step S3.

(Step S13)
In step S13, the CPU 6a performs a process of determining whether or not the status is "5 (recovery)". Specifically, the CPU 6a performs a process of determining whether or not the value of the status storage area provided in the RAM 6c is "5 (recovery)". Then, when it is determined that the status is "5 (recovery)" (step S13 = YES), the process shifts to step S14. On the other hand, if it is determined that the status is not "5 (recovery)" (step S13 = NO), the process proceeds to step S15.

(Step S14)
In step S14, the CPU 6a performs the repressurization process. Specifically, the CPU 6a stops the drive of the pressurizing pump 27 and the depressurizing pump 28, and opens and closes the first on-off valve 23 to the fourth on-off valve 26 to bring the air pressure inside the accommodating portion 2 to the standard atmospheric pressure. Performs decompression processing to return to. Further, when the decompression process is completed, the CPU 6a performs a process of setting "1 (stop)" in the status storage area provided in the RAM 6c. Then, when the process of step S14 is completed, the process shifts to step S3.

(Step S15)
In step S15, the CPU 6a performs a process of determining whether or not the status is "6 (pressurization adjustment)". Specifically, the CPU 6a performs a process of determining whether or not the value of the status storage area provided in the RAM 6c is "6 (pressurization adjustment)". Then, when it is determined that the status is "6 (pressurization adjustment)" (step S15 = YES), the process proceeds to step S16. On the other hand, if it is determined that the status is not "6 (pressurization adjustment)" (step S15 = NO), the process proceeds to step S17.

(Step S16)
In step S16, the CPU 6a performs the pressurization adjustment processing. Specifically, the CPU 6a is a process of setting "4 (pressure holding)" in the status storage area provided in the RAM 6c when the atmospheric pressure inside the accommodating portion 2 reaches the changed pressure (atmospheric pressure). I do. Further, when the operation of the end button 12 is detected, the CPU 6a performs a process at the time of the end button operation for setting "5 (recovery pressure)" in the status storage area provided in the RAM 6c, and temporarily performs the process. When the operation of the stop button 13 is detected, the temporary stop button operation process for maintaining the air pressure inside the accommodating unit 2 is performed, and when the operation of the emergency stop button 14 is detected, the atmosphere release valve 22 is performed. Is released, and "1 (stop)" is set in the status storage area provided in the RAM 6c. The emergency stop button operation process is performed. Then, when the process of step S16 is completed, the process shifts to step S3.

(Step S17)
In step S17, the CPU 6a performs a process of determining whether or not the status is "7 (decompression adjustment)". Specifically, the CPU 6a performs a process of determining whether or not the value of the status storage area provided in the RAM 6c is "7 (decompression adjustment)". Then, when it is determined that the status is "7 (decompression adjustment)" (step S17 = YES), the process proceeds to step S18. On the other hand, if it is determined that the status is not "7 (decompression adjustment)" (step S17 = NO), the process proceeds to step S19.

(Step S18)
In step S18, the CPU 6a performs the decompression adjustment processing. Specifically, the CPU 6a is a process of setting "4 (pressure holding)" in the status storage area provided in the RAM 6c when the atmospheric pressure inside the accommodating portion 2 reaches the changed pressure (atmospheric pressure). I do. Further, when the operation of the end button 12 is detected, the CPU 6a performs a process at the time of the end button operation for setting "5 (recovery pressure)" in the status storage area provided in the RAM 6c, and temporarily performs the process. When the operation of the stop button 13 is detected, the temporary stop button operation process for maintaining the air pressure inside the accommodating unit 2 is performed, and when the operation of the emergency stop button 14 is detected, the atmosphere release valve 22 is performed. Is released, and "1 (stop)" is set in the status storage area provided in the RAM 6c. The emergency stop button operation process is performed. Then, when the process of step S18 is completed, the process shifts to step S3.

(Step S19)
In step S19, the CPU 6a performs a process of determining whether or not the status is "8 (abnormal)". Specifically, the CPU 6a performs a process of determining whether or not the value of the status storage area provided in the RAM 6c is "8 (abnormal)". Then, when it is determined that the status is "8 (abnormal)" (step S19 = YES), the process shifts to step S20. On the other hand, if it is determined that the status is not "8 (abnormal)" (step S19 = NO), the process shifts to step S3.

(Step S20)
In step S20, the CPU 6a performs an error processing. Specifically, the CPU 6a performs a process of restoring the atmospheric pressure inside the accommodating portion 2 to the standard atmospheric pressure, and when the atmospheric pressure inside the accommodating portion 2 becomes the standard atmospheric pressure, the status storage area provided in the RAM 6c Is set to "1 (stop)". Here, the method of restoring the pressure to the standard atmospheric pressure will be described in detail later. Then, when the process of step S20 is completed, the process shifts to step S3.

(Interrupt processing)
Next, the interrupt process will be described with reference to FIG.

Here, the interrupt process is a process performed by interrupting the process (see FIG. 4) in the atmospheric pressure control unit 6 at predetermined cycles (for example, 2 ms).

(Step S101)
In step S101, the CPU 6a performs a process of determining whether or not the barometric pressure threshold has been reached. Specifically, the CPU 6a determines whether or not the atmospheric pressure inside the accommodating portion 2 has reached the atmospheric pressure threshold value by comparing the measurement result by the barometer 16 with the atmospheric pressure threshold value stored in the ROM 6b. Perform the processing to be performed. Then, when it is determined that the atmospheric pressure threshold has been reached (step S101 = YES), the process proceeds to step S103. On the other hand, if it is determined that the atmospheric pressure threshold has not been reached (step S101 = NO), the process proceeds to step S102.

Here, the "atmospheric pressure threshold value" is provided with a barometric pressure threshold value for pressurization and a barometric pressure threshold value for depressurization. Specifically, the atmospheric pressure threshold value for pressurization in the present embodiment is "1.8" atmospheric pressure, and the atmospheric pressure threshold value for depressurization is "0.6" atmospheric pressure. That is, in the process of step S101, the process of determining whether or not the atmospheric pressure inside the accommodating portion 2 has reached the atmospheric pressure threshold value of "1.8" for pressurization and the atmospheric pressure threshold value for decompression. The process of determining whether or not the pressure has reached "0.6" will be performed.

