JP2007327716A - Humidifier - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a humidifier capable of satisfactorily humidifying gas to be humidified and effectively suppressing its pressure fluctuation. <P>SOLUTION: A gas-water permeable humidifying guide member 7 is held in a humidifying container 8 filled with humidifying liquid. A humidifying pipe 6 is held in the humidifying guide member 7. The gas 12 to be humidified is jetted into the humidifying guide member 7 from gas jet pores of the humidifying pipe 6. Intense foaming is suppressed by the damper action of the humidifying guide member, and a part below the liquid level of the humidifying guide member is degraded in gas permeability to attain excellent humidification. Further, since pressure fluctuation can be suppressed, humidified gas always with almost constant pressure can be taken out. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention includes a humidifying container such as a humidifying bottle filled with a humidifying liquid such as water or medicine-filled water, and a humidifying pipe accommodated in the humidifying container, and the humidifying pipe preferably includes a plurality of humidifying pipes. It has a gas ejection pore and is configured to be able to introduce a humidified gas such as air or oxygen-enriched air, and the humidified gas introduced into the humidified pipe is discharged from the humidified pipe into the gas jet. It is related with the humidifier comprised so that it may move in the said humidification container through the pore for use.

  Conventionally, an artificial bottle comprising a humidifying bottle filled with a humidifying liquid such as water or medicine-filled water, a humidifying pipe accommodated in the humidifying bottle, and a heating cylinder accommodated in the humidifying pipe. Respiratory warming humidifiers are known. In this conventional warming humidifier, the humidifying pipe has a large number of gas ejection pores near its lower end, and introduces a gas to be humidified (ie, humidified gas) into the interior. Configured to get. In the conventional humidifier, the humidified gas introduced into the humidifying pipe moves from the humidifying pipe into the humidifying bottle through the gas jetting pores. The inside rises while being humidified by the humidifying liquid, and is taken out from the upper end of the humidifying bottle as humidified gas.

  According to the conventional warming humidifier configured as described above, the humidified gas can be warmed by the warming cylinder, and thus the warmed and humidified gas is taken out from the humidifying bottle as patient inhalation. be able to. Further, since the humidified gas in the humidifying pipe can be ejected vigorously from the gas ejection pores, the humidified gas can sufficiently bubble the humidifying liquid in the humidifying bottle, Furthermore, the humidified gas can be sufficiently humidified in the humidifying bottle.

  However, in the case of the conventional humidifier for a ventilator configured as described above, the humidified gas that is vigorously ejected from the gas ejection pores causes the humidifying liquid to be violently bubbled. For this reason, when this humidified gas is supplied to the patient as the patient's inspiration, the pressure of the inhalation pressure gauge fluctuates violently due to the above-mentioned intense foaming. Measurements can be difficult, and the patient may not be able to supply the patient with an almost constant pressure of inspiration that is desirable for the patient.

  The present invention is to make it possible to effectively correct the above-mentioned drawbacks of the above-mentioned conventional humidifier for a ventilator with a relatively simple configuration.

The present invention includes a humidifying container such as a humidifying bottle filled with a humidifying liquid such as water or medicine-filled water, and a humidifying pipe accommodated in the humidifying container, and the humidifying pipe preferably includes a plurality of humidifying pipes. It has a gas ejection pore and is configured to be able to introduce a humidified gas such as air or oxygen-enriched air, and the humidified gas introduced into the humidified pipe is discharged from the humidified pipe into the gas jet. In the humidifier configured to move into the humidification container through the pore for use, the humidification guide member further accommodated in the humidification container, wherein the humidification guide member has air permeability and water permeability. And a humidifier, wherein the humidifying pipe is configured to be accommodated in the humidifying guide member.

  In the present invention, it is preferable that the humidifying guide member is composed of a three-dimensional skeleton structure having continuous pores. In the present invention, it is preferable that the upper half portion of the humidifying guide member is thinner than the lower half portion of the humidifying guide member. Moreover, in this invention, it is preferable that the said humidifier is comprised as a heating humidifier by accommodating a heating cylinder in the said humidification pipe. Furthermore, in the present invention, it is preferable that the humidifier is for a ventilator to be mounted on a ventilator body in order to constitute a ventilator.

