Nov. 21, 1967 F. M. BIRD ET AL NEBULI ZER 2 Sheets-Sheet 1 Filed April 13, 1965 Fig.3
INVENTORS d? a@ Wm .r n r "mm m .P, A M. ...L@ 8 RH United States Patent 3,353,536 NEBULIZER Forrest M. Bird, Airport, Box 970, Palm Springs, Calif. 92262, and Henry L. Pohndorf, 1227 Brewster Drive, El Cerrito, Calif. 94530 Filed Apr. 13, 1965, Ser. No. 447,852 8 Claims. (Cl. 128-194) ABSTRACT OF THE DISQLOSURE Nebilizer having a container and a cover removably mounted on the container and in which the cover is formed with an inlet passage and outlet passage and with a skirt which is disposed in front of the inlet passage and the outlet passage, the cover havinga nozzle mounted thereon for taking fluid from the container and nebulizing the same at a point which is above the lower extremity of the skirt.
This invention relates to a nebulizer and more particularly to a nebulizer which can be utilized for long-term therapy.
Nebulizers heretofore available have either been relatively small in size requiring frequent re-filling, or have been very expensive for the larger sizes.- There is, therefore, a need for a new and improved low price nebulizer which can be utilized for long-term therapy.
In general, it is an object of the present invention to provide a nebulizer which can be utilized for long-term therapy for all applications where oxygen or air is admin istered to a patient.
Another object of the invention is to provide a nebulizer of the above character which is relatively inexpensive.
Another object of the invention is to provide a nebulizer of the above character which can be used on many different types of respirators.
Another object of the invention is to provide a nebulizer of the above character which can be readily filled and refilled.
Another object of the invention is to provide a nebulizer of the above character which can be readily maintained.
Another object of the invention is to provide a nebulizer of the above character which can be readily cleaned.
Another object of the invention is to provide a nebulizer of the above character in which the critical parts are always in alignment.
Additional objects and features of the invention will appear from the following description in which the preferred embodiment is set forth in detail in conjunction with the accompanying drawings.
Referring to the drawings:
FIGURE 1 is a side elevational view of a neubulizer incorporating the present invention.
FIGURE 2 is a top plan view of the nebulizer shown in FIGURE 1.
FIGURE 3 is a front elevational view of the nebulizer shown in FIGURE 1.
FIGURE 4 is a side elevational view partially in crosssection of a portion of the nebulizer shown in FIGURE 1.
FIGURE 5 is a side elevational view similar to that shown in FIGURE 1 showing another way of using the nebulizer and showing the cap in cross-section.
FIGURE 6 is a cross-sectional view of the nebulizer shown in FIGURE 5.
FIGURE 7 is an enlarged fragmentary view of a portion of the nebulizer shown in FIGURE 6.
In general, the nebulizer is utilized for supplying small liquid particles in a mainstream of gases supplied to a patient. The nebulizer consists of a container defining a chamber which is adapted to contain a liquid. A cover is removably mounted on the container and is formed with inlet and outlet passages having relatively large crosssectional areas for carrying the mainstream of gases for the patient. A nozzle is mounted on the cover and has a passage therein for supplying additional gases into the chamber and mixing with the mainstream gases. A nipple is formed on the nozzle and has a passage opening into the passage in the nozzle. A tube is connected to the nipple and is adapted to extend into the liquid in the container so that as gases pass through the nozzle, the liquid is drawn upwardly and entrained in the gases passing through the nozzle. Means is mounted in the cover and provides a surface disposed in front of the nozzle to break up the liquid particles entrained in the gases passing from the nozzle. A skirt is mounted in the cover and surrounds the nozzle and has its lower extremity extending beyond the point at which the liquid particles impinge upon the surface whereby the larger particles engage the skirt and fall back into the liquid in the reservoir and the smaller particles are picked up by the mainstream of gases passing from the inletpassage and into the outlet passage.
As shown in the drawing, the nebulizer consists of a container 11 with a castellatedcover 12 removably mounted thereon. The container 11 can be formed in any suitable shape as, for example, cylindrically, as shown in the drawings, and can be formed of any suitable material such as a transparent plastic. The container can be of any suitable size but preferably should be relatively large in order to provide a relativelylarge chamber 13 for long-term therapy as hereinafter described. Thus, the container can be of a size such as to contain 500 cc. of liquid. If desired, as shown particularly in FIGURE 1, the container 11 can be provided withvertical calibrations 14 so that the amount of liquid in the chamber can be readily determined by visually examining the level of the liquid in the chamber or reservoir.
The container 11 is open at the top and is provided withthreads 15 on its upper extremity. The cove-r 12 can also be formed of a suitable material such as an opaque plastic and can be of any suitable shape. For example, as shown in the drawings, it can have a dome-shaped portion 12a and acylindrical portion 12b. Thecylindrical portion 12b is provided with threads which are adapted to cooperate with thethreads 15 to form a threaded connection between thecover 12 and the container 11.