(Step S102)
In step S102, the CPU 6a performs a process of determining whether or not the oxygen concentration threshold has been reached. Specifically, the CPU 6a compares the result of the measurement by the oxygen concentration meter 17 with the oxygen concentration threshold value stored in the ROM 6b to see if the oxygen concentration inside the accommodating portion 2 has reached the oxygen concentration threshold value. Performs the process of determining whether or not. Then, when it is determined that the oxygen concentration threshold has been reached (step S102 = YES), the process proceeds to step S103. On the other hand, if it is determined that the oxygen concentration threshold has not been reached (step S102 = NO), the process proceeds to step S105.

Here, the "oxygen concentration threshold value" in this embodiment is "14%" and is stored in the ROM 6b.

(Step S103)
In step S103, the CPU 6a performs a warning process. Specifically, the CPU 6a performs a process of transmitting a predetermined signal to the warning device 29 in order for the warning device 29 to display a warning image and to output a warning sound. Further, a process of displaying a warning image on the liquid crystal display device 19 and a process of producing a warning sound by the atmospheric pressure control unit 6 are performed. Then, when the process of step S103 is completed, the process shifts to step S104.

(Step S104)
In step S104, the CPU 6a performs a warning status change process. Specifically, the CPU 6a performs a process of setting "8 (abnormal)" in the status storage area provided in the RAM 6c. Then, when the process of step S104 is completed, the interrupt process is ended, and the process is shifted to the process before the interrupt process is started.

(Step S105)
In step S105, the CPU 6a performs a monitoring process. Specifically, the CPU 6a performs a process of monitoring the pressurization amount and the decompression amount per predetermined unit time. Then, when the process of step S105 is completed, the process shifts to step S106.

(Step S106)
In step S106, the CPU 6a performs a process of determining whether or not it is at the time of correction. Specifically, the CPU 6a performs a process of determining whether or not a predetermined amount of deviation occurs in the pressurization amount and the decompression amount per unit time by the monitoring process in step S105. Then, when it is determined that it is the time of correction (step S106 = YES), the process shifts to step S107. On the other hand, if it is determined that it is not the time of correction (step S106 = NO), the process shifts to step S108.

(Step S107)
In step S107, the CPU 6a performs a correction process. Specifically, the CPU 6a is one of the first on-off valves 23 to the fourth on-off valve 26 when the pressurizing amount per unit time or the depressurizing amount deviates by a predetermined amount (step S106 = YES). Alternatively, by opening a plurality of them, a process of correcting a predetermined amount of deviation is performed. Then, when the process of step S107 is completed, the interrupt process is ended, and the process is shifted to the process before the interrupt process is started.

Here, to explain the correction process in step S107 more specifically, the CPU 6a controls to open the first on-off valve 23 when the pressurization amount or the deviation of the depressurization amount is the first amount. As a result, the process of correcting the deviation of the atmospheric pressure is performed. Further, the CPU 6a opens the first on-off valve 23 and the second on-off valve 24 when the pressurizing amount or the deviation of the depressurizing amount is a second amount larger than the first amount. By performing control, processing for correcting the deviation of atmospheric pressure is performed.

Further, the CPU 6a has a first on-off valve 23, a second on-off valve 24, and a third on-off valve 23 when the pressurization amount and the deviation of the decompression amount are a third amount larger than the second amount. By controlling the opening of the on-off valve 25, a process of correcting the deviation of the atmospheric pressure is performed. Further, the CPU 6a has a first on-off valve 23, a second on-off valve 24, and a third on-off valve 23 when the pressurization amount or the deviation of the decompression amount is a fourth amount larger than the third amount. By controlling the opening of the valve 25 and the fourth on-off valve 26, a process of correcting the deviation of the atmospheric pressure is performed.

(Step S108)
In step S108, the CPU 6a performs a process of determining whether or not an error has been detected. Specifically, the CPU 6a performs a process of determining whether or not the atmospheric pressure deviation could not be corrected within a predetermined time, although the correction process of step S107 was performed, for example. Then, when it is determined that an error has been detected (step S108 = YES), the process proceeds to step S109. On the other hand, if it is determined that no error has been detected (step S108 = NO), the interrupt process is terminated and the process is shifted to the process before the interrupt process is started.

(Step S109)
In step S109, the CPU 6a performs an error processing. Specifically, the CPU 6a performs a process of displaying an error image on the liquid crystal display device 19 and a process of transmitting a signal necessary for the warning device 29 to display the error image. Further, the CPU 6a performs a process of setting "8 (abnormal)" in the status storage area provided in the RAM 6c. Then, when the process of step S109 is completed, the interrupt process is ended, and the process is shifted to the process before the interrupt process is started.

(Graph showing the transition of atmospheric pressure from step-down to re-pressure)
Next, with reference to FIG. 6, a graph showing the transition of the atmospheric pressure from the pressure reduction to the pressure recovery will be described.

First, at the timing of FIG. 6 (A), while the mode selection screen is displayed, "0.70 atm" is selected as the pressure, "90 minutes" is selected as the operation time, and "slowly" is selected as the step-down time. Is selected, the setting completion operation is detected, and when the start button 11 is operated, the pressure reducing on-off valve 21 is opened and the pressure reducing pump 28 is driven to reduce the air pressure inside the accommodating portion 2. It becomes.

Here, the step-down time will be described later, but when "standard" is selected, it is selected in "10" minutes, and when "slow" is selected, it is selected in "15" minutes. Control is performed to lower the pressure to the atmospheric pressure.

When "90" minutes is selected as the operation time and "slow" is selected as the step-down time, the step-down time is "15" minutes, the atmospheric pressure maintenance is "60" minutes, and the decompression time is "15" minutes. Become.