  According to the present invention, even if the humidified gas that is vigorously ejected from the gas ejection pores of the humidifying pipe into the humidifying guide member tries to bubble the humidifying liquid vigorously in the humidifying guide member, the air permeability and the passage are improved. Due to the damper action of the humidifying guide member having water, it is suppressed that the humidified gas bubbles the humidifying liquid violently, so that quiet foaming is performed. In addition, the portion below the actual liquid line of the humidifying guide member having air permeability and water permeability is infiltrated with the humidifying liquid, and the air permeability is extremely reduced. Alternatively, all of them move from the humidifying guide member to the humidifying container after passing through the actual liquid line. Therefore, the humidified gas can be favorably humidified in the humidifying guide member, so that the humidified humidified gas can be always taken out from the humidifying container. Moreover, since the intense pressure fluctuation of the humidified gas can be effectively suppressed, the humidified gas having a substantially constant pressure can be always taken out from the humidified container.

  Further, according to the invention of claim 2, since the humidifying guide member is composed of a three-dimensional skeleton structure having continuous pores, the damper action against the humidified gas by the humidifying guide member is satisfactorily exhibited. The For this reason, since the humidified gas is well suppressed from vigorously bubbling the humidifying liquid in the humidifying guide member, the humidified gas taken out from the humidifying container can be further humidified and its pressure can be increased. The fluctuation can be more effectively suppressed.

  According to the third aspect of the invention, the lower half portion of the humidifying guide member is thick, so that the damper action against the humidified gas by the humidifying guide member is sufficiently exhibited. For this reason, it is possible to effectively humidify the humidified gas taken out from the humidifying container, because the humidified gas effectively suppresses the humidifying liquid from foaming vigorously in the humidifying guide member. Pressure fluctuation can be more effectively suppressed. Moreover, since the upper half of the humidifying guide member is thin enough to allow the humidified gas to pass therethrough, the humidified gas that has passed through the actual liquid line can be favorably moved from the humidifying guide member into the humidifying container. it can.

  Moreover, according to the invention which concerns on Claim 4, since humidified gas can be heated with a heating cylinder, the heated and humidified gas can be taken out from the said humidification container.

  Furthermore, according to the fifth aspect of the present invention, it is possible to supply the patient with inhaled air that is well humidified and always has a substantially constant pressure.

  Next, one example in which the present invention is applied to a warming humidifier for a ventilator is described in “1, Schematic configuration of the entire warming humidifier”, “2, Configuration of the warming humidification mechanism” and “3, The description will be made with reference to the drawings, divided into items "operation of the warming humidifier".

1. Schematic configuration of whole heating humidifier A warming humidifier (in other words, a humidifier combined with a warmer) 1 is attached to a ventilator body 3 to constitute the ventilator 2 shown in FIG. For the ventilator to be worn. As shown in FIGS. 1 and 2, the warming humidifier 1 includes a warming humidifier body 4 and a plurality of accessories that are detachably attached to the warming humidifier body 4. Yes. The plurality of accessories includes a heating and humidifying mechanism 9 including a heating cylinder 5, a humidifying pipe 6, a humidifying guide member 7 and a humidifying bottle (in other words, a humidifying container) 8, and an exhaust pipe 10. Contains. The specific configuration of the heating and humidifying mechanism 9 will be described in detail in “2, Configuration of the heating and humidifying mechanism” in the next section.

As shown in FIGS. 1 and 2, the warming humidifier body 4 may have a base block 11 made of a metal such as an aluminum alloy or other suitable material. The base block 11 is provided with a plurality of gas passages and a plurality of valves. The plurality of gas passages can include those described in the following items (a) to (e), as shown in FIGS.
(A) Gas extending from the gas inlet 13 through which oxygen-enriched air (in other words, intake gas) 12 fed from the ventilator main body 3 is introduced to the vicinity of the upper end of the heating and humidifying mechanism 9 Supply passage 14,
(B) an intake passage 19 extending from the vicinity of the upper end of the warming / humidifying mechanism 9 through the switching valve 15, the emergency air valve 16 and the emergency manual valve 17 to the intake outlet 18;
(C) a relief gas passage 22 configured as a bypass of the intake passage 19 and provided with a relief valve 21;
(D) An expiratory passage 25 extending from the expiratory inlet 23 to the expiratory outlet 24 through the switching valve 15, and (e) an emergency manual valve 61 configured as a bypass of the expiratory passage 25 and provided. Gas passage 62.

