JP5930149B2 - Ventilator - Google Patents

Description

  The present invention relates to an artificial respirator that supplies a gas (inspired gas) when artificial respiration is given to a user (patient) by resuscitation.

  In recent years, automatic external defibrillators (AEDs) can be used by non-healthcare professionals such as doctors, paramedics, and nurses, and are widely used in places where people gather, such as airports, stations, and buildings. Arranged and helped increase lifesaving rate. Resuscitation must deal with cardiac and respiratory arrest. Although AED is effective for cardiac arrest, it is currently necessary to rely on artificial respiration (mouse-to-mouse method, etc.) for respiratory arrest. Thus, if small portable emergency ventilators that are easy to move are widely used together with AEDs, the lifesaving rate can be further increased.

WO2011-24383 publication

  On the other hand, when using a ventilator during resuscitation, it is necessary to secure the airway by bending the patient's back head and raising the chin. However, in the event of an emergency, especially when general citizens other than medical workers perform resuscitation, there is a high possibility that the airway will not be adequately secured, and appropriate resuscitation is performed even if a ventilator is used. Could have been difficult.

  Furthermore, in order to maintain the inspiratory gas supplied from the mask to the patient at a desired pressure, it is necessary to appropriately maintain the distance between the ventilator body and the mask attached to the patient. However, it has been difficult to always keep the distance between the ventilator body and the patient appropriate at the time of emergency response outside the medical field.

  In view of the circumstances as described above, an object of the present invention is to provide a ventilator that is small in size and can easily perform an appropriate resuscitation treatment.

In order to achieve the above object, a ventilator according to an embodiment of the present invention includes a mask, a respiration control unit, and a main body.
The mask can be worn on a patient.
The breathing control unit has a first state in which gas is delivered to the mask and a second state in which the patient exhaled from the mask is released and is connected to the mask.
The main body includes a first main body portion capable of maintaining the patient's head back-bending posture; a second main body portion adjacent to the first main body portion and where the respiratory control unit is disposed; including.

It is a perspective view which shows the structure of the ventilator which concerns on the 1st Embodiment of this invention. It is a top view which shows the structure at the time of using the ventilator which concerns on the 1st Embodiment of this invention for the patient who laid supine. It is sectional drawing which shows the structure of the support stand of the ventilator which concerns on the 1st Embodiment of this invention. It is the schematic which shows the whole ventilator which concerns on the 1st Embodiment of this invention. It is a schematic plan view which shows the structure of the main body of the ventilator which concerns on the 2nd Embodiment of this invention, (A) shows the aspect at the time of use, (B) has shown the aspect at the time of non-use. It is a schematic sectional drawing which shows the structure of the main body of the ventilator which concerns on the 2nd Embodiment of this invention, (A) is sectional drawing of the [B]-[B] direction of FIG. FIG. 5B is a cross-sectional view in the [C]-[C] direction of FIG.

A ventilator according to an embodiment of the present invention includes a mask, a respiratory control unit, and a main body.
The mask can be worn on a patient.
The breathing control unit has a first state in which gas is delivered to the mask and a second state in which the patient exhaled from the mask is released and is connected to the mask.
The main body includes a first main body portion capable of maintaining the patient's head back-bending posture; a second main body portion adjacent to the first main body portion and where the respiratory control unit is disposed; including.

  The ventilator can easily secure the patient's airway by having the first main body that can hold the patient's head bending posture. In addition, since the first main body and the breathing control unit are integrated, the distance from the breathing control unit to the mask attached to the patient during the resuscitation is short and almost constant regardless of the treatment status. Can be held. As a result, the inspiratory gas supplied from the respiratory control unit to the mask can be maintained at a desired pressure, and appropriate inspiratory gas can be supplied to the patient.

The shape of the first main body is not particularly limited as long as the shape can hold the patient's head bending posture. For example, the first body portion supports a first support portion that supports the patient's neck at a first height and the occipital region of the patient at a second height that is lower than the first height. And a second support portion.
By forming the first main body portion in this way, the patient's back of the head can be supported at a position lower than the neck, so that it is easy for the patient to maintain the back-bending posture and to secure the airway.

