JP2585696Y2 - Breathing gas supply system - Google Patents

Description

[Detailed description of the invention] A. Purpose of the invention (1) Industrial application field This invention supplies respiratory gas to a mask worn by a crew of an aircraft flying at a high altitude where air is sparse. Regarding the respiratory gas supply system, in particular, the gas worn by the mask wearer after inhalation and then exhaled, that is, carbon dioxide contained in the exhaled breath, is reduced, and the carbon dioxide reduced gas is circulated again as the breathing gas to the mask. To a respiratory gas supply system as described above.

(2) Conventional technology In a conventional aircraft, the in-flight pressure is usually maintained at a value slightly higher than the outside air pressure. Therefore, when the aircraft flies at a high altitude where the air is lean, the in-flight pressure is reduced and the oxygen partial pressure is also reduced. In this case, there is a problem that the occupant becomes deficient in oxygen and the occupant's judgment becomes dull.

For this reason, aircraft flying at a high altitude are equipped with a respiratory gas supply system that supplies respiratory gas to an oxygen replenishing mask worn by a passenger. In this respiratory gas supply system, respiratory gas is supplied to the mask from a fresh gas supply source such as an oxygen cylinder or an oxygen concentrator, and the pressure of the supplied respiratory gas is also reduced as the in-machine pressure decreases. It has become. And by increasing the oxygen concentration with the decrease in the pressure of the breathing gas,
The oxygen partial pressure of the respiratory gas supplied to the mask is kept substantially constant. And in the conventional respiratory gas supply system, the respiratory gas supplied to the mask is:
When the mask wearer once inhales and discharges, it is configured to be released into the machine.

However, since the respiratory gas supplied to the mask has a high oxygen concentration, a large amount of oxygen still remains in the gas that the mask wearer inhales once and then exhales, that is, the exhaled breath. Therefore, if such exhaled air containing a large amount of oxygen is directly discharged into the cabin, the produced oxygen is wasted.

In order to eliminate the waste, the expired oxygen-rich air may be circulated through the mask. Then, the respiratory gas supply system that circulates the oxygen-exhaled breath through the mask has the following constituent elements (a) to (e) illustrated in FIG.
(C).

(A) the gas supply valve 01 has a gas supply valve 01 is closed when the gas in the mask M ₀ the gas is discharged into the mask M ₀ is opened when it is inhaled is open gas supply path for supplying breathable gas to the mask M in ₀ when L1.

(B) a fresh gas supply source connected to the upstream side of the gas supply path L1 and supplying fresh breathing gas to the gas supply path L1
02.

(C) exhausting gas from the mask M within ₀ when gas in the mask M ₀ is opened with opened when the gas is discharged closed and in the mask M ₀ when inhaled A gas discharging valve 03 and a carbon dioxide removing device 04 for reducing carbon dioxide in the gas discharged from the gas discharging valve 03. Gas supply path upstream of 01
A return path L2 for gas circulation returned to L1.

(3) Problems to be Solved by the Invention By the way, the fifth embodiment having the above-mentioned constitutional requirements (a) to (c)
In the respiratory gas supply system shown in the figure, when the gas supply valve and the gas discharge valve are configured by check valves, the gas supply valve and the gas discharge valve are operated by an air flow generated when the mask wearer breathes.

However, as described above, when the gas supply valve and the gas discharge valve are configured by a check valve that is operated by an airflow at the time of inhalation or expiration of the mask wearer, the operation of the check valve consumes respiratory energy of the mask wearer. There must be. In this case, there is a problem that a burden is imposed on the breathing of the mask wearer.

The present invention has been made in view of the above circumstances, and in a respiratory gas supply system including a gas supply path having a gas supply valve and a gas circulation return path having a gas discharge valve, the gas supply valve and the gas An object of the present invention is to provide an exhaust valve so as not to burden a breather of a mask wearer.