Thecover 12 is provided withextensions 16 and 17 which have axially aligned inlet andoutlet passages 18 and 19 formed therein having relatively large cross-secional areas for carrying the mainstream gases for the patient. As shown in the drawing, theoutlet passage 19 is slightly larger than theinlet passage 18. However, it should be pointed out that the functions of the two passages can be reversed.
Thecover 12 is provided with anannular recess 21 which carries an O-ring 22 which is adapted to engage the top edge of the reservoir 11 to form a tight seal between the cover .12 and the reservoir 11 as shown particularly in FIGURE 4.
The upper portion of the cover is provided with a frustoconical depending skirt 24 which extends downwardly into thecover 12 for a substantial distance and which has its lowermost extremity substantially below the lower portions of the inlet andoutlet passages 18 and 19 for a purpose hereinafter described. The skirt 24 is provided with a slight inward taper in a downward direction and forms alarge opening 26 in the top of thecover 12. Thecover 12 is also provided with a vertically extending threadedboss 27 which has amantle 28 threadedly mounted thereon. Themantle 28 is provided with large and small plug-likemale portions 28a and 28b.
Themale portion 28a is of a size so that it can be inserted in theoutlet passage 19 to plug the same, whereas theportion 28b is of such a size that it can be inserted in theinlet passage 18 to plug that passage when desired.
Thelarge opening 26 provided in thecover 12 is normally closed by a large plug orcrown 31. The plug is provided with a frustoconical portion 31a and a planar bottom wall portion 31b which adjoins the frustoconical portion 31a. The plug is also provided with an outwardly extendinglip 31c. Anarcuate recess 32 is formed in thelip portion 310 to accommodate the mantle orcap 28. As can be seen from FIGURE 4, theplug 31 forms a relatively tight fit in the skirt 24 and normally seals theopening 26.
Anozzle 34 is mounted in theplug 31 and is formed as an integral part thereof and extends through the bottom wall portion 31b. Thenozzle 34 is provided with a vertically extendingpassage 36 which has a taperedportion 36a and a capillary-like portion 36b which are in communication with a port ororifice 37 disposed below the bottom wall portion 31b to provide a downwardly directed jet of air. The nozzle is provided with anipple 38 which has apassage 39 which communicates with thepassage 36. Thenozzle 34 and thenipple 38 are cast as integral parts so that they cannot become misaligned. This assures maximum efficiency of the nozzle at all times. Aflexible tube 41 of a suitable material such as plastic is mounted on thenipple 38 and is adapted to extend downwardly into thechamber 13 and into the liquid carried in the container 11. As hereinafter described, thenozzle 34 is adapted to carry gases and through conventional aspirator action, is able to draw liquid from thechamber 13 and to cause liquid particles to be entrained in the gases as they pass through thenozzle 37.
By way of example, onenozzle 34 andnipple 38 had the following dimensions. Thepassage 36 had a diameter of .025 inch; thepassage 39 had a diameter of .045 inch; and the port ororifice 37 had a diameter of .047 inch. The taperedportion 36a of thepassage 36 had an included angle of 8". Theportion 36b had a length of A of an inch and the orifice orport 37 had a length of .067 inch. Thus, in this example, the ratio of the size of theportion 36b of thepassage 36 and theorifice 37 is .025 1.047, and the ratio of the area was 1:3.54.
Means is provided on theplug 31 which forms a surface disposed in front of the nozzle for breaking up the liquid particles entrained in the gases passing from theport 37 This means consists of aball 42 which is formed as an integral part of a substantiallyU-shaped pendant 43. Thependant 43 is provided with upper tapered portions 43a which are adapted to fit relatively tightly inholes 44 provided inbosses 46 formed integral with the planar bottom wall portion 31b. Thependant 43 is so positioned so that the spherical surface provided by theball 44 is disposed slightly below theport 37 for thenozzle 34. It also will be noted that theport 37 and theball 42 are positioned so that the gases carrying the liquid particles impinge upon the ball at a point which is above the lower extremity of the skirt 24 or, in other words, the skirt 24 extends beyond the point at which the liquid particles impinge upon theball 42.
Theplug 31 is also provided with a pair ofrisers 48 which havepassages 49 extending therethrough.Caps 51 of a suitable material, such as rubber, are mounted over the risers and close the upper ends of thepassages 49.