Then, at the timing between FIGS. 6 (A) and 6 (B), the atmospheric pressure inside the accommodating portion 2 is changed from the standard atmospheric pressure of "1.0" to the set "0.70" atmospheric pressure. Controls to lower the pressure. Specifically, control is performed to reduce the atmospheric pressure by "0.3" in "15" minutes. In other words, control is performed to lower the atmospheric pressure by "0.02" per "1" minute, which is a unit time. Then, in the monitoring process of step S105, it is monitored whether or not the pressure is lower than the "0.02" atmospheric pressure every "1" minute, which is a unit time, and the pressure is lower than the "0.02" atmospheric pressure. If so, the correction process in step S107 controls opening and closing one or more of the first on-off valves 23 to the fourth on-off valves 26. Here, when one or more of the first on-off valves 23 to the fourth on-off valves 26 are opened, the air pressure inside the accommodating portion 2 is corrected by taking in the outside air into the accommodating portion 2. Become.

Next, the timing of FIG. 6 (B) indicates that the pressure was lowered to the set "0.70" atmospheric pressure.

Here, at the timing between FIGS. 6 (B) and 6 (C), the control for maintaining the "0.70" atmospheric pressure set by the atmospheric pressure control unit 6 is performed. Specifically, in the monitoring process of step S105, it is monitored whether or not the pressure is lowered by "0.02" every "1" minutes, and if the pressure is lowered by "0.02", the pressure is lowered by "0.02". The correction process in step S107 controls opening and closing one or more of the first on-off valves 23 to the fourth on-off valves 26. Here, when one or more of the first on-off valves 23 to the fourth on-off valves 26 are opened, the outside air is taken into the inside of the accommodating portion 2, so that the air pressure inside the accommodating portion 2 is corrected. It will be.

Next, the timing of FIG. 6C indicates the timing at which the air pressure inside the accommodating portion 2 is maintained for the set “60” minutes. At this timing, the drive of the decompression pump 28 is stopped.

Next, at the timing between FIGS. 6 (C) and 6 (D), the atmospheric pressure inside the accommodating portion 2 is restored from "0.70" atmospheric pressure to "1.0" atmospheric pressure, which is the standard atmospheric pressure. Take control. Specifically, control is performed to boost the atmospheric pressure by "0.3" in "15" minutes. In other words, control is performed to boost the atmospheric pressure by "0.02" per "1" minute, which is a unit time. Then, in the monitoring process of step S105, it is monitored whether or not the atmospheric pressure is boosted by "0.02" every "1" minutes, which is a unit time, and if the pressure is not boosted by "0.02", the pressure is not boosted by "0.02". The correction process in step S107 controls opening and closing one or more of the first on-off valves 23 to the fourth on-off valves 26. Here, when one or more of the first on-off valves 23 to the fourth on-off valves 26 are opened, the air pressure inside the accommodating portion 2 is corrected by taking in the outside air into the accommodating portion 2. Become.

Next, the timing of FIG. 6D indicates the timing at which the atmospheric pressure inside the accommodating portion 2 is restored to the standard atmospheric pressure.

(Graph showing the transition of atmospheric pressure at the time of step-down failure)
Next, with reference to FIG. 7, a graph showing the transition of the atmospheric pressure at the time of the step-down failure will be described.

First, at the timing of FIG. 7A, while the mode selection screen is displayed, "0.7 atm" is selected as the pressure, "90 minutes" is selected as the operation time, and "slowly" is selected as the step-down time. Is selected, the setting completion operation is detected, and when the start button 11 is operated, the pressure reducing on-off valve 21 is opened and the pressure reducing pump 28 is driven to reduce the air pressure inside the accommodating portion 2. It becomes.

Then, at the timing between FIGS. 7 (A) and 7 (B), the atmospheric pressure inside the accommodating portion 2 is changed from the standard atmospheric pressure of "1.0" to the set "0.70" atmospheric pressure. Controls to lower the pressure. Specifically, control is performed to reduce the atmospheric pressure by "0.3" in "15" minutes. In other words, control is performed to lower the atmospheric pressure by "0.02" per "1" minute, which is a unit time. Then, in the monitoring process of step S105, it is monitored whether or not the pressure is lower than the "0.02" atmospheric pressure every "1" minute, which is a unit time, and the pressure is lower than the "0.02" atmospheric pressure. If so, the correction process in step S107 controls the opening and closing of the first on-off valve 23 to the fourth on-off valve 26. Here, when the first on-off valve 23 to the fourth on-off valve 26 are opened, the air pressure inside the accommodating portion 2 is corrected by taking in the outside air into the accommodating portion 2.

Next, the timing of FIG. 7 (B) indicates that the pressure was lowered to the set "0.70" atmospheric pressure.

Here, at the timing between FIGS. 7 (B) and 7 (C), the control for maintaining the "0.70" atmospheric pressure set by the atmospheric pressure control unit 6 is performed. Specifically, in the monitoring process of step S105, it is monitored whether or not the pressure is lowered by "0.02" every "1" minutes, and if the pressure is lowered by "0.02", the pressure is lowered by "0.02". The correction process in step S107 controls opening and closing one or more of the first on-off valves 23 to the fourth on-off valves 26. Here, when one or more of the first on-off valves 23 to the fourth on-off valves 26 are opened, the outside air is taken into the inside of the accommodating portion 2, so that the air pressure inside the accommodating portion 2 is corrected. It will be.

Next, the timing of FIG. 7C indicates the timing at which the atmospheric pressure control unit 6 has failed. Here, to give a specific example of failure, it is conceivable that any or all of the first on-off valve 23 to the fourth on-off valve 26 may remain closed.

Here, at the timing between FIGS. 7 (C) and 7 (D), the air pressure control unit 6 is out of order, so that the air pressure inside the accommodating unit 2 cannot be corrected, and the air pressure is accommodated. The air pressure inside the part 2 is gradually lowered.

Next, the timing of FIG. 7 (D) is the timing at which the atmospheric pressure inside the accommodating portion 2 is lowered to the atmospheric pressure threshold value of "0.6" for decompression. At this timing, the warning device 29 displays a warning image indicating that it is dangerous to continue staying inside the accommodating portion 2, and emits a warning sound.