Furthermore, the second support portion may be formed as a concave surface having a bottom portion having the second height.
As a result, the patient's occipital region can be supported more stably.

  In one embodiment, the ventilator further includes a tank unit capable of storing a gas supplied to a patient, and the respiratory control unit includes a pressurizing pump, a valve mechanism, and a first passage. And a second passage. The pressurizing pump supplies gas to the internal space. The valve mechanism is disposed between the internal space and the mask, and can be switched from the first position corresponding to the first state and the first position corresponding to the second state. Possible second position. The first passage connects the pressurizing pump and the internal space. The second passage connects the internal space and the valve mechanism.

The main body may have an internal space and be configured as the tank portion.
As a result, the space of the tank part for storing the gas supplied to the patient can be omitted, and the apparatus can be miniaturized.

<First Embodiment>
[Configuration of ventilator]
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a perspective view showing a ventilator 100 according to an embodiment of the present invention, and FIG. 2 is a plan view showing a configuration when the ventilator 100 is used for a patient P in a supine state. . FIG. 3 is a schematic cross-sectional view in the [A]-[A] line direction in FIG.

  The ventilator 100 includes a mask 2, a main body 10, and a respiratory control unit 22. The breathing control unit 22 has a housing 23 indicated by a broken line in FIG. FIG. 2 shows a state in which the upper portion of the housing 23 is removed for the sake of explanation.

(Body)
The main body 10 has an internal space S in which intake gas can be stored, and is formed in a generally rectangular plate shape as a whole, and is gripped by a user at one side during transportation. A handle 28 is provided. The size of the main body 10 is not particularly limited, and is, for example, 36 cm wide and 56 cm long.

  The material constituting the main body 10 is not particularly limited, and for example, fiber reinforced plastic (FRP) can be adopted. By configuring with such a material, it becomes possible to stably support the occipital region of the patient P as will be described later. In addition, a series of resuscitation procedures such as heart massage can be performed stably.

  The main body 10 includes a first main body portion R1 and a second main body portion R2. The first main body R1 constitutes a support base 11 that supports the head of the patient P who is supine. In this embodiment, the support base 11 is formed as a pillow that supports the back of the head of the patient P so as to maintain the back of the head. The second main body R2 constitutes a base 15 that supports various devices constituting the respiratory control unit 22.

  As shown in FIG. 3, the main body 10 has a first surface (back surface) 13 installed on the ground or floor and a second surface (front surface) 14 facing the first surface (back surface) 13. The first surface 13 is formed as a flat surface, but is not limited thereto. The second surface 14 is formed with a structural surface that can guide the patient's head backward bending posture in the region of the first main body portion R1, and is substantially flat in the region of the second main body portion R2. Formed with.

  The support base 11 includes a first support part 141 and a second support part 142. The first support part 141 supports the neck (or neck and shoulders) of the patient P, and the second support part 142 supports the back of the patient P. In the present embodiment, the first support portion 141 is formed with an inclined surface whose thickness gradually decreases from one end E1 of the main body 10 toward the center portion, and the first support portion 141 is based on the first surface 13 as an end. Part E1 has a maximum height H1. The second support portion 142 is formed as a concave surface adjacent to the inclined surface, and the bottom portion of the concave surface has a height H2 lower than the height H1 with respect to the first surface 13.

  By configuring the support base 11 as described above, the first support portion 141 can support the neck of the patient P at the height H1, and the second support portion 142 can raise the back of the patient P at the height. It can be supported at a height H2 lower than H1. Thereby, when the support base 11 supports the head of the patient P, it becomes possible to stably hold the head backward bending posture in which the airway can be easily secured. Therefore, the treatment with the ventilator 100 is more appropriate. And can be performed effectively.

