US2709577A - Oxygen therapy humidifier - Google Patents

Description

W 31, 1955 H. L. POHNDORF ET AL 2,709,577

OXYGEN THERAPY HUMIDIFIER Filed July 28, 1951 INVENTORR/ GEORGE L HAM/H0 lE/WPY L. POI/NDORF w vim ATTORNEY 2,709,577 oxvonn THERAPY HUMIDIFIER Henry L. Pohndorf, El Cerrito, and George L. Hammon,

Oakland, Calif., assignors to National Welding Equip- ;nent (10., San Francisco, Calif., a corporation of Callornia Application July 28, 1951, Serial No. 239,136 i Claims. (Cl. 26I--2) This invention relates to an improved humidifier.

One important use of humidifiers is in connection with oxygen treatment for hospital patients. Commercial tanks of oxygen normally maintain the gas under extremely high pressures and with no contained moisture. When the pressure of the humidity, and if administered that way to the patient, it will tend to dry out the lung tissues. Prolonged breathing of dry oxygen can be quite harmful; so it has become accepted practice to humidity the oxygen before the patient breathes it.

It is often desirable to saturate the oxygen, that is, to wet the gas to a humidity of approximately 100%. This makes it possible to produce gas of any desired humidity by mixing a known amount of the saturated gas (100% humidity) with a known amount of the dry gas humidity). One trouble with humidifiers which have heretofore been used has been that they were not able to wet the dry gas to 100% humidity. Most of these prior art humidifiers have been mere bubb1ersi. e., they operated by bubbling the dry gas through a jar of water. Only the oxygen near the surface of the bubble came in contact with the water, and the balance of the oxygen inside the bubble remained relatively dry.

Another problem with bubblers has been that their efiiciency decreased with increase in the pressure of the gas. The higher the pressure of the gas introduced into the humidifier, the larger the bubbles, and the larger the bubbles, the less gas that comes in contact with the water so the gas that goes out the outlet is less humid than desired.

Another fault with humidifiers of the bubbler type has been that the gas often carried over small droplets of water which were never evaporated. It is believed that such droplets, when carried into the lungs, sometimes induced pneumonia and aggravated the disease which the treatment was intended to cure.

Still another disadvantage of the humidifiers that have heretofore been in use is that they have required almost constant watching. The jars held a relatively small amount of water, and only a small proportion of this small amount was available for humidification. When the water level dropped, the bubbles traveled a shorter distance through the water, less gas came into contact with the water, and the humidity of the outgoing gas dropped. Also when the water level dropped only a short distance, it would fall below the gas inlet of the bubbler; so there was no humidification. This meant that the nurse had to watch the water level closely and had to add water frequently.

A more serious problem was the fact that many of such humidifiers were dangerous. The humidified oxygen has usually been conducted away from the jar by a flexible rubber hose, and this is usually the most desirable way to do it. However, when such a hose became kinked, or was stepped on, or otherwise collapsed, two dangers were present: First, the patient would not get enough oxygen to breathe so that he might suffocate. Second, the

gas is reduced, the gas remains at zero iftates Patent 0 pressure of the gas would build up inside the jar, so that it was not uncommon for the jar to explode and scatter broken glass.

All these problems, and several others which will become apparent from this description, have been solved by the present invention. It provides a humidifier which will produce substantially humid oxygen, free from droplets of water. It can be used with jars of relatively large volume and makes use of substantially all the water in the jar; so the humidifier does not require frequent attention. Moreover, its efficiency will not drop as the water level drops, and the humidity will remain substantially constant so long as there is any water in the jar. Further, a unique warning system is provided that sends out an audible signal when the gas pressure in the jar reaches a predetermined amount so that the nurse is called automatically and the patient is given more oxygen to breathe. At the same time, a relief valve permits escape of excess gas and thereby prevents explosions from occurring.