Next, at the timing between FIGS. 7 (D) and 7 (E), the pressure inside the accommodating portion 2 is controlled to be restored to the standard atmospheric pressure of "1.0". Here, as a method of recovering the atmospheric pressure inside the accommodating portion 2 from the atmospheric pressure threshold value for decompression to the standard atmospheric pressure, the pressure is restored by any of the following first decompression method to fourth decompression method. The Rukoto.

(First recompression method)
When there is a first on-off valve 23 to a fourth on-off valve 26 that has not failed, one or a plurality of the first on-off valves 23 to the fourth on-off valve 26 that have not failed are stored in the ROM 6b in advance. During the recovery pressure time (for example, "15" minutes), the pressure inside the accommodating unit 2 is restored from the pressure threshold value "0.6" for decompression to the standard pressure "1.0" pressure. Press.

(Second recompression method)
When there is a first on-off valve 23 to a fourth on-off valve 26 that has not failed, the air pressure inside the accommodating portion 2 is obtained by opening all the first on-off valves 23 to the fourth on-off valve 26 that have not failed. Is restored from "0.6" atmospheric pressure, which is the atmospheric pressure threshold for decompression, to "1.0" atmospheric pressure, which is the standard atmospheric pressure.

(Third recompression method)
By opening the atmosphere release valve 22, the atmospheric pressure inside the accommodating portion 2 is restored from the atmospheric pressure threshold value of "0.6" for decompression to the standard atmospheric pressure of "1.0".

(Fourth recompression method)
By driving the pressurizing pump 27, the atmospheric pressure inside the accommodating portion 2 is restored from the atmospheric pressure threshold value "0.6" for decompression to the standard atmospheric pressure "1.0" atmospheric pressure.

Next, the timing of FIG. 7 (E) is the timing at which the atmospheric pressure inside the accommodating portion 2 is restored to the standard atmospheric pressure of "1.0".

(Graph showing the transition of atmospheric pressure from boosting to restoring pressure)
Next, with reference to FIG. 8, a graph showing the transition of atmospheric pressure from boosting to restoring pressure will be described.

First, at the timing of FIG. 8A, while the mode selection screen is displayed, "1.7 atm" is selected as the pressure, "90 minutes" is selected as the operating time, and "slowly" is selected as the boosting time. Is selected, the setting completion operation is detected, and when the start button 11 is operated, the pressurizing on-off valve 20 is opened and the pressurizing pump 27 is driven to increase the air pressure inside the accommodating portion 2. The Rukoto.

Here, the boosting time will be described later, but when "standard" is selected, it is selected in "10" minutes, and when "slow" is selected, it is selected in "15" minutes. Control is performed to boost the pressure to the atmospheric pressure.

When "90" minutes is selected as the operation time and "slow" is selected as the boosting time, the boosting time is "15" minutes, the atmospheric pressure maintenance is "60" minutes, and the decompression time is "15" minutes. Become.

Then, at the timing between FIGS. 8 (A) and 8 (B), the atmospheric pressure inside the accommodating portion 2 is changed from the standard atmospheric pressure of "1.0" to the set "1.7" atmospheric pressure. Controls to boost the pressure. Specifically, control is performed to boost the atmospheric pressure by "0.7" in "15" minutes. In other words, control is performed to boost the atmospheric pressure by "about 0.047" per "1" minute, which is a unit time. Then, in the monitoring process of step S105, it is monitored whether or not the pressure is higher than the "about 0.047" atmospheric pressure every "1" minute, which is a unit time, and the pressure is higher than the "about 0.047" atmospheric pressure. If this is the case, the correction process in step S107 controls opening and closing one or more of the first on-off valves 23 to the fourth on-off valves 26. Here, when the first on-off valve 23 to the fourth on-off valve 26 are opened, the air pressure inside the accommodating portion 2 is corrected by taking in the outside air into the accommodating portion 2.

Next, the timing of FIG. 8 (B) indicates that the pressure was increased to the set "1.7" atmosphere.

Here, at the timing between FIGS. 8 (B) and 8 (C), the control for maintaining the "1.7" atmospheric pressure set by the atmospheric pressure control unit 6 is performed. Specifically, in the monitoring process of step S105, it is monitored whether or not the atmospheric pressure is boosted by "about 0.047" every "1" minute, and when the atmospheric pressure is boosted by "about 0.047". Is controlled to open and close one or more of the first on-off valves 23 to the fourth on-off valves 26 by the correction process in step S107. Here, when one or more of the first on-off valves 23 to the fourth on-off valves 26 are opened, the outside air is taken into the inside of the accommodating portion 2, so that the air pressure inside the accommodating portion 2 is corrected. It will be.

Next, the timing of FIG. 8C indicates the timing at which the air pressure inside the accommodating portion 2 is maintained for the set “60” minutes. At this timing, the drive of the pressurizing pump 27 is stopped.

Next, at the timing between FIGS. 8 (C) and 8 (D), the atmospheric pressure inside the accommodating portion 2 is restored from "1.7" atmospheric pressure to "1.0" atmospheric pressure, which is the standard atmospheric pressure. Take control. Specifically, control is performed to reduce the atmospheric pressure by "0.7" in "15" minutes. In other words, control is performed to reduce the atmospheric pressure by "about 0.047" per "1" minute, which is a unit time. Then, in the monitoring process of step S105, it is monitored whether or not the atmospheric pressure is lowered by "about 0.047" every "1" minute, which is a unit time, and when the atmospheric pressure is not lowered by "about 0.047". In the above, the correction process of step S107 controls opening and closing one or more of the first on-off valves 23 to the fourth on-off valves 26. Here, when one or more of the first on-off valves 23 to the fourth on-off valves 26 are opened, the air pressure inside the accommodating portion 2 is corrected by taking in the outside air into the accommodating portion 2. Become.

Next, the timing of FIG. 8D indicates the timing at which the atmospheric pressure inside the accommodating portion 2 is restored to the standard atmospheric pressure.