  In addition, the shape of the support base 11 is not restricted to the above-mentioned example, For example, all the formation areas of the support base 11 may be formed with the inclined surface mentioned above. Moreover, the magnitude | size of height H1, H2 is not specifically limited, Each can be set to an appropriate magnitude | size. Further, when the ventilator 100 is not used, the mask case 27 is disposed in a partial region of the first main body R1 as shown in FIG. When the ventilator 100 is in use, the mask case 27 is removed as shown in FIG. 2, so that the second support part 142 is exposed and the back of the patient P can be supported.

  The internal space S of the main body 10 may be formed across each region of the first main body portion R1 and the second main body portion R2, as shown in the figure, or the first main body portion R1 or the second main body portion. It may be formed only on R2. As described above, the internal space S is for storing the gas for inhalation sent to the patient P, and the main body 10 having the internal space S functions as the tank unit 4 that accumulates the gas at a predetermined pressure. It also has.

(Respiration control unit)
FIG. 4 is a schematic diagram showing the entire ventilator 100. The respiration control unit 22 includes a pressurizing pump 1, an inspiratory solenoid valve 5, an exhalation solenoid valve 8, a first pipe (first passage) 31, and a second pipe (second passage). 32 and the control unit 17. The inspiratory solenoid valve 5 and the exhalation solenoid valve 8 constitute a valve mechanism V. The breathing control unit 22 has a housing 23 and is disposed on the surface 14 of the second main body R2. Hereinafter, the configuration of the breathing control unit 22 will be described with reference to FIGS. 1 and 4.

The pressurizing pump 1 has a suction port and a discharge port connected to the tank unit 4 via the first pipe line 31. The pressurizing pump 1 sucks and pressurizes air (outside air) from the suction port, and supplies it to the internal space S of the main body 10. As the pressurizing pump 1, for example, a diaphragm type pump (for example, product of ULVAC KIKOH CO., LTD. (Trade name “DFC-4-2”)) can be used. Such a pressurizing pump 1 has a discharge flow rate of 5.75 NL / min at a pressure of 40 kPa, for example, at a rotational speed of 3100 min ^-1 (rpm). The first pipe line 31 is configured by a pipe member that penetrates the surface wall portion of the second main body R2 and communicates between the discharge port of the pressurizing pump 1 and the internal space S.

  The pressurizing pump 1 is driven by a DC brushless motor 1M. The motor 1M is supplied with driving power from the storage battery 20 via the driver 16, and operates the pressure pump 1 at an arbitrary rotational speed by changing the output waveform based on a command from the control unit 17.

  The intake gas in the tank unit 4 is stored in a pressurized state so that it can be supplied immediately. Generally, a diaphragm pump has an intake valve and an exhaust valve. Therefore, if the tank is stopped while being pressurized, the discharge valve is fixed by being pressed by the pressure, and intake gas can be generated at startup. There is a risk of disappearing. Therefore, in the present embodiment, a check valve 29 for preventing the backflow of the intake gas from the tank unit 4 to the pressurizing pump 1 is attached in the first pipeline 31. Further, an air release solenoid valve 9 is attached between the pressurizing pump 1 and the check valve 29 so that the pressure is released when the pump is stopped, and the pressure of the intake gas is not applied to the discharge valve. Yes. The air release solenoid valve 9 is driven by the control unit 17.

  The capacity | capacitance of the tank part 4 is not specifically limited, For example, it is 2L. The main body 10 has a relief valve 30 connected to the internal space S. The relief valve 30 is opened when the internal pressure of the tank unit 4 becomes, for example, 40 kPaG or more, thereby preventing overloading of the pressurizing pump 1.

  The tank unit 4 is connected to the intake solenoid valve 5 via the second pipe line 32. The pressure reducing valve 6 and the flow meter 7 are attached to the second conduit 32, and the downstream side of the pressure reducing valve 6 is maintained at 104.26 kPa (3 kPaG), for example. The second pipe line 32 is constituted by, for example, a pipe member that penetrates the surface wall portion of the second main body R2 and communicates between the internal space S and the intake electromagnetic valve 5.