The structure which has solved these problems, and which has many other advantages that will be taken up in connection with the illustrative description, includes a sealed jar having an outlet and an inlet with a fixed orifice. The orifice opens into, or near to, a venturi chamber. The passage of oxygen through the venturi sucks water into the chamber through a long, flexible tube which may extend as long as necessary, up to the atmospheric limit for sucking water. Inside the venturi chamber, the Water is apparently broken up into millions of tiny droplets which are then introduced into the oxy gen stream. This stream issues against a novel baffle that breaks up the bubbles and aids their evaporation and prevents the stream from striking directly against the surface of the water. This keeps the oxygen free of any unabsorbed water or residual droplets. Moreover, the bathe, in combination with a somewhat labyrinthine pathway which the humidified gas must travel in its way to the outlet serves to shake out all of the few such droplets that might remain in the gas. Gas is prevented from building up to high pressures by a safety relief valve that is provided in the cover to the jar. When the pressure reaches a value somewhat above normal but still well within the limits of safe operation, a reed in the relief valve sounds a musical tone to give audible warning that the pressure is excessive.

Further features of the invention will be understood from a detailed description and illustration of one form of the device that embodies the principles of the invention, but the scope of the invention is not intended to be limited thereby except as provided by the appended claims.

In the drawings:

Fig. l is a view in elevation showing an oxygen tank, a regulator, gauges, and a humidifier connected thereto.

Fig. 2 is a View in elevation and in section of a humidifier embodying the principles of this invention.

Fig. 3 is a view on a reduced scale of a portion of the humidifier adjacent the venturi chamber, looking from the left side in Fig. 2.

Fig. 4 is a view in section of a portion of the safety valve, looking at right angles to Fig. 2 along the line 4-4.

Fig. 5 is a view in section looking up from the bottom of Fig. 4, along the line 5-5.

Fig. 6 is a view in section of the venturi and baffle of a modified form of the invention.

Fig. 7 is a View taken along the line 7-7 of Fig. 6.

Fig. 1 shows an assembly employing a humidifier em bodying the principles of this invention. The dry gas is usually supplied at high pressure from acylinder 10 filled with oxygen, and its pressure is reduced by a regulator 11. Agauge 12 may indicate the pressure of the gas as it issues from the regulator 11, while aflow measuring device 13 may indicate the volume of the gas being humidified, usually expressed in liters per minute. Ahumidifier 15 that embodies the present invention may be located adjacent the flow measuring device '13.

Thehumidifier 15 appears in greater detail in Fig. 2. It includes ahousing 16 with aninlet 17 for the dry gas and anoutlet 13 for the humidified gas. Thehousing 16 comprises ajar 20 and acover 21. Thejar 20 will usually be made of glass or other transparent material so that the water level and the operation of the vaporizer can be watched. Preferably the jar is of the mason-type, having aflat shoulder 22 at the lower end of a threadedneck 23. Arubber gasket 24 rests on theshoulder 22 and effects a seal between thejar 20 and thelower lip 25 of thecover 21. in this manner there is no dependence on thetop edge 26 of the jar to effect a seal.

Thecover 21 supports the working parts of thehumidifier 15. A central tappedhole 27 in its upper surface holds a threaded inlet fitting 28 in the upper end of which is thehumidifier inlet 17. Afilter screen 29 may fit in theinlet 17 to remove any foreign matter from the incoming gas.

A central bore 3t extends through thecover 21 from the lower end of thehole 27, thebore 36 being flared out at its lower end to provide a socket 31 for a purpose to be explained. An interiorly-threadedannular rim 32 depends from the lower surface of thecover 21, concentric with the socket 31. From a point inside this rim 32 apassageway 33 is bored through thecover 21 to theoutlet 18.

A hollow cylindrical sleeve ormuffler tube 35 is threaded into therim 32. Thesleeve 35 hasperforations 36 through which the humidified gas passes on its way to theoutlet passageway 33, as shown by the direction of the arrows.