Suitable additional fittings are provided for use with the nebulizer. For example, as shown in FIGURES 1, 2, 3 and 4, afitting assembly 56 is provided which consists of a T-shapedfitting 57. The fitting 57 has one leg 5711 which is tapered and adapted to seat within thepassage 36 provided in thenozzle 34. The fitting is also provided withnipples 57b and 57c which are stepped as shown and which are connected totubes 58 and 59.Tube 58 is adapted to be connected to a source of gas under pressure so that the gas is supplied to thenozzle 34. Thetube 59 is adapted to be connected to other accessories as, for
example, an exhalation valve of a breathing assembly provided as a part of a respirator.
In FIGURES 5 and 6, anotherfitting assembly 61 is provided which consists of anextension member 62 which is provided with a cap 63which is adapted to be threaded onto the threadedboss 27 and atapered element 64 which is adapted to seat within a taperedrecess 66 provided in theboss 27. Theextension member 62 can be formed of any suitable material such as plastic. It is provided with a vertically extendingpassage 67. It also is provided with anintegral fitting 68 which has a passage 69 therein opening into thepassage 67. Atube 71 is mounted on the fitting 68. Anadapter 72 is mounted on the other end of thetube 71 and is provided with a tapered portion 72a adapted to fit within thepassage 36 provided in thenozzle 34. The adapter is provided with apassage 73 which opens into thetube 71. Ametal fitting 76 is mounted on the upper end of theextension member 72 and has aswivel 77 of a conventional type mounted thereon which is adapted to be connected to anoutlet assembly 78 of a conventional type that is connected to a source ofgas 79 under pressure.
Operation and use of the nebulizer may now be briefly described as follows. Let it be assumed that theinlet extension 16 is connected to means for supplying mainstream gases to a patient, as, for example, arespirator 81 such as disclosed in Patent No. 3,068,856, and that theoutlet extension 17 is connected to a suitable patient adapter such as a breathing assembly and that thefitting assembly 56 has itstube 58 connected to a suitable supply of gas under pressure such as supplied from the respirator. Let it also be assumed that the container 11 has been filled to a suitable level with a liquid with which it is desired to supply to the patient as, for example, water.
In operation, the gases passing through thetube 58 enter thepassage 36 and thenozzle 34 and discharge at relatively high velocity through theport 37. During the travel of the gases through thepassage 36, liquid from the container 11 is siphoned through thetube 41 and is entrained in liquid particles in the gases passing through thepassage 36 by conventional aspiratory action and the liquid particles are discharged with the jet of gases emerging from theport 37 and impinge upon the spherical surface provided by theball 42 which breaks the entrained particles of liquid into many smaller particles as, for example, particles having a size of .5 to 4 microns. These particles, with the jet of air, are dispersed downwardly within the skirt 24. Certain of the larger normally undesirable particles collect on the skirt, whereas the smaller particles enter the mainstream of gases passing through the nebulizer from theinlet passage 18 and around the skirt 24 out the outlet passage to the patient. Since the mainstream does not take a direct route across the point at which the gas jet emerging from theport 37 strikes theball 42 because of the protection afforded by the skirt 24, the mainstream of gases passing around the skirt 24 will only pick up or capture those smaller particles which readily travel with the gases, whereas the larger particles will be collected by the skirt 24 and will drain down into the container 11. The smaller particles captured by the main air stream passing through the nebulizer are delivered to the patient so that the patient is supplied with properly moistened gases.
The integral one-piece construction of thenozzle 34 andnipple 38, which alternatively can be called a one-piece air jet capillary and discharge port assembly, is relatively important. This is because the amount of liquid delivered to thependant ball 42 through themetering orifice 37 is determined by its size relationship with respect to the size of thepassage 36a and the length of thepassage 39 that must be bridged by the jet of gases which passes from thepassage 36 through theorifice 37. Thus, the area of thepassage 36b, the length of the free gas jet travel across thepassage 39 to the inlet of thelarger orifice 37 and the relationship of thelarge orifice 37 to thepassage 36b controls the amount of liquid placed in the jet stream and which is slammed against theball 42 and thus, in a great measure, determining the availability of the volume of liquid to be suspended in the mechanical airway to the patient. The element efficiency of the jet capillary construction depends greatly on the registration or concentricity of thejet orifice 36b and thedischarge orifice 37 which emits the mixed gas and liquid. The present construction precludes misalignment of the parts. The size of theball 42 determines the particulate size.
When the nebulizer is connected as shown in FIGURES 14, an in-line connection is provided for the mainstream gases and all of the mainstream gases as, for. example, all of the inspired gases during pressure breathing, can be caused to flow directly through the nebulizer to make possible maximum transport of the liquid particles to the patient. Additional liquids for giving the necessary therapy to the patient, such as anaesthetic agents, drugs and bronchodialators, can be introduced by way of hypodermic needles through thecaps 51 and through thepassage 49 provided in therisers 48. The chamber orreservoir 13 can be refilled during the expiratory phase merely by removing thecover 12 and filling the reservoir without disconnecting the various fittings. Alternatively, if desired, the container 11 can be unscrewed from thecover 12, filled with liquid and then screwed back into the cover.