  The intake solenoid valve 5 functions as a supply valve for sending the intake gas in the tank 4 to the mask 2. The inhalation solenoid valve 5 has a communication position (first position) and a blocking position (second position), and is switched to a communication position during inspiration and to a blocking position during expiration. FIG. 4 shows a state where the intake solenoid valve 5 is in the cutoff position. Switching of the intake solenoid valve 5 is controlled by the control unit 17. The intake gas that has passed through the intake solenoid valve 5 is sent to the mask 2 via the third conduit 25.

  The third conduit 25 connects between the intake solenoid valve 5 and the mask 2. The third conduit 25 may be at least partially configured by a flexible piping member, and for example, a piping member made of an accordion-shaped resin material may be employed. A portion of the third conduit 25 is accommodated in the housing 23 and the mask case 27 as shown in FIG. 1 when not in use, and the mask case 27 is removed as shown in FIG. It is pulled out to a length that can be attached to P (for example, about 50 cm).

  A filter 12, a relief valve 43, and a pressure gauge 14 are attached to the third pipeline 25. The relief valve 43 is opened when the third conduit 25 reaches a predetermined abnormal pressure value, such as when the patient P's airway is blocked.

  In addition, a fourth pipe 26 that communicates with the exhalation solenoid valve 8 is connected to the third conduit 25. The exhalation solenoid valve 8 has a communication position (second position) and a blocking position (first position), and is switched to a blocking position during inspiration and to a communication position during expiration. FIG. 4 shows a state when the exhalation solenoid valve 8 is in the communication position. Switching of the exhalation solenoid valve 8 is controlled by the control unit 17.

  In the present embodiment, since the respiratory control unit 22 is installed on the main body 10, the third conduit 25 during use can be shortened. Further, since the support base 11 and the respiration control unit 22 are provided on the same main body 10, the distance between the inspiratory solenoid valve 5 and the mask 2 can be kept substantially constant during treatment. It becomes. Thereby, fluctuations in the supply pressure, supply amount, etc. of the intake gas to the mask 2 due to the change in the length of the third conduit 25 can be suppressed.

  The mask 2 has a shape and size that can cover the mouth and nose of the patient P. The mask 2 may include a holder that can hold the wearing state when the mask 2 is worn on the patient P. When not in use, the mask 2 is housed in a mask case 27 disposed on the second surface 14 of the main body 10 together with a part of the third conduit 25 as shown in FIG. At the time of use, the mask case 27 is removed from the second surface 14 and the mask 2 is attached to the patient P as shown in FIG.

  The mask case 27 is formed of a cloth, for example, and the mask 2 and the third conduit 25 can be taken out from the inside by a fastener or the like. It is also possible to accommodate a plurality of masks for adults, children, etc. inside the mask case 27 so that different masks can be selected depending on the patient P.

  The control unit 17 constitutes a control system for the ventilator 100. The control unit 17 is configured by a computer and controls driving of the pressurizing pump 1 (driver 16), the inspiratory solenoid valve 5, the exhalation solenoid valve 8, and the open air solenoid valve 9. The control unit 17 controls the switching of the inspiratory solenoid valve 5 and the exhalation solenoid valve 8 in synchronization, thereby delivering the inspiratory gas to the patient P (first state) and discharging the exhaled breath from the patient P. The state to be performed (second state) is alternately switched.

  Further, the control unit 17 monitors the operation of the gas supply system based on the outputs of the flow meter 7 and the pressure gauge 14. For example, when a predetermined pressure is not detected by the pressure gauge 14 at the time of inspiration, the control unit 17 determines that the mask 2 is not mounted correctly and outputs a predetermined announcement via the display unit 18 or the speaker 19, so that the user Call attention to. On the other hand, the controller 17 closes both the inspiratory solenoid valve 5 and the expiratory solenoid valve 8 after a predetermined number of breaths has elapsed. By monitoring the output of the pressure gauge 14 at that time, recovery of the independent breathing of the patient P may be detected.