  The ventilator main body 3 that sends the oxygen-enriched air 12 to the gas inlet 13 as described in the above section (a) includes a mixer 26, a regulator 27, and an electromagnetic valve 28 as shown in FIG. Then, the mixer 26 supplies the oxygen-enriched air 12 to the regulator 27 by mixing the oxygen 31 and the air (in other words, the atmosphere) 32 supplied to the artificial absorber body 3. Further, the regulator 27 adjusts the pressure and flow rate of the oxygen-enriched air 12 supplied thereto, and then supplies the oxygen-enriched air 12 to the electromagnetic valve 28. The oxygen-enriched air 12 sent out from the electromagnetic valve 28 is supplied to the gas inlet 13 of the warming humidifier body 4.

  The exhalation discharge pipe 10 can be screwed and fixed to the base block 4. The exhalation discharge pipe 10 is formed with an exhalation discharge hole 33 communicating with the exhalation discharge port 24 of the exhalation passage 25 of the base block 4. Further, the exhalation discharge hole 33 can be provided with a silencer function that can mute the discharge sound of the exhalation 34.

  In FIG. 1 and FIG. 2, reference numeral 20 denotes a liquid injection port for pouring a humidifying liquid 29 such as water or drug-containing water into the humidifying bottle 8. Reference numeral 30 denotes an air inlet for supplying the air 32 guided through the air passage 63 of the ventilator main body 3 slightly before the expiratory outlet 24 of the expiratory passage 25. The air 32 introduced from the air introduction port 30 is supplied as a jet flow slightly before the exhalation discharge port 24 of the exhalation passage 25 through a gas passage (not shown) provided in the base block 11. For this reason, the exhalation 34 becomes negative pressure and is discharged well from the exhalation discharge port 24 to the exhalation discharge hole 33 of the exhaust pipe 10. Reference numeral 38 denotes a positioning protrusion that is fitted into a positioning hole (not shown) of a case (not shown) of the ventilator main body 3. Reference numeral 39 denotes a rotary knob for adjusting the opening pressure of the relief valve 21. Further, reference numeral 40 denotes a rotation of a mounting screw (not shown) that is screwed into a female screw portion provided in the case of the ventilator body 3 when the base block 11 is attached to or removed from the case. It is a rotary knob to make it.

2. Configuration of the heating / humidifying mechanism The upper end of the heating cylinder 5 of the heating / humidifying mechanism (in other words, the humidifying mechanism serving as the heating mechanism) 9 is, as shown in FIGS. It is fixedly attached to the holder 64. The outer cylinder 35 of the heating cylinder 5 may be made of a metal such as stainless steel or other suitable material, and has a bottomed and substantially cylindrical shape such as a cylindrical shape, or other hollow body shape (illustrated). In this embodiment, it may be substantially in the shape of a test tube. In addition, a heater wire 36 made of nickel-chromium alloy or the like is disposed in the outer cylinder 35, and a sealing material 37 made of magnesium oxide or the like may be sealed therein. Further, the pair of upper end portions 36a and 36b of the heater wire 36 may be subjected to sealing treatment as necessary after being subjected to lead wire processing.