The'humidification is done in avaporizer assembly 37 that is threaded into the lower end of thesleeve 35. Theassembly 37 comprises alower member 38 into which anupper member 39 is threaded. The dry gas from the inlet fitting 28 is conducted to thevaporizer 37 by means of atube 41 held between the socket 31 and a socket 42 in theupper member 35. An O-ring 43 seals the reduced upper end of thetube 41 at the socket 31 and another O-ring 44 seals the reduced lower end of thetube 41 in the socket 42. This type of fitting makes it easy to disassemble the pieces to sterilize them.

The dry oxygen issues from theupper vaporizer member 39 through a relatively long, narrow, and restricted orifice 45, of a size compatible with theflow measuring device 13. The importance of relating the size of the orifice 45 to thefiow measuring device 13 will be explained later.

The orifice 45 extends deep into a substantiallyannular chamber 46 that is formed in thelower vaporizer member 38. The orifice 45 is spaced a short distance from a wider nozzle 47 that leads out from thechamber 46 through the lower wall of themember 33. This combination of orifice 45,chamber 46, and nozzle 47, forms a venturi whose sucking action is used to draw water up into thechamber 46, where it is broken up into very small particles and is then mixed with the gas.

The water may be drawn inthrough aflexible tube 50 secured around the projecting lower end of ametal tube 51 which is joined to thechamber 46 by apassageway 52. The proper length of theflexible tube 50 depends on the height of thejar 20, so that it may vary from a few inches to several feet. However, because of its flexibility, a relatively long piece oftubing 50 may be used inside relatively short jars, so that asingle tube 50 may be used for several ditferent sizes ofjars 20.

At the lower end of thetube 50 there may be secured an intake fitting 53, preferably of ball shape so that it'may lie in the lowest rim of thejar 20 and suck up water so long as there is water in the jar. To prevent the introduction of foreign particles, the fitting 53 may be provided with a-filter 54 adjacent thenarrow passageway 55.

The water and oxygen mixed in thechamber 46 are ejected from the nozzle 47 against a stream divcrter member or baffie 6b. This may comprise a cusp-shapedmetallic member 61 supported below theassembly 37 by themetal tube 51 and asolid standard 62. The stream is spread outwardly by thecusp 61, which breaks up its concentration into thin sheet form, prevents the water surface from rippling, and also breaks up any stray water droplets, any remaining free droplets dripping down the member 6i and off it into the water below. The cusp shape efiects a very even distribution of the humidified stream of gas, at the same time causing the stream to turn outwardly and upwardly without striking the water below.

From thebattle 68 the humidified oxygen follows a labyrinthine path to the outlet, going from the jar interior through theholes 36 and thepassageway 33 to theoutlet 18.

A novel pressure-relief valve is also provided, for the prevention of excessive pressures within thejar 20 and for giving an audible warning when the outlet of gas from the normal outlet is blocked and the pressure builds up. For this purpose arecess 66 is provided in the upper surface of thecover 21, andopenings 67 and 68 extend all the way through the cover. The upper portion of therecess 66 is a generally verticalcylindrical wall 71, while thelower portion 72 slopes inwardly to a flat web 73 that forms the bottom of therecess 66 and is perforated at its center by theopening 67 and bordering it by theopenings 68.

The moving part of thevalve 70 comprises adisc 74 that fits in therecess 66 and has a rubber O-ring 75 around its periphery, preferably on the lower side so as to seat against the sloping wall 73. When seated, thedisc 74 closes the path to gas entering through any of theopenings 68.

A stem 76 depends from thedisc 74 down through thecentral opening 67, a nut '77 being threaded on its lower end. A spring 73%, held in tension between thenut 77 and the web 73, normally retains thedisc 74 in its lower position, where it prevents leakage of gas. When the pressure of the gas inside thejar 20 exceeds the tension of thespring 78, the spring 73 is compressed, thedisc 74 is lifted, and gas passes between therubber ring 75 and the walls of therecess 66.

A hollow cap fill has at its lower end a rubber O-ring 81 that fits in a groove 82 in therecess 66. All the gas escaping past thedisc valve 74 goes up through thecap 80. Just below the caps upper end is aplate 83, having asmall outlet opening 84 and a generally rectangular opening 85. Areed 86 lies across the opening 85, one end being secured to theplate 33 so that its other end can vibrate freely in theopening 35.