  The display unit 18 is configured by a liquid crystal display, an organic EL display, or the like, and display control is performed by the control unit 17. The display unit 18 displays the state of the patient P and the wearing state of the mask based on the output of the control unit 17. Further, the control unit 17 causes the display unit 18 to display the operation procedure of the ventilator 100 (mask wearing procedure, resuscitation procedure, etc.). At this time, voice guidance using the speaker 19 may be performed simultaneously. As a result, emergency treatment by general citizens other than medical workers becomes possible.

  The ventilator 100 is detachably attached to a base 24 installed at a predetermined place indoors or outdoors, and is removed from the base 24 and moved to the place of use when in use. At this time, by using the handle 28 provided on the main body 10, the transfer work of the ventilator 100 is facilitated.

  The base 24 includes a charger 33 connected to a power supply source such as a commercial power source. The housing 23 has a built-in storage battery 20 constituting a power supply system, and can be charged via the conductor 21 by being installed on the base 24. As the storage battery 20, for example, a nickel hydride battery (24V) having a capacity of 3AH can be used.

  Next, the usage method and operation | movement of the ventilator 100 of this embodiment comprised as mentioned above are demonstrated.

[Usage and operation of ventilator]

  When not in use, the mask case 27 is disposed on the second surface 14 of the main body 10 and accommodates the mask 2 and the third conduit 25. As shown in FIG. 4, the inhalation solenoid valve 5 and the exhalation solenoid valve 8 are in the cutoff position and the communication position, respectively. In the tank portion 4, intake gas having a predetermined pressure (for example, 141.3 kPa) is stored in advance. The gas pressure between the pressure reducing valve 6 and the intake solenoid valve 5 is maintained at, for example, 104.26 kPa.

  At the time of use, the first surface 13 of the main body 10 is set so as to face an arbitrary plane at the place of use. Then, the mask case 27 is removed from the second surface 14, and the mask 2 and the third conduit 25 are taken out from the mask case 27. The patient's P neck is supported by the first support portion 141 of the support base 11 and the occipital region is supported by the second support portion 142. Thereby, the patient's P head bending posture is maintained and an airway is ensured. Thereafter, the mask 2 is attached to the patient P.

  The control unit 17 controls driving of the inspiratory solenoid valve 5 and the exhalation solenoid valve 8 to alternately switch the supply of the inspiratory gas to the patient P and the discharge of the exhaled breath. In the present embodiment, the inspiratory solenoid valve 5 and the exhalation solenoid valve 8 are driven according to a predetermined breathing pattern. For example, for a breathing interval of 5 seconds, the inspiration time is 1.66 seconds and the expiration time is 3.33 seconds. The control unit 17 continuously operates the pressurizing pump 1 at a constant rotation speed (for example, 3100 rpm) simultaneously with the start of use.

  The pressurizing pump 1 replenishes the amount of gas consumed at the time of inspiration while maintaining the minimum inspiratory pressure (for example, 104.26 kPa) until the expiration time. Therefore, the tank unit 4 always has a gas amount necessary for intake.

  As described above, since the main body 10 includes the support base 11 (first main body portion R1) that can hold the patient's P head flexion posture, it is easy to secure the patient P's airway. Even if it is an emergency response treatment by the general public other than medical personnel, appropriate and effective treatment can be performed.

  In addition, since the respiration control unit 22 is disposed in the main body 10, the distance from the respiration control unit 22 to the mask 2 attached to the patient P can be kept substantially constant during resuscitation, and the third The pipe line 25 can be configured to be short. Therefore, the intake gas supplied from the respiratory control unit 22 to the mask 2 can be maintained at a desired pressure.

  Moreover, since the tank part 4 and the main body 10 are comprised integrally, the ventilator 100 can be reduced in size. Accordingly, the ventilator 100 having excellent portability can be provided, and the degree of freedom of the installation location can be increased.