B. Configuration of the Invention (1) Means for Solving the Problem In order to solve the problem, the respiratory gas supply system of the present invention is opened when the gas in the mask is inhaled and is opened in the mask. A gas supply path for closing the mask when the gas is discharged, a gas supply path for supplying breathing gas into the mask when the gas supply valve is open, and a gas supply path connected to an upstream side of the gas supply path A fresh gas supply source for supplying fresh breathing gas to the gas supply path, being closed when gas in the mask is inhaled and opened and opened when gas is discharged into the mask. A gas discharge valve for discharging gas from the inside of the mask when the gas is removed, and a carbon dioxide removing device for reducing carbon dioxide in the gas discharged from the gas discharging valve. Charcoal A gas circulation return path for returning the elementally reduced gas to a gas supply path upstream of the gas supply valve, wherein the gas supply valve and the gas discharge valve are operated by a driving force. A respiratory detector which is constituted by a power actuated valve and detects inhalation of gas in the mask and discharge of gas into the mask is provided, and the gas supply valve and the gas discharge valve are operated by a detection signal of the respiration detector. It is characterized by doing so.

(2) Operation According to the present invention having the above-described structure, the gas supply valve operated by the driving force is operated by the detection signal of the respiration detector, and is opened when the gas in the mask is inhaled. It is closed when gas is discharged into the mask. Further, the gas discharge valve operated by the driving force,
It is activated by the detection signal of the respiration detector, and is closed when gas in the mask is inhaled and opened when gas is discharged into the mask. That is, the gas supply valve and the gas discharge valve are opened and closed by the driving force in synchronization with the respiration timing detected by the detection signal of the respiration detector. Therefore, the opening and closing operations of the gas supply valve and the gas discharge valve are performed without consuming the respiratory energy of the mask wearer.

(3) Embodiment Hereinafter, a first embodiment of the respiratory gas supply system according to the present invention will be described with reference to the drawings.

In FIG. 1, a respiratory gas supply system S includes a fresh gas supply source A such as an oxygen cylinder or an oxygen concentrator, and a gas supplied from the fresh gas supply source A into a mask M worn by a pilot. A supply path L1 and a gas circulation return path for circulating the gas in the mask M to the gas supply path L1.
L2 and.

The gas supply path L1 has a pressure regulating valve 1 and a gas supply valve 2 operated by an electromagnet. This gas supply valve 2 is attached to a mask M in this embodiment. Note that the gas supply valve 2 may be provided in the middle of a connection pipe connecting the mask M and the pressure regulating valve 1.

The gas circulation return path L2 has a gas discharge valve 3 and a carbon dioxide removing device 4. In this embodiment, the gas discharge valve 3 is attached to the mask M. However, the gas exhaust valve 3 may be provided in the middle of a connection pipe connecting the mask M and the carbon dioxide removing device 4.

The carbon dioxide removal device 4 includes a mask M in its flow path.
Is provided with a permeable membrane 4a having a property of selectively transmitting carbon dioxide in the exhaled breath discharged by the wearer, and the inside of the permeable membrane 4a communicates with a low-pressure source (not shown) through an exhaust passage 4b. doing. Examples of the permeable membrane 4a having the above properties include, for example, polydimethylsiloxane-based, polymethylpentene-based, polyphenylene oxide-based, cellulose acetate-based, polyimide composite membrane-based, silicone rubber-based membranes, and the like. Composite membranes are known, and are appropriately selected and used from these membranes.

An exhaust gas buffer cylinder 5 is connected to a connection path between the gas exhaust valve 3 and the carbon dioxide removal device 4 in the gas circulation return path L2. The piston 5a of the exhaust gas buffer cylinder 5 is connected by a link 8 to a disk 7 connected to the rotating shaft of the motor 6. The motor 6 is configured to reciprocate by a predetermined angle smaller than 180 degrees, and the disk 7 is also configured to reciprocate by a predetermined angle with the reciprocating rotation. And the disk 7
As the piston reciprocates, the piston 5a reciprocates and the volume of the exhaust gas buffer cylinder 5 changes.

The extremity inside the mask M is provided with a distal end 9a of a thermometer 9 having a very small heat capacity using a thermocouple, and a proximal end 9b of the thermometer 9 detects respiration outside the mask M. Connected to circuit 10. The temperature detector 9 and the respiration detection circuit 10 constitute a respiration detector 11 of this embodiment.