  As shown in FIGS. 2 and 4, the upper end portion 41 of the humidifying pipe 6 of the heating and humidifying mechanism 9 is fitted to the outer periphery of the holder 64 to which the outer cylinder 35 of the heating cylinder 5 is attached. The base block 11 is detachably attached. Therefore, since the humidifying pipe 6 surrounds almost the entire heating cylinder 5, the heating cylinder 5 and the humidifying pipe 6 have a double structure as a whole. In this case, the outer bottom surface of the outer cylinder 35 is preferably slightly raised from the inner bottom surface of the humidifying pipe 6. The humidifying pipe 6 has a substantially cylindrical shape such as a substantially cylindrical shape whose inner diameter is relatively large from the upper end to the middle, relatively small from the middle to the lower end and has a relatively large outer diameter, and other hollow body shapes. And an intermediate portion 42 having a substantially cylindrical shape such as a substantially cylindrical shape having a relatively small inner diameter and outer diameter, and other hollow body shapes. Further, the upper end portion 41 and the intermediate portion 42 may be integrally formed from a metal such as stainless steel or other appropriate material. Further, the humidifying pipe 6 includes a substantially cup-shaped lower end portion 43 which may be made of a metal such as stainless steel or other suitable material. The lower end portion 43 is detachably attached to the intermediate portion 42 by screwing and fixing, for example, a male screw portion provided near the upper end of the lower end portion 43 to, for example, a female screw portion provided near the lower end of the intermediate portion 42. . A large number of gas ejection holes 44 are formed on the peripheral side surface of the lower end portion 43. A substantially ring-shaped packing 45 made of a suitable elastic material such as synthetic rubber is attached to the outer periphery of the upper end portion 41 of the humidifying pipe 6.

  As shown in FIGS. 2 and 5, the upper end of the humidifying guide member 7 of the warming / humidifying mechanism 9 is the outer periphery of the lower half portion of the upper end 41 of the humidifying pipe 6 (including the location where the packing 45 is attached). Is attached to the humidifying pipe 6 in a detachable manner. Therefore, since the humidifying guide member 7 surrounds substantially the entire humidifying pipe 6, the heating cylinder 5 and the humidifying pipe 6 and the humidifying guide member 7 have a triple structure as a whole. In this case, the outer bottom surface of the humidifying pipe 6 may be in contact with the inner bottom surface of the humidifying guide member 7. The humidifying guide member 7 has a substantially cylindrical shape such as a substantially cylindrical shape having a relatively large inner diameter and a relatively small outer diameter, and other hollow body shape and a thin upper half portion 46, and an inner diameter thereof. A substantially cylindrical shape such as a substantially cylindrical shape that is relatively small and has a relatively large outer diameter, and other hollow body-shaped and thick lower half portion 47 and the lower end opening of this lower half portion 47 are substantially closed. It consists of a bottom wall 48. The bottom wall portion 48 can be provided with a through hole 49 as necessary.

  Therefore, on the inner peripheral surface and the outer peripheral surface of the humidifying guide member 7, a substantially ring-shaped inner step portion 52 and a substantially ring-shaped outer step portion 53 at substantially the same position in the vertical direction of the humidifying guide member 7. Are formed respectively. The inner step portion 52 is formed because the lower half portion 47 protrudes from the upper half portion 46 toward the radial center of the humidifying guide member 7. Further, the outer step portion 53 is formed because the lower half portion 47 projects more outward in the radial direction of the humidifying guide member 7 than the upper half portion 46. In addition, the upper half part 46, the lower half part 47, and the bottom wall part 48 can be integrally molded from an appropriate elastic material functioning as a damper and other materials as described later.