(Graph showing the transition of atmospheric pressure at the time of boost failure)
Next, with reference to FIG. 9, a graph showing the transition of the atmospheric pressure at the time of the boost failure will be described.

First, at the timing of FIG. 9A, while the mode selection screen is displayed, "1.7 atm" is selected as the pressure, "90 minutes" is selected as the operating time, and "slowly" is selected as the boosting time. Is selected, the setting completion operation is detected, and when the start button 11 is operated, the pressure reducing on-off valve 21 is opened and the pressurizing pump 27 is driven to increase the air pressure inside the accommodating portion 2. It will be.

Then, at the timing between FIGS. 9 (A) and 9 (B), the atmospheric pressure inside the accommodating portion 2 is changed from the standard atmospheric pressure of "1.0" to the set "1.7" atmospheric pressure. Controls to boost the pressure. Specifically, control is performed to boost the atmospheric pressure by "0.7" in "15" minutes. In other words, control is performed to boost the atmospheric pressure by "about 0.047" per "1" minute, which is a unit time. Then, in the monitoring process of step S105, it is monitored whether or not the pressure is higher than the "0.047" atmospheric pressure every "1" minute, which is a unit time, and the pressure is higher than the "about 0.047" atmospheric pressure. If so, the correction process in step S107 controls opening and closing one or more of the first on-off valves 23 to the fourth on-off valves 26. Here, when one or more of the first on-off valves 23 to the fourth on-off valves 26 are opened, the air pressure inside the accommodating portion 2 is corrected by taking in the outside air into the accommodating portion 2. Become.

Next, the timing in FIG. 9B indicates that the pressure was increased to the selected "1.7" atmosphere.

Here, at the timing between FIGS. 9 (B) and 9 (C), the control for maintaining the "1.7" atmospheric pressure set by the atmospheric pressure control unit 6 is performed. Specifically, in the monitoring process of step S105, it is monitored whether or not the atmospheric pressure is boosted by "about 0.047" every "1" minute, and when the atmospheric pressure is boosted by "about 0.047". Is controlled to open and close one or more of the first on-off valves 23 to the fourth on-off valves 26 by the correction process in step S107. Here, when one or more of the first on-off valves 23 to the fourth on-off valves 26 are opened, the outside air is taken into the inside of the accommodating portion 2, so that the air pressure inside the accommodating portion 2 is corrected. It will be.

Next, the timing of FIG. 9C indicates the timing at which the atmospheric pressure control unit 6 has failed. Here, to give a specific example of failure, it is conceivable that any or all of the first on-off valve 23 to the fourth on-off valve 26 may remain closed.

Here, at the timing between FIGS. 9 (C) and 9 (D), the air pressure control unit 6 is out of order, so that the air pressure inside the accommodating unit 2 cannot be corrected, and the air pressure is accommodated. The air pressure inside the part 2 is gradually increasing.

Next, the timing of FIG. 9D is the timing at which the atmospheric pressure inside the accommodating portion 2 is boosted to the "1.8" atmospheric pressure, which is the atmospheric pressure threshold for pressurization. At this timing, the warning device 29 displays a warning image indicating that it is dangerous to continue staying inside the accommodating portion 2, and emits a warning sound.

Next, at the timing between FIGS. 9 (D) and 9 (E), control is performed to restore the atmospheric pressure inside the accommodating portion 2 to the standard atmospheric pressure of "1.0". Here, as a method of restoring the atmospheric pressure inside the accommodating portion 2 from the atmospheric pressure threshold value for pressurization to the standard atmospheric pressure, the pressure is restored by any of the following first recompression method to fourth decompression method. The Rukoto.

(First recompression method)
When there is a first on-off valve 23 to a fourth on-off valve 26 that has not failed, one or a plurality of the first on-off valves 23 to the fourth on-off valve 26 that have not failed are stored in the ROM 6b in advance. During the recovery pressure time (for example, "15" minutes), the pressure inside the accommodating portion 2 is restored from the pressure threshold value of "1.8" for pressurization to the standard pressure of "1.0". Press.

(Second recompression method)
When there is a first on-off valve 23 to a fourth on-off valve 26 that has not failed, the air pressure inside the accommodating portion 2 is obtained by opening all the first on-off valves 23 to the fourth on-off valve 26 that have not failed. Is restored from "1.8" atmospheric pressure, which is the atmospheric pressure threshold for pressurization, to "1.0" atmospheric pressure, which is the standard atmospheric pressure.

(Third recompression method)
By opening the atmosphere release valve 22, the atmospheric pressure inside the accommodating portion 2 is restored from the atmospheric pressure threshold value of "1.8" for pressurization to the standard atmospheric pressure of "1.0".

(Fourth recompression method)
By driving the decompression pump 28, the atmospheric pressure inside the accommodating portion 2 is restored from the atmospheric pressure threshold value of "1.8" for pressurization to the standard atmospheric pressure of "1.0".

Next, the timing of FIG. 9 (E) is the timing at which the atmospheric pressure inside the accommodating portion 2 is restored to the standard atmospheric pressure of "1.0".

(Display mode of warning device 29 at the time of step-down failure)
Next, a display mode of the warning device 29 at the time of a step-down failure will be described with reference to FIG.

First, FIG. 10A shows that the mode selection screen is displayed on the liquid crystal display device 19. Further, in FIG. 10A, "0.70" atmospheric pressure is selected as the pressure selection, "90" minutes is selected as the operating time, and "slow" is selected as the step-down time.

Here, in the present embodiment, as the pressure selection, "1.3" atmospheric pressure, "1.4" atmospheric pressure, "1.5" atmospheric pressure, "1.6" atmospheric pressure, "1.7" atmospheric pressure, "0" You can select .90 "atmospheric pressure," 0.85 "atmospheric pressure," 0.80 "atmospheric pressure," 0.75 "atmospheric pressure, and" 0.70 "atm. The pressure selection shown in FIG. 10A is merely an example, and other pressures may be selectable.