The respiration detection circuit 10 is configured by an amplification circuit using an operational amplifier or the like, and the temperature T _a of the tip 9 a of the temperature measuring body 9 is measured.
And a temperature difference T _a −T _b (see FIG. 2) between the temperature and the temperature T _b of the base end portion 9b are amplified to an appropriate value and output. In FIG.
_Tc is the temperature of the breathing gas supplied from the gas supply path L1 into the mask M. As can be seen from FIG. 2, when the gas worn by the mask wearer is discharged, a certain value (the value of the temperature of the gas discharged from the body of the mask M wearer) is maintained for a while after rising first. keep.

When the next mask M wearer begins to inhale gas, the temperature T _a gradually begins to decrease. This is because the respiratory gas having the temperature _Tc starts flowing into the mask M from the gas supply path L1. When some time from the start of the inhalation, held until temperature T _a of the temperature detector 9 tip portion 9a, the temperature T _c next to the gas of the gas supply passage L1, that value is then breathed discharged Is done.

An output signal of the respiration detection circuit 10, that is, a respiration detection signal is converted by an analog-digital (hereinafter, referred to as "AD") converter 15.
The signal is AD-converted and input to the microcomputer 16.

The microcomputer 16 includes a central processing unit CPU, a random access memory RAM, a read-only memory ROM, an input / output interface I / O, and the like.

The microcomputer 16 determines whether the breath of the wearer of the mask M is inhalation or inhalation from the digital value of the respiration detection signal input from the AD converter 15, and according to the determination. It outputs a gas supply valve control signal 16a, a gas discharge valve control signal 16b, and a motor control signal 16c.

The gas supply valve control signal 16a becomes “1” when the breath is inhaled, and is applied to the electromagnet of the gas supply valve 2 via the amplifier 17. At this time, the gas supply valve 2 is opened. Further, the gas discharge valve control signal 16b becomes “1” when the breath is discharged, and is applied to the electromagnet of the gas discharge valve 3 via the amplifier 18. At this time, the gas discharge valve 3 is opened.

The motor control signal 16c becomes "1" when the breath is inhaled and becomes "0" when the breath is exhaled. Then, the motor control signal 16c is input to the motor drive circuit 19. The output signal of the motor drive circuit 19 drives the motor 6, and when the motor control signal 16c is "1", rotates the motor 6 so that the piston 5a moves forward. When the motor control signal 16c is "0", the motor drive circuit 19 rotates the motor 6 so that the piston 5a moves backward.

Next, the operation of the first embodiment of the respiratory gas supply system of the present invention having the above-described configuration will be described.

The operation of this breathing gas supply system is started by pressing an operation start button (not shown) or the like.
When the operation is started, the digital value of the respiration detection signal T _a -T _b shown in FIG. 2 is input to the microcomputer 16 in accordance with the respiration of the wearer of the mask M.

At this time, the microcomputer 16 operates according to the flowchart shown in FIG.

The rate of change of T _a -T _b whether positive is determined in step 21. If yes, the process proceeds to step 22, wherein the gas supply valve control signal 16a is set to "0" and the gas discharge valve control signal 16b
Is “1” and the motor control signal 16 is “0”. Then, return to step 21. If the answer is no in step 21, the process proceeds to step 23.

Whether T _a -T _b ≧ T _o is determined in step 23. The T _o is substantially intermediate temperature between the temperature T _a of the breath that discharge temperature T _c and the mask M wearer's breathing gas supplied from the gas supply path L1 in the mask M (T _a + T _c) / 2 and the temperature
A value corresponding to the difference between T _b, is a value set in the microcomputer 16. Note that this T _o is enabled to change the settings according to usage. This step 23
The reason for providing is described below. That is, as can be seen from Figure 2, the rate of change of T _a -T _b even when the suction even when the discharge is 0
There are a period and a period of the change rate at the time of discharge is 0 is T _a -T _b ≧ T _o, the period of the change rate at the time of inhalation 0 is T _a -T _b <T _o. Therefore, by looking at magnitude relation between T _a -T _b and T _o, the rate of change it is possible to periods of 0, it is determined whether a period of time of inhalation whether a period of time of ejection.