The operation is substantially identical with the use of thefitting assembly 61 provided in FIGURES and 6. However, in this arrangement, themantle 28 closes theinlet passage 18 and the only gas which passes through the nebulizer and out theoutlet passage 19 is the gas supplied through thenozzle 34. Such an arrangement is used where the patient is being supplied with oxygen through a nasal catheter, etc. Since the oxygen passes through the nebulizer, it is properly moistened for the patients use.
Thecrown 31 can act as a relief valve which will automatically pop out of thecover 12 when excessive high pressure gases accumulate in the mechanical airway to the patient.
From the foregoing, it can be seen that the nebulizer may be used in combination with any metered oxygen supply to provide a suspension of water particles to resolve any humidity deficit in the gases being supplied to the patient. Thus, the nebulizer may also be called a humidifier. The container 11 is of sufficient size so that continuous therapy can be provided for the patient. The inlet and outlets are in line and can be reversed. The nebulizer humidifier can be applied without alternation on free flow oxygen inhalation therapy or pulmonary therapy.
We claim:
1. In a nebulizer for supplying small liquid particles in a mainstream of gases supplied to a patient, a container forming a chamber adapted to contain a liquid, a cover mounted on said container, the cover being formed with an inlet opening and an outlet opening for carrying main stream gases to the patient, a nozzle mounted on said cover and having a passage therein for supplying gases into the chamber, an additional passage formed in said nozzle and communicating with said first named passage, means connecting said additional passage to the fluid in the reservoir, means mounted in the cover providing a surface disposed in front of the nozzle for breaking up liquid particles entrained in the gases passing from the nozzle, and a skirt disposed in the cover and surrounding the nozzle and having its lower extremity extending below said inlet and outlet openings and below the point at which the liquid particles impinge upon said surface, said skirt being disposed in front of said inlet opening and said outlet opening and in said mainstream gases so that the mainstream gases have a tendency to flow around the skirt.
2. A nebulizer as in claim 1 wherein said cover has a large opening formed therein, a plug removably mounted in said cover and closing said opening and wherein said nozzle and said means providing a surface are mounted on said plug.
3. A nebulizer as in claim 1 wherein the inlet and outlet passages are in alignment and wherein the nozzle is disposed so that the gases jetting therefrom are substantially at right angles to the aligned inlet and outlet passages.
4. In a nebulizer for supplying small liquid particles in a mainstream of gases supplied to a patient, a container forming a chamber adapted to contain a liquid, a cover removably mounted on said reservoir and being formed with axially aligned inlet and outlet passages having relatively large cross-sectional areas for carrying the mainstream of gases for the patient, a cylindrical skirt formed in the cover and defining a relatively large opening extending downwardly at right angles to and below the axially aligned inlet and outlet passages, the skirt being disposed in front of the inlet and outlet passages in the main airstream so that the mainstream gases have a tendency to flow around the skirt, a plug removably mounted in said large opening in the cover and serving to close the same, a nozzle mounted in said plug and having a downwardly disposed port so that gases jetting therefrom pass in a direction which is substantially at right angles to the direction of flow of the mainstream gases through the nebulizer, said nozzle being formed with an additional passage, means connecting said additional passage to the liquid in the container so that as gases pass through the nozzle, liquid is siphoned from the container and entrained in the gases, and means mounted on the cover supporting a substantially spherical surface disposed in front of the nozzle for breaking up the liquid particles entrained in the gases passing from the port into smaller particles.
5. A nebulizer as in claim 4 together with a boss mounted on said cover and a mantle removably mounted on said boss, said mantle having portions thereof adapted to be inserted in either said inlet passage or said outlet passage to close either said inlet passage or said outlet passage.
6. A nebulizer as in claim 4 wherein said means supporting said substantially spherical surface consists of a substantially U-shaped member removably mounted in said plug.
7. A nebulizer as in claim 4 together with at least one riser mounted on said plug, a passage in said riser, and a resilient cap mounted on said riser and closing said passage.
8. A nebulizer as in claim 4 wherein said substantially spherical surface is positioned so that it is above the lower extremity of the skirt.
References Cited UNITED STATES PATENTS 2,709,577 5/1955 Pohndorf et a1 128185 2,840,417 6/1958 Dorsak et a1. 128-194 3,018,971 1/196-2 Cheney 239-338 3,172,406 3/1965 Bird et al. 128-194 3,206,175 9/1965 Boteler 128188 3,269,665 8/1966 Cheney 239338 FOREIGN PATENTS 452,438 11/1948 Canada.
RICHARD A. GAUDET, Primary Examiner. K. L. HOWELL, Assistant Examiner.