<Second Embodiment>
5 and 6 are diagrams showing the configuration of the main body 60 of the ventilator 300 according to one embodiment of the present invention. FIG. 5 is a schematic plan view, and FIG. 6 (A) is a diagram of FIG. FIG. 6B is a schematic cross-sectional view in the [C]-[C] direction of FIG. 5B. 5 (A) and 6 (A) each show a mode when the ventilator 300 is used in the main body 60, and FIGS. 5 (B) and 6 (B) each show a mode when not used. ing. 5 and 6, the structure other than the main body 60 of the ventilator is omitted. In the present embodiment, description of parts common to the first embodiment will be omitted, and different parts will be mainly described.

  The main body 60 includes a first main body R10, a second main body R20, a third main body R30, a fourth main body R40, a fifth main body R50, and a sixth main body R60. And have. Each main body is formed in a substantially rectangular plate shape as a whole. The first main body R10 and the second main body R20 are connected via a third main body R30, and one side of the first main body R10, one side of the third main body R30, the second One side of the main body R20 and one side of the third main body R30 are connected to each other by a hinge or the like so as to be rotatable. Further, three sides of the second main body R20 except one side connected to the third main body R30 are one side of the fourth main body R40, the fifth main body R50, and the sixth main body R60, respectively. And are pivotally connected by a hinge or the like.

  The first main body R10 is configured similarly to the first embodiment. That is, in use, it forms a support base that supports the head of the patient who is supine, and is formed as a pillow that holds the back of the head by supporting the back of the patient. The second main body R20 constitutes a base that supports various devices constituting the respiratory control unit.

  In addition, the site | part which forms the tank part which can store the gas for inhalation is not restrict | limited in particular. For example, it can be formed in the internal space of the first main body R10 or the internal space of the second main body R20. Thereby, the ventilator 100 can be reduced in size. Moreover, it is also possible to arrange | position as an independent structure on 2nd main-body part R20.

  When not in use, as shown in FIGS. 5B and 6B, the main body 60 is configured as a casing 73 having a substantially rectangular parallelepiped shape. For example, the first main body R10 is configured as a lid on the upper portion of the housing 73, and is accommodated with the structural surface for supporting the patient's head facing inward. The second main body R20 constitutes the base of the housing 73. In addition, the third main body R30, the fourth main body R40, the fifth main body R50, and the sixth main body R60 are each configured as a side wall of the housing 73.

When not in use, three sides of the first main body R10 other than the one connected to the third main body R30 are connected to the fourth main body R30, the fifth main body R50, and the sixth main body R60. Each side can be engaged with each other. Moreover, it can comprise similarly between each main-body part which comprises a side wall so that engagement is possible. The method of engagement is not particularly limited, and for example, a clasp or the like can be employed. Accordingly, the structure can be maintained even when the housing 73 is moved, and the portability of the ventilator 300 can be improved.

  The main body 60 configured as described above can be developed into a plate shape when used. Here, a method for expanding the main body 60 will be described. First, the second main body R20 of the casing 73 when not in use is installed on the ground or floor surface of the place of use. And the clasp etc. with 1st main-body part R10, 4th main-body part R40, 5th main-body part R50, and 6th main-body part R60 are each removed, and 1st main-body part is 3rd main-body part R30. Rotate about 90 ° with respect to. As a result, the upper portion of the housing 73 is opened. Then, the third main body R30 is rotated about 90 ° with respect to the second main body R20. As a result, the first main body R10 and the third main body R30 are unfolded and installed at the place of use. Further, the fourth main body portion R40, the fifth main body portion R50, and the sixth main body portion R60 are rotated about 90 ° with respect to the second main body portion R20, respectively. Thereby, the main body 60 can be developed in a plate shape as a whole as shown in FIGS. 5 (A) and 6 (A).

  In the ventilator 300 having the main body 60 as described above, the same effect as that of the first embodiment can be obtained. Furthermore, since the first main body R10 as the support base is configured as a lid of the housing 73, the ventilator can be reduced in size and a ventilator excellent in portability can be provided. .