The humidifying guide member 7 is formed by continuously molding a synthetic resin such as polypropylene, soft polyethylene and hard polyethylene, a metal such as copper alloy and stainless steel, and other suitable materials (particularly preferably, soft polyethylene) by sintering. It may be configured as a three-dimensional skeleton structure having pores. In the case of using a sintered metal, it is possible to enhance control action such as rectification, dispersion, and buffering for a fluid such as a humidifying liquid and oxygen-enriched air. In terms of practicality, the humidifying guide member 7 generally satisfies one, a plurality, or all of the numerical ranges described in the following items (a) to (sa). It is preferable. Therefore, the humidifying guide member 7 can be provided with air permeability and water permeability, and elasticity when necessary.
(A) Porosity: in the range of 40-80%, more preferably in the range of 50-70% (in the case of the illustrated embodiment, about 58%),
(A) Surface pore diameter: in the range of 50 to 300 μ, more preferably in the range of 100 to 200 μ (in the illustrated embodiment, about 150 μ),
(C) Length L ₁ : in the range of 150 to 450 mm, more preferably in the range of 200 to 350 mm (about 255 mm in the case of the illustrated example),
(D) The length L _{2 of the} thin upper half portion 46 is in the range of 40 to 120 mm, more preferably in the range of 50 to 100 mm (in the illustrated embodiment, about 67 mm),
(E) The length L ₃ of the lower half portion 47 of the wall thickness: in the range of 45 to 140 mm, more preferably in the range of 60 to 110 mm (about 79 mm in the illustrated embodiment)
(F) Ratio (L ₃ / L ₂ ) of the length L ₃ of the lower half portion 47 of the wall thickness to the length L ₂ of the thin upper half portion 46 (L ₃ / L ₂ ): more preferably , In the range of 0.9 to 1.8 (about 1.18 in the illustrated embodiment),
(G) The inner diameter D _{1 of the} thin upper half portion 46 is in the range of 16 to 44 mm, more preferably in the range of 20 to 38 mm (in the illustrated embodiment, about 27.4 mm),
(H) The inner diameter D ₂ of the lower half portion 47 of the wall thickness is in the range of 15 to 45 mm, more preferably in the range of _{20 to} 35 mm (in the illustrated embodiment, about 25.5 mm),
(K) Thickness T _{1 of the} thin upper half 46: 0.75 to 2.3 mm, more preferably 1.0 to 1.8 mm (in the illustrated embodiment, about 1. 3mm),
(G) Thickness T ₂ of the lower half portion 47 of the wall thickness: in the range of 1.8 to 5.5 mm, more preferably in the range of 2.2 to 4.2 mm (in the illustrated embodiment, about 3 mm) ), And (sa) the ratio of the thickness T ₁ of the thin upper half 46 to the thickness T ₂ of the lower half 47 (T ₂ / T ₁ ): more preferably in the range of 1.2 to 4.2. Is in the range of 1.8 to 3.2 (about 2.3 in the illustrated embodiment).

On the other hand, the intermediate portion (i.e., the main portion) outer diameter _{D 3} of 42 of the humidifying pipe 6 is approximately 17 mm. Then, generally with the outer diameter D _3, between the inner diameter D ₂ of the inner diameter D ₁ and the thickness of the lower half 47 of the humidifying guide member 7 on the thin half 46, from the viewpoint of practicality In addition, it is preferable that at least one of the numerical ranges described in the following (S) and (S) terms is satisfied.
The inner diameter _{D 1} of the ratio _{(D 1} / D 3) of the intermediate portion 42 of the outer diameter _{D 3} on the thin relative to the half portion 46 of the (sheet) humidifying pipe 6: range of 0.9 to 3, more preferably 1. 2 to 2.2 range (in the case of the illustrated embodiment is about 1.6), and (scan) the inner diameter D of the lower half portion 47 of the wall thickness to the outer diameter _{D 3} of the intermediate portion 42 of the humidifying pipe 6 ₂ ratio (D ₂ / D ₃ ): in the range of 0.8 to 2.8, more preferably in the range of 1.1 to ₂ (about 1.5 in the case of the illustrated example).

  As shown in FIGS. 2 and 6, the upper end portion of the humidifying bottle 8 is provided on the outer peripheral surface of the mounting hole 54 of the base block 11 of the warming humidifier body 4 with, for example, a male screw portion provided near the upper end thereof. For example, it is detachably attached to the base block 11 by screwing and fixing a female screw portion. Therefore, since the humidifying bottle 8 surrounds almost the entire humidifying guide member 7, the humidifying cylinder 5, the humidifying pipe 6, and the humidifying guide member 7 and the humidifying bottle 8 have a quadruple structure as a whole. It has become. In this case, the outer bottom surface of the humidifying guide member 7 may be in contact with the inner bottom surface of the humidifying bottle 8. The humidifying bottle 8 has a mouth 55 at its upper end, and a bottle main body (in other words, a container main body extending from the mouth 55 to the lower end of the humidifying bottle 8 and having a bottom wall 57. 56). As shown in FIG. 6, the mouth portion 55 may have a substantially cylindrical shape such as a substantially cylindrical shape or other hollow body shape. Further, as shown in FIG. 6, the bottle body 56 may have a substantially frustum shape such as a substantially truncated cone shape, a substantially cylindrical shape such as a substantially cylindrical shape, and other hollow body shapes. The upper end of the bottle body 56 may be integrally connected to the lower end of the mouth portion 55, and the continuous portion 58 may constitute the shoulder portion of the humidifying bottle 8. Further, the humidifying bottle 8 is preferably transparent or translucent, and can be composed of a hard synthetic resin such as polycarbonate or other appropriate hard material. In addition, a liquid line 59 such as a water line extending in a substantially horizontal direction is formed in the vicinity of the center of the bottle body 56 in the vertical direction. The water line 59 indicates a desirable position of the liquid surface of the humidifying liquid such as water injected into the humidifying bottle 8 or drug-containing water.