If yes in step 23, step 24
Then, the gas supply valve control signal 16a is set to "0", the gas discharge valve control signal 16b is set to "1", and the motor control signal 16c is set to "0".
And Then, return to step 21. If the answer is no in step 23, the process proceeds to step 25.

By the way, “yes” in steps 21 and 23 described above means that the breathing of the wearer of the mask M is a period during which the inhaled gas is discharged. During this discharge period, the gas supply valve control signal 16a is "0", so that the gas supply valve 2 is closed, and the gas discharge valve control signal 16b is "1", so that the gas discharge valve 3 is opened, and the motor control is performed. Since the signal 16c is "0", the motor 6 operates to retract the piston 5a. At this time, the buffer cylinder 5
The gas discharged from the gas discharge valve 3 is accommodated in the buffer cylinder 5. The speed at which the volume of the buffer cylinder 5 increases is determined by the inner diameter of the buffer cylinder 5 and the rotation speed of the motor 6. Therefore, in this embodiment, the rate of increase in the volume of the buffer cylinder 5 is controlled by the gas discharge valve 3.
The inner diameter of the buffer cylinder 5 and the speed of the motor 6 are set so as to accommodate substantially half of the volume of gas discharged from the motor. Therefore, the gas discharge valve 3
Approximately half of the gas discharged from is stored in the buffer cylinder 5, and the other approximately half flows into the carbon dioxide removal device 4. Part of the gas flowing into the carbon dioxide removing device 4 is discharged from a discharge passage 4b to a low-pressure source (not shown) through a permeable membrane 4a through which the carbon dioxide is selectively transmitted. When the gas passes through the permeable membrane 4a, nitrogen, oxygen, and carbon dioxide contained in the gas dissolve on one surface of the permeable membrane 4a, diffuse inside the permeable membrane 4a, and diffuse on the other surface. Break away from At this time, since the permeable membrane 4a has a property of mainly transmitting carbon dioxide at a high ratio, the concentration of carbon dioxide in the gas that passes through the permeable membrane 4a and is discharged to the outside increases, and the permeable membrane 4a does not pass through the permeable membrane 4a. The carbon dioxide concentration of the gas circulated from the carbon dioxide removing device 4 to the gas supply path L1 decreases. Therefore, a gas having a high oxygen concentration is circulated through the gas supply path L1.

Then, the rate of change of T _a -T _b in step 25 whether the negative is determined. If yes, go to step 26,
The gas supply valve control signal 16a is "1", the gas discharge valve control signal 16b is "0", and the motor control signal 16c is "1".
Then, return to step 21. If no in step 25, the process proceeds to step 27.

Whether T _a -T _b <T _o is determined in step 27. If yes in step 27, step
28, the gas supply valve control signal 16a is set to "1", the gas discharge valve control signal 16b is set to "0", and the motor control signal 16c is set to "1". Then, return to step 21. Step 27
If the result is NO, the process returns to step 21.

By the way, the fact that the determination in steps 25 and 27 is yes means that the breathing of the wearer of the mask M is during the inhalation period. During this suction period, the gas supply valve control signal
Since 16a is "1", the gas supply valve 2 is opened, and the gas discharge valve control signal 16b is "0", so that the gas discharge valve 3
Is closed and the motor control signal 16c is "1" so that the motor 6 operates to advance the piston 5a. At this time, since the volume of the buffer cylinder 5 decreases, the gas stored in the buffer cylinder 5 at the time of the discharge (substantially half of the gas discharged from the gas discharge valve 3 at the time of the discharge) is removed by the carbon dioxide removing device. Flow into 4.
Then, similarly to the above, a gas having a high oxygen concentration is circulated through the gas supply path L1.

When the buffer cylinder 5 is provided in the gas circulation return path L2 as in the first embodiment, approximately half of the gas discharged from the gas discharge valve 3 at the time of breathing is removed.
, And the other half can be flowed into the carbon dioxide removing device 4 when breathing is inhaled. Therefore, in this case, the velocity of the gas permeating the permeable membrane 4a of the carbon dioxide removing device 4 can be reduced, so that the carbon dioxide removing efficiency can be improved.