Further, in the present embodiment, the operation time can be selected from "30" minutes, "60" minutes, "90" minutes, "120" minutes, and "180" minutes. The operation time shown in FIG. 10A is only an example, and another operation time may be selectable. For example, "infinity" may be selectable as the operating time.

Further, in the present embodiment, "normal" and "slow" can be selected as the step-down time. Here, when "normal" is selected as the step-down time, the pressure is lowered so as to reach the selected atmospheric pressure in "10" minutes, and when "slow" is selected as the step-down time, "15" is selected. The pressure will be reduced to reach the selected air pressure in minutes. The step-down time shown in FIG. 10A is just an example, and another step-down time may be selectable.

Then, when the display mode of the liquid crystal display device 19 is the display mode shown in FIG. 10 (A), the setting completion operation in which the touch panel 15 in the area corresponding to "setting completion" is operated is detected and started. When the button 11 is operated, the air pressure inside the accommodating portion 2 is lowered.

Next, FIG. 10B shows a display mode of the warning device 29 in a state where the air pressure inside the accommodating portion 2 is lowered. Further, FIG. 10B shows that "0.70" atmospheric pressure is selected as the pressure selection, and "90" minutes is selected as the operation time, and the step-down time is set. It indicates that "15" minutes are selected, and indicates that the decompression time is "15" minutes.

Further, FIG. 10B shows that the operating state is "lowering", and that the elapsed time is "10" minutes and "23" seconds, and that the inside of the current accommodating portion 2 is inside. It shows that the atmospheric pressure is "0.8" atmospheric pressure.

Further, at the timing of FIG. 10B, a graph showing the transition of the air pressure inside the accommodating portion 2 is displayed. It should be noted that this graph displays a graph obtained by adding "5" minutes to the set operation time.

When the setting change operation is detected at the timing of FIG. 10B, the atmospheric pressure can be changed from the set "0.7" atmospheric pressure.

Next, in FIG. 10C, the first on-off valve 23 to the fourth on-off valve 26 of the air pressure control unit 6 failed, and the air pressure inside the accommodating unit 2 reached the threshold value of “0.6”. The display mode of the warning device 29 at the time is shown.

Further, FIG. 10C shows that the operating state is "abnormal", and that the elapsed time is "35" minutes and "00" seconds, and that the inside of the current accommodating portion 2 is inside. It shows that the atmospheric pressure is "0.6" atmospheric pressure.

Further, at the timing of FIG. 10C, since the atmospheric pressure inside the accommodating portion 2 has reached the threshold value of "0.6" atmospheric pressure, the character image of "abnormality occurred" is displayed on the warning device 29. The Rukoto.

At the timing of FIG. 10 (C), a graph showing the transition of the air pressure inside the accommodating portion 2 is displayed as in FIG. 10 (B).

Here, when the atmospheric pressure inside the accommodating portion 2 reaches the threshold value of "0.6" atmospheric pressure, the display mode of the liquid crystal display device 19 is the same as the display mode of FIG. 10 (C). It becomes an aspect. Therefore, it is possible to recognize that an abnormality has occurred even from the outside of the accommodating portion 2.

Then, when the atmospheric pressure inside the accommodating portion 2 reaches the atmospheric pressure threshold value for decompression, control is performed to restore the atmospheric pressure to the standard atmospheric pressure of "1.0".

Next, FIG. 10D shows a display mode of the warning device 29 when the atmospheric pressure inside the accommodating portion 2 is restored to the standard atmospheric pressure of “1.0”. Further, FIG. 10D shows that the operating state is "stopped", and that the elapsed time is "60" minutes and "00" seconds, and that the inside of the current accommodating portion 2 is inside. It shows that the atmospheric pressure is "1.0" atmospheric pressure.

(Display mode of warning device 29 at the time of boost failure)
Next, with reference to FIG. 11, a display mode of the warning device 29 at the time of a boost failure will be described.

First, FIG. 11A shows that the mode selection screen is displayed on the liquid crystal display device 19. Further, in FIG. 11A, "1.7" atmospheric pressure is selected as the pressure selection, "90" minutes is selected as the operating time, and "slow" is selected as the boosting time.

Further, in the present embodiment, "normal" and "slow" can be selected as the boosting time. Here, when "normal" is selected as the boosting time, the pressure is increased so as to reach the selected atmospheric pressure in "10" minutes, and when "slow" is selected as the boosting time, "15" is selected. It will be boosted to reach the selected air pressure in minutes. The boosting time shown in FIG. 11A is just an example, and another boosting time may be selectable.

Then, in the case where the display mode of the liquid crystal display device 19 is the display mode shown in FIG. 11A, when the setting completion operation is detected and the start button 11 is operated, the air pressure inside the accommodating unit 2 is operated. Will be boosted.

Next, FIG. 11B shows a display mode of the warning device 29 in a state where the air pressure inside the accommodating portion 2 is boosted. Further, FIG. 11B shows that "1.7" atmospheric pressure is selected as the pressure selection, and "90" minutes is selected as the operating time, and the boosting time is set. It indicates that "15" minutes are selected, and indicates that the decompression time is "15" minutes.

Further, FIG. 11B shows that the operating state is “boosting”, and that the elapsed time is “10” minutes and “23” seconds, and that the inside of the current accommodating portion 2 is inside. It shows that the atmospheric pressure is "1.5" atmospheric pressure.

Further, at the timing of FIG. 11B, a graph showing the transition of the air pressure inside the accommodating portion 2 is displayed. It should be noted that this graph displays a graph obtained by adding "5" minutes to the set operation time.

When the setting change operation is detected at the timing of FIG. 11B, the atmospheric pressure can be changed from the set "1.7" atmospheric pressure.

Next, in FIG. 11C, the first on-off valve 23 to the fourth on-off valve 26 of the air pressure control unit 6 failed, and the air pressure inside the accommodating unit 2 reached the threshold value of “1.8”. The display mode of the warning device 29 at the time is shown.