When the humidifying guide member 7 is housed in the humidifying bottle 8 as shown in FIG. 2, the upper end of the lower half portion 47 of the humidifying guide member 7 (in other words, the thin upper half portion). the lower end of the 46) is located above the length L ₄ than the water line 59. In addition, the inner circumferential surface of the outer peripheral surface of the humidifying guide member 7 on the thin half 46 and the humidification bottles 8 are spaced on average by a distance S ₁ in the horizontal direction. Then, the inner peripheral surface of the outer peripheral surface of the lower half portion 47 of the wall thickness of the humidifying guide member 7 and the humidification bottles 8 are spaced on average by an interval S ₂ to each other in the horizontal direction. Then, the length L _4, the spacing S _1, S ₂ is generally in terms of practicality, one or more of the numerical ranges described in the following (Se) to (data) section Or it is preferable that all are satisfied.
(C) A length L ₄ extending downward from the upper end of the lower half portion 47 or the lower end of the thin upper half portion 46 to the water line 59 (specifically, the center in the vertical direction of the water line 59): In the range of 4-16 mm, more preferably in the range of 6-12 mm (in the illustrated embodiment about 8 mm),
(So) Average distance S ₁ in the horizontal direction between the outer peripheral surface of the thin upper half portion 46 and the inner peripheral surface of the humidifying bottle 8 is in the range of 4 to 16 mm, more preferably 6 to 12 mm (the illustrated embodiment). In the horizontal direction between the outer peripheral surface of the lower half portion 47 of the wall thickness and the inner peripheral surface of the humidifying bottle 8 in the horizontal direction S2: more preferably in the range of 8 to 26 mm, 10 to 22 mm (about 15 mm in the illustrated embodiment).

3. Operation of the warming humidifier Next, the operation of the warming humidifier 1 is divided into “(1) General operation of the warming humidifier” and “(2) Operation of the humidifying guide member”. This will be described with reference to the drawings.
(1) Schematic operation of the entire warming humidifier When using the humidifying humidifier 1 shown in FIGS. 1 to 7, a humidifying liquid is poured into the humidifying bottle 8 from the liquid injection port 20 in advance. Fill. In this case, the humidifying liquid is finally filled to the water line 59 in the humidifying bottle 8. The humidifying liquid injected into the humidifying bottle 8 is also injected into the humidifying guide member 7 through the lower half portion 47 having the water permeability of the humidifying guide member 7, and the lower half portion 47. Fully penetrated. The humidifying liquid injected into the humidifying guide member 7 is also injected into the humidifying pipe 6 through the gas ejection pores 44. Further, as shown in FIG. 7, a substantially Y-shaped gas transfer hose 65 is connected to the intake outlet 18 and the exhalation inlet 23 of the warming humidifier 4.