  Note that the fourth main body R40, the fifth main body R50, and the sixth main body R60 are not expanded even when in use, and are configured to be side walls of the housing that covers the three surfaces around the breathing control unit. It is also possible. In addition, the fourth main body R40, the fifth main body R50, and the sixth main body R60 can be configured to be removable from the second main body R20 during use, or omitted as necessary. You can also

  The embodiment of the present invention has been described above, but the present invention is not limited to this, and various modifications can be made based on the technical idea of the present invention.

  For example, in the above embodiment, the example in which the respiratory control unit 22 is disposed on the top side of the patient P supported by the main body 10 has been described. A breathing control unit may be arranged.

  In the above embodiment, although the 2nd support part was formed with the concave surface, it is not restricted to this, You may form with a plane. Further, the first main body R1 may be formed in a size that can support not only the back and neck of the patient P but also the shoulder or back.

  Moreover, the 1st surface 13 which is the back surface side of the main body 10 is not restricted to a plane, What is necessary is just a shape which can install the main body 10 stably in a use place, for example, a concave surface may be sufficient. In addition, a plurality of protrusions (leg portions) may be disposed on the first surface.

  The mask case 27 can be omitted as necessary. In this case, for example, the mask 23 may be housed in the housing 23.

  The breathing pattern in the breathing control unit, the number of breaths per unit time, the amount of inspiratory gas, the minimum inspiratory pressure, etc. can be changed as appropriate, and an appropriate pump can be selected as a pressurizing pump according to these conditions. it can.

  In the above embodiment, the pair of two-port two-position electromagnetic valves 5 and 8 are used as a valve mechanism for switching between inspiration and expiration. However, the present invention is not limited to this. For example, it has a first position for sending intake gas from the tank part to the mask side, a second position for blocking between the tank part and the mask, and a third position for opening the mask to the atmosphere. A port 3 position solenoid valve may be used as the valve mechanism.

DESCRIPTION OF SYMBOLS 1 ... Pressurizing pump 2 ... Mask 4 ... Tank part 5 ... Inhalation solenoid valve 8 ... Exhalation solenoid valve 10, 60 ... Main body 22 ... Respiration control unit 23, 73 ... Housing 31 ... 1st Of pipe 32 ... second pipe 100, 300 ... ventilator R1, R10 ... first main body R2, R20 ... second main body S ... inner space V ...・ Valve mechanism D ・ ・ ・ Pipe member

Claims (4)

A mask that can be worn by the patient;
A respiration control unit having a first state for delivering gas to the mask and a second state for releasing the patient's exhaled air that is expelled from the mask and connected to the mask;
A main body including a first main body capable of maintaining the patient's back-bending posture; and a second main body adjacent to the first main body and in which the respiratory control unit is disposed; ,
A mask case disposed in the main body adjacent to the breathing control unit and capable of accommodating the mask;
A tank portion capable of storing gas supplied to the patient, and
The respiratory control unit is
A pressure pump for supplying gas to the tank part;
A second position that is disposed between the tank portion and the mask and that can be switched from the first position corresponding to the first state and the first position corresponding to the second state. A valve mechanism having a position;
A first passage connecting the pressurizing pump and the tank unit;
A second passage connecting the tank portion and the valve mechanism;
A conduit connecting between the valve mechanism and the mask;
Further comprising
The valve mechanism is disposed at a position closer to the mask case than any of the pressurizing pump, the first passage, and the second passage of the respiratory control unit,
The mask case is a respirator configured to be capable of accommodating the mask in a state of being connected to the conduit . The ventilator of claim 1,
The first body part is:
A first support for supporting the patient's neck at a first height;
A ventilator having a second support for supporting the occipital region of the patient at a second height lower than the first height. A ventilator according to claim 2,
The second support portion is formed of a concave surface having a bottom portion having the second height. The ventilator according to any one of claims 1 to 3 ,
The main body is capable of storing a gas supplied to the patient, and has an internal space formed over each region of the first main body portion and the second main body portion, and the patient A ventilator configured as the tank unit that accumulates the gas supplied to the tank at a predetermined pressure .

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