Further, FIG. 11C shows that the operating state is "abnormal" and that the elapsed time is "35" minutes and "00" seconds, and that the inside of the current accommodating portion 2 is inside. It shows that the atmospheric pressure is "1.8" atmospheric pressure.

Further, at the timing of FIG. 11C, since the atmospheric pressure inside the accommodating portion 2 has reached the threshold value of "1.8" atmospheric pressure, the character image of "abnormality occurred" is displayed on the warning device 29. The Rukoto.

At the timing of FIG. 11C, a graph showing the transition of the air pressure inside the accommodating portion 2 is displayed as in FIG. 11B.

Here, when the atmospheric pressure inside the accommodating portion 2 reaches the threshold value of "1.8" atmospheric pressure, the display mode of the liquid crystal display device 19 is the same as the display mode of FIG. 11 (C). It becomes an aspect. Therefore, it is possible to recognize that an abnormality has occurred even from the outside of the accommodating portion 2.

Then, when the atmospheric pressure inside the accommodating portion 2 reaches the threshold value, control is performed to restore the atmospheric pressure to the standard atmospheric pressure of "1.0".

Next, FIG. 11D shows a display mode of the warning device 29 when the atmospheric pressure inside the accommodating portion 2 is restored to the standard atmospheric pressure of “1.0”. Further, FIG. 11D shows that the operating state is "stopped", and that the elapsed time is "75" minutes and "00" seconds, and that the inside of the current accommodating portion 2 is inside. It shows that the atmospheric pressure is "1.0" atmospheric pressure.

(Other embodiments)
Hereinafter, other embodiments will be described.

In the above-described embodiment, "1.8" atmospheric pressure is stored in the ROM 6b as the atmospheric pressure threshold value for pressurization, and "0.6" atmospheric pressure is stored in the ROM 6b as the atmospheric pressure threshold value for depressurization, but the present invention is not limited to this. For example, a barometric pressure threshold may be provided for each selectable pressure.

Specifically, in the above-described embodiment, the pressure selections are "1.3" atmospheric pressure, "1.4" atmospheric pressure, "1.5" atmospheric pressure, "1.6" atmospheric pressure, and "1.7" atmospheric pressure. , "0.90" atmospheric pressure, "0.85" atmospheric pressure, "0.80" atmospheric pressure, "0.75" atmospheric pressure, and "0.70" atmospheric pressure can be selected.

Therefore, "1.4" atmospheric pressure is stored as the atmospheric pressure threshold for pressurization when "1.3" atmospheric pressure is selected, and "1.4" atmospheric pressure is stored as the atmospheric pressure threshold for pressurization when "1.4" atmospheric pressure is selected. Stores "1.5" atmospheric pressure, stores "1.6" atmospheric pressure as the atmospheric pressure threshold for pressurization when "1.5" atmospheric pressure is selected, and applies when "1.6" atmospheric pressure is selected. "1.7" atmospheric pressure is stored as the atmospheric pressure threshold for pressure, and "1.8" atmospheric pressure is stored as the atmospheric pressure threshold for pressurization when "1.7" atmospheric pressure is selected.

As a result, for example, when "1.3" atmospheric pressure is selected as the pressure selection, the atmospheric pressure threshold value for pressurization becomes "1.4" atmospheric pressure, and therefore, as in the above-described embodiment, "1". It is possible to detect a failure of the atmospheric pressure control unit 6 before boosting to the atmospheric pressure of .8 ". As a result, the safety of the user can be further enhanced.

Further, "0.80" atmospheric pressure is stored as the atmospheric pressure threshold for decompression when "0.90" atmospheric pressure is selected, and "0" is stored as the atmospheric pressure threshold for decompression when "0.85" atmospheric pressure is selected. Stores .75 "atmospheric pressure, stores" 0.70 "atmospheric pressure as the atmospheric pressure threshold for decompression when" 0.80 "atmospheric pressure is selected, and stores decompression when" 0.75 "atmospheric pressure is selected. "0.65" atmospheric pressure is stored as the atmospheric pressure threshold of, and "0.60" atmospheric pressure is stored as the atmospheric pressure threshold for decompression when "0.70" atmospheric pressure is selected.

As a result, for example, when "0.8" atmospheric pressure is selected as the pressure selection, the atmospheric pressure threshold value for decompression becomes "0.7" atmospheric pressure, so that "0" is used as in the above-described embodiment. It is possible to detect a failure of the atmospheric pressure control unit 6 before lowering the pressure to "0.6" atmospheric pressure. As a result, the safety of the user can be further enhanced.

As described above, according to the present invention, in the state where the mode selection screen is displayed on the liquid crystal display device 19 of the atmospheric pressure control unit 6, the atmospheric pressure lower than the standard atmospheric pressure is selected as the atmospheric pressure selection, and the operating time and the operating time and When the step-down time is selected, the setting completion operation is detected, and the start button 11 is operated, the air pressure inside the accommodating portion 2 is stepped down. Then, when the CPU 6a determines that the atmospheric pressure inside the accommodating portion 2 has reached the atmospheric pressure threshold value of "0.6" for decompression, the warning device 29 issues a warning. Then, the user can recognize that the atmospheric pressure inside the accommodating portion 2 has reached the atmospheric pressure threshold value of "0.6" for decompression, so that the user can evacuate to the outside of the accommodating portion 2. It becomes. Thereby, the safety of the user of the oxygen room 1 can be enhanced.

Further, according to the present invention, in a state where the mode selection screen is displayed on the liquid crystal display device 19 of the atmospheric pressure control unit 6, an atmospheric pressure higher than the standard atmospheric pressure is selected as the pressure selection, and the operating time and the boosting time are increased. Is selected, the setting completion operation is detected, and when the start button 11 is operated, the air pressure inside the accommodating portion 2 is increased. Then, when the CPU 6a determines that the atmospheric pressure inside the accommodating portion 2 has reached the atmospheric pressure threshold value of "1.8" for pressurization, the warning device 29 issues a warning. Then, the user can recognize that the atmospheric pressure inside the accommodating portion 2 has reached the atmospheric pressure threshold value of "1.8" for pressurization, so that the user can evacuate to the outside of the accommodating portion 2. It becomes. Thereby, the safety of the user of the oxygen room 1 can be enhanced.