  At the same time, an operation button or the like of an operation panel (not shown) of the ventilator main body 3 is operated to introduce oxygen 31 and air 32 into the mixer 26. Therefore, the oxygen-enriched gas 12 is introduced to the gas inlet 13 of the warming humidifier body 4 through the regulator 12 and the electromagnetic valve 28, and thus introduced into the warming pipe 6 of the warming / humidifying mechanism 9 through the gas supply passage 14. Is done. The oxygen-enriched gas 12 descends in the heating pipe 6 and is ejected from the gas ejection pores 44 as a gas to be humidified (that is, a humidified gas) in the vicinity of the lower end in the humidifying guide member 7. Is done. In this case, the humidifying liquid in the humidifying pipe 6 is previously pushed out of the humidifying pipe 6 by the pressure of the oxygen-enriched gas 12 (in other words, in the humidifying guide member 7). . Further, the oxygen-enriched air 12 descending in the heating pipe 6 is heated to an appropriate temperature by the heating pipe 6. The heated oxygen-enriched air 12 rises in the humidifying guide member 7 and moves above the water line 59, and then the thin upper half of the humidifying guide member 7 that has air permeability. Pass through portion 46 from the inside to the outside. Further, the oxygen-enriched air 12 is guided to the intake outlet 18 through the switching valve 15 through the intake passage 19 of the warming humidifier body 4 as the intake 50.

  On the other hand, the gas transfer tube 66 attached to the distal end portion (that is, the free end portion) of the gas transfer hose 65 is attached to the patient 67 as shown in FIG. Therefore, the inhalation 50 guided to the inhalation outlet 18 is supplied to the lung 68 of the patient 67 through the gas transfer hose 65 and the gas transfer tube 66. In this case, the switching valve 15 performs an opening / closing operation so as to substantially coincide with the breathing timing of the patient 67. Therefore, the exhalation 34 from the lung 68 of the patient 67 is introduced into the exhalation passage 25 from the exhalation inlet 23 through the gas transfer tube 66 and the gas transfer hose 65. The exhalation 34 introduced into the exhalation passage 25 is further moved through the exhalation passage 25 through the switching valve 15 and then guided to the exhalation discharge port 24. Further, the exhalation 34 guided to the exhalation discharge port 24 is discharged to the outside through the exhalation discharge hole 33 of the exhaust pipe 10.

(2) Operation of the humidifying guide member The oxygen-enriched air 12 that is vigorously ejected from the gas ejection pores 44 of the humidifying pipe 6 into the humidifying guide member 7 causes the humidifying liquid to vigorously flow inside the humidifying guide member 7. Try to foam. However, the lower half portion 47 of the humidifying guide member 7 is composed of a three-dimensional skeletal structure having continuous pores and, in some cases, has elasticity, and thus functions as a damper. Intense foaming is suppressed and quiet foaming is performed. In addition, the lower half portion 47, particularly the portion below the actual water line of the humidifying liquid, has sufficiently penetrated the humidifying liquid as described above, and the air permeability is extremely reduced. Most or all of the oxygen-enriched air 12 passes through the actual water line and rises into the thin upper half 46. The increased oxygen-enriched air 12 moves through the thin upper half 46 into the humidifying bottle 8 (in other words, outside the humidifying guide member 7).

  In the above case, since the lower half portion 47 of the humidifying guide member 7 is thick, the damper action on the oxygen-enriched air 12 by the humidifying guide member 7 is sufficiently exhibited. For this reason, since the oxygen-enriched air 12 can extremely effectively prevent the humidifying liquid from being bubbled, the intense pressure fluctuation of the intake air 50 is effectively suppressed. Therefore, there is no fear that the needle of a pressure gauge (not shown) for the inhalation 50 will always swing greatly, making it difficult to accurately measure the pressure of the inhalation 50, and inhalation at an almost constant pressure that is highly desirable for the patient 67. 50 can be delivered to the patient 67. Further, since the upper half portion 46 of the humidifying guide member 7 is thin, the oxygen-enriched air 12 further rising from the actual water line of the humidifying liquid can permeate the thin upper half portion 46 very well. For this reason, the inhalation 12 in a stable state can be supplied to the patient 67 at all times.

  In the above, one embodiment of the present invention has been described in detail. However, the present invention is not limited to this embodiment, and various changes and modifications can be made based on the gist of the invention described in the claims. Is possible.