Next, a second embodiment of the present invention will be described with reference to FIG.

In FIG. 4 showing the second embodiment, the same components as those in the first embodiment are denoted by the same reference numerals.

The second embodiment has the same configuration as that of the first embodiment except that the buffer cylinder 5 and the elements for driving the buffer cylinder 5 of the first embodiment are omitted.

The second embodiment has the same operation as the first embodiment except for the operation of the buffer cylinder 5 of the first embodiment.

As described above, the embodiments of the present invention have been described in detail. However, the present invention is not limited to the above embodiments, and various small designs can be made without departing from the present invention described in the claims of the utility model registration. It is possible to make changes.

For example, instead of connecting the discharge path 4b of the carbon dioxide removing device 4 to a low pressure source, it is also possible to provide a blower fan for discharging gas from the discharge path 4b, and it is also possible to provide a gas supply path L1 or a gas circulation path. It is possible to provide a blower fan at an appropriate position on the return path L2. In addition, pressure regulating valve 1
It is also possible to provide a buffer tank or an accumulator in the gas supply path L1 between the gas supply valve 2 and the gas supply valve L1.

Furthermore, whether the respiration of the mask wearer is inhaling or exhaling, instead of detecting the temperature of the exhalation and judging from the change in the detected temperature, the direction of the airflow at an appropriate position in the mask is determined. It is also possible to detect and judge from the detection direction of this air flow, and also to judge from the change in the pressure in the mask. As a means for detecting the temperature of the expired air, a temperature measuring resistor, a thermistor, or the like can be used instead of the thermocouple.

C. Effects of the Invention According to the above-described respiratory gas supply system of the present invention, a gas supply valve that opens when the mask wearer inhales breathing to supply respiratory gas into the mask and closes when breathing is discharged, And a gas discharge valve that opens when discharging the gas and discharges gas in the mask to the gas circulation return path and closes when breathing is inhaled. Since the discharge valves are activated, they do not burden the wearer of the mask. Therefore, the mask wearer can breathe easily.

[Brief description of the drawings]

FIG. 1 is an overall explanatory diagram of a respiratory gas supply system according to a first embodiment of the present invention, FIG. 2 is an explanatory diagram of a temperature change of gas in a mask, and FIG. 3 is a flowchart of a microcomputer used in the embodiment. FIG. 4 is an overall explanatory diagram of a respiratory gas supply system according to a second embodiment of the present invention, and FIG. 5 is an explanatory diagram of a prerequisite technology of the present invention. A: fresh gas supply source, L1: gas supply path, gas circulation return path L2, M: mask, 2: gas supply valve, 3: gas discharge valve,
4: Carbon dioxide removal device, 11: Respiratory detector

──────────────────────────────────────────────────続 き Continued on front page (58) Field surveyed (Int.Cl. ⁶ , DB name) A62B 7/06 A62B 7/14 B64D 13/00

Claims (1)

(57) [Scope of request for utility model registration] 1. A gas supply valve which is opened when gas in a mask is sucked and closed when gas is discharged into the mask, wherein the mask is opened when the gas supply valve is opened. A gas supply path for supplying a respiratory gas into the gas supply path, a fresh gas supply source connected to an upstream side of the gas supply path to supply a fresh respiratory gas to the gas supply path, and a gas in the mask being inhaled. When the gas is discharged into the mask, it is closed when it is opened, and is opened when the gas is discharged. A gas circulation return path having a carbon dioxide removal device for reducing carbon dioxide and returning the carbon dioxide reduced gas obtained by the carbon dioxide removal device to a gas supply path upstream of the gas supply valve. For breathing A body supply system, wherein the gas supply valve and the gas discharge valve are configured by a power actuated valve that operates by a driving force, and a breathing detector that detects inhalation of gas in the mask and discharge of gas into the mask. A gas supply system for breathing, wherein the gas supply valve and the gas discharge valve are operated by a detection signal of the respiration detector.