Further, according to the present invention, when the CPU 6a determines that the atmospheric pressure inside the accommodating portion 2 has reached the atmospheric pressure threshold of "1.8" for pressurization, or when the atmospheric pressure inside the accommodating portion 2 is for depressurizing. When it is determined that the atmospheric pressure is "0.6", which is the atmospheric pressure threshold value of, the control is performed to restore the atmospheric pressure inside the accommodating portion 2 to the standard atmospheric pressure. As a result, even if the atmospheric pressure control unit 6 fails, the inside of the accommodating unit 2 is restored to the standard atmospheric pressure, so that the safety of the user of the oxygen room 1 can be further enhanced.

In the present embodiment, the "accommodation unit 2" constitutes the "accommodation unit" of the invention according to claim 1.

Further, in the present embodiment, the "opening 3" constitutes the "opening" of the invention according to claim 1.

Further, in the present embodiment, the "atmospheric pressure control unit 6" constitutes the "low pressure control unit" of the invention according to claim 1.

Further, in the present embodiment, the "door portion 4" constitutes the "door portion" of the invention according to claim 1.

Further, in the present embodiment, the "barometer 16" constitutes the "measurement unit" of the invention according to claim 1.

Further, in the present embodiment, the "CPU 6a that performs the process of step S101" constitutes the "determination unit" of the invention according to claim 1.

Further, in the present embodiment, the "warning device 29" constitutes the "warning unit" of the invention according to claim 1.

In the present embodiment, the "accommodation unit 2" constitutes the "accommodation unit" of the invention according to claim 2.

Further, in the present embodiment, the "opening 3" constitutes the "opening" of the invention according to claim 2.

Further, in the present embodiment, the "atmospheric pressure control unit 6" constitutes the "high pressure control unit" of the invention according to claim 2.

Further, in the present embodiment, the "door portion 4" constitutes the "door portion" of the invention according to claim 2.

Further, in the present embodiment, the "barometer 16" constitutes the "measurement unit" of the invention according to claim 2.

Further, in the present embodiment, the "CPU 6a that performs the process of step S101" constitutes the "determination unit" of the invention according to claim 2.

Further, in the present embodiment, the "warning device 29" constitutes the "warning unit" of the invention according to claim 2.

In the present embodiment, the "CPU 6a that performs the process of step S20" constitutes the "recovery unit" of the invention according to claim 3.

Although the implementation of the present invention has been described with reference to the drawings, the specific configuration is not limited to these embodiments, and the present invention includes design changes and the like within a range that does not deviate from the gist of the present invention. included. Further, the embodiments shown in the drawings can be combined with each other as long as there is no contradiction or problem in the purpose and configuration thereof. Moreover, the description content of each drawing can be an independent embodiment, and the embodiment of the present invention is not limited to one embodiment in which each drawing is combined.

1 Oxygen room 2 Accommodation 3 Opening 4 Door 5 Window 6 Barometric pressure control 6a CPU
6b ROM
6c RAM
7 Concentrated oxygen device 8 Outer oxygen discharge valve 9 Inner oxygen discharge valve 10 Power key 11 Start button 12 End button 13 Pause button 14 Emergency stop button 15 Touch panel 16 Barometer 17 Oxygen concentration meter 18 Handset 19 Liquid crystal display device 20 Pressurization On-off valve 21 Pressure-reducing on-off valve 22 Atmospheric opening valve 23 1st on-off valve 24 2nd on-off valve 25 3rd on-off valve 26 4th on-off valve 27 Pressurizing pump 28 Depressurizing pump 29 Warning device

Claims (2)

A metal housing that can accommodate the user inside,
The opening formed in the accommodating portion and
A low-pressure control unit that controls the atmospheric pressure inside the accommodating unit to be lower than the standard atmospheric pressure.
A door that can close the opening and
A measuring unit that measures the air pressure inside the housing unit,
A determination unit that determines whether or not the air pressure inside the accommodation unit measured by the measurement unit has reached a predetermined threshold value, and a determination unit.
When the determination unit determines that the air pressure inside the accommodation unit has reached the predetermined threshold value, a warning unit that gives a warning.
An inner oxygen discharge valve that restores the air pressure inside the housing to the standard atmospheric pressure when operated by the user from the inside of the housing.
When the determination unit determines that the air pressure inside the accommodation unit has reached the predetermined threshold value, the pressure reduction control unit controls to restore the air pressure inside the accommodation unit to the standard air pressure.
Equipped with a,
The low voltage control unit
Atmospheric pressure is controlled by opening and closing multiple on-off valves.
The pressure recovery control unit
An oxygen chamber characterized in that when the predetermined threshold value is reached, the air pressure inside the accommodating portion is restored to the standard air pressure by controlling the on-off valve. A metal housing that can accommodate the user inside,
The opening formed in the accommodating portion and
A high-pressure control unit that controls the atmospheric pressure inside the accommodating unit to be higher than the standard atmospheric pressure.
A door that can close the opening and
A measuring unit that measures the air pressure inside the housing unit,
A determination unit that determines whether or not the air pressure inside the accommodation unit measured by the measurement unit has reached a predetermined threshold value, and a determination unit.
When the determination unit determines that the air pressure inside the accommodation unit has reached the predetermined threshold value, a warning unit that gives a warning.
An inner oxygen discharge valve that restores the air pressure inside the housing to the standard atmospheric pressure when operated by the user from the inside of the housing.
When the determination unit determines that the air pressure inside the accommodation unit has reached the predetermined threshold value, the pressure reduction control unit controls to restore the air pressure inside the accommodation unit to the standard air pressure.
Equipped with a,
The high voltage control unit
Atmospheric pressure is controlled by opening and closing multiple on-off valves.
The pressure recovery control unit
An oxygen chamber characterized in that when the predetermined threshold value is reached, the air pressure inside the accommodating portion is restored to the standard air pressure by controlling the on-off valve.

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