  For example, in the above-described embodiment, the porosity (refer to the item 2 (a)) and the surface pore diameter (refer to the above 2 (a)) between the thin upper half portion 46 and the thin lower half portion 47 of the humidifying guide member 7. The system is configured so that items (a) are the same. However, one or both of the porosity and the surface pore diameter may be different between the thin upper half portion 46 and the thin lower half portion 47. For example, the upper half portion 46 may have a different porosity. The surface hole diameter may be larger than the lower half portion 47. In this case, if the porosity and the surface porosity of the upper half portion 46 are sufficiently larger than the lower half portion 47, the upper half portion 46 does not have to be thinner than the lower half portion 47 as in the above-described embodiment. Since the desired high air permeability and water permeability can be obtained and the desired purpose as described above can be achieved, the upper half portion 46 is made substantially the same wall thickness as the lower half portion 47. You can also

  Moreover, in the above-mentioned Example, the inner side step part 52 and the outer side step part 53 of the humidification guide member 7 are each provided in the substantially the same location in the up-down direction of this humidification guide member 7. However, the inner stepped portion 52 and the outer stepped portion 53 may be provided at different locations in the vertical direction of the humidifying guide member 7, respectively.

  In the above-described embodiment, the thin upper half portion 46 and the thin lower half portion 47 of the humidifying guide member 7 are substantially equal in thickness as shown in FIGS. It is configured. However, the thin upper half 46 and the lower half 47 may be partially different in thickness. For example, each of the thin upper half portion 46 and the thin lower half portion 47 may be configured to gradually increase in thickness from the upper end thereof to the lower end thereof. In this case, the lower end of the thin upper half portion 46 and the upper end of the thin lower half portion 47 may have substantially the same thickness. Therefore, the characteristics such as the length and the thickness described in the items (a) to (c) mean an average characteristic such as an average length and an average thickness, if necessary. be able to.

  Moreover, in the above-mentioned Example, although this invention was applied to the heating humidifier 1, this invention is applicable also to the humidifier which does not have a heating function.

  Furthermore, in the above-described embodiments, the present invention is applied to the humidifier 1 for a ventilator. However, the present invention can also be applied to a medical humidifier other than a ventilator, and indoor air. The present invention can also be applied to a humidifier for indoor use that humidifies water and a humidifier used for other purposes.

BRIEF DESCRIPTION OF THE DRAWINGS It is a front view of the whole heating humidifier in one Example which applied this invention to the warming humidifier for ventilators. Example 1 It is a schematic center longitudinal cross-sectional view of the heating humidifier shown in FIG. Example 1 It is a center longitudinal cross-sectional view of the heating cylinder shown in FIG. Example 1 It is a front view of the humidification pipe shown in FIG. Example 1 It is a front view of the humidifying guide member shown in FIG. Example 1 It is a front view of the humidification bottle shown in FIG. Example 1 It is a block diagram which shows the relationship between the heating humidifier shown in FIG. 1 and the principal part of a ventilator main body in a use condition. Example 1

Explanation of symbols

1 Heating humidifier (humidifier)
2 Ventilator 3 Ventilator body 5 Heating cylinder 6 Humidification pipe 7 Humidification guide member 8 Humidification bottle (humidification container)
12 Oxygen-enriched air (intake gas, humidified gas)
44 Gas ejection hole 46 Thin upper half 47 Thin lower half

Claims (5)

A humidifying container filled with a humidifying liquid, and a humidifying pipe accommodated in the humidifying container,
The humidifying pipe has gas ejection pores and is configured to be able to introduce a humidified gas,
In the humidifier configured to move the humidified gas introduced into the humidifying pipe from the humidifying pipe into the humidifying container through the gas ejection pores,
A humidifying guide member accommodated in the humidifying container;
The humidifying guide member has air permeability and water permeability,
A humidifier, wherein the humidifying pipe is configured to be accommodated in the humidifying guide member.   2. The humidifier according to claim 1, wherein the humidifying guide member is constituted by a three-dimensional skeleton structure having continuous pores.   The humidifier according to claim 1 or 2, wherein an upper half portion of the humidifying guide member is thinner than a lower half portion of the humidifying guide member.   The humidifier according to claim 1, 2 or 3, wherein the humidifier is configured as a warming humidifier by accommodating a warming cylinder in the humidifying pipe.   The humidifier according to any one of claims 1 to 4, wherein the humidifier is for a ventilator to be mounted on a ventilator body so as to constitute a ventilator. .

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