Anopening 87 through the top of the cap permits escape of the gas after it has passed through theopenings 84 and 85. The top of theplate 83, which shows through theopening 87, may be colored red to discourage tampering. However, there is a further safety feature that comes into play if anyone should tape over theopening 87 or otherwise obstruct it. The O ring 81 connection is air tight, but if theescape opening 87 is blocked, excess pressure will eject the entire cap by lifting it and its 0 ring 81 out of therecess 32.

In operation, the gas enters at theinlet 17, goes through thetubes 28 and 41 to thevaporizer assembly 37 and issues from the orifice 45 into thechamber 46. The venturi sucks water in through the ball inlet 53 via the tubes 55) and 51 into thechamber 46. There the water is broken up into infinitesimal portions and mixed with the dry gas to produce gas having up to humidity. The humidified gas issues from the nozzle 47 and its stream is then spread by thecusp 61, which breaks up any droplets and prevents any disturbance of the surface of the water. The gas then goes up into the interior of thejar 20 above the ballle 63, passes through theholes 36 in the sleeve ormuffler tube 35, into thepassageway 33, and goes to the outlet 1%.

An advantage of this device is that the gas will hu midify with equal eificiency, no matter what the water level is, and the gas will be humidified so long as there is water in thejar 29. The water level can always be observed through thetransparent jar 20 and water added when it is needed.

Thesafety valve 70 operates only from the gas pressure inside thejar 20. Then, when the gas pressure exceeds the tension of thespring 78, thedisc 74 is raised and gas enters thecap 80. It passes through the plate openings 3 's and 85 out the cap opening 8'/, sounding the warning reed 85 as it does so. If someone carelessly tapes over theopening 87, thewhole cap 80 will be ejected, and the gas will still escape.

It is worth noting that the structure of the humidifier makes possible the use of either of two types of fiow measuring devices and makes it possible to use them on the dry gas before humidification. One such device is usually termed a fiow gauge. In reality it is a pressure gauge that is used in conjunction with an orifice of known size, the gauge being calibrated to read in terms of the quantity per unit time (e. g. liters per minute) of gas which the pressure would cause to flow through the orifice. A flow gauge may be used with the present invention, because thehumidifier 15 is of the jet type, and its orifice 45 can be standardized, and the gauge calibrated to it.

The second type of flow measuring device that is in common use is usually termed a flow meter and is illustrated by the floating ball type of meter. There, gas flows from bottom to top through a vertical tube with conical walls that widen gradually toward the upper end. In its flow the gas lifts a light ball to a height that depends on the rate of flow. The ball will drop when there is no fiow, even though the pressure of the gas increases. Consequently the flow meter is more accurate than the flow gauge. For example, if the orifice became stopped up, flow would stop, and pressure would build up; the flow gauge would then falsely indicate an increase in flow, whereas the flow meter would correctly indicate a cessation of flow.

Flow meters have heretofore been used only at atmospheric pressures, or at least where the outlet end is at atmospheric pressure. With humidifiers this has two principal disadvantages. Wet gas fogs the tube and makes it difiicult to read, and if water has collected on and around the ball, it weighs it down and makes it stick to the walls, so the reading is inaccurate. With this invention, the flow meter can be placed on the input side of the humidifier, where the gas is dry, and where these ditliculties are prevented. This is possible, because the orifice 45 is standardized, making it possible to calibrate the tube for operation under the flow valves cor responding to the orifice. Also, the warningreed 86 in dicates when the outlet tube from the humidifier is clogged. When the warning system is silent, gas is flowing out from the humidifier at substantially the same rate it is flowing in.

In Figs. 6 and 7 a modified form of the invention is shown. Here the gas stream entering the vaporizer assembly 140 flows through twoorifices 145 of identical size. This enables the use of the same flow meter or flow gauge to indicate a stream of twice as much gas, either by new calibration or by a corrected reading of the 01d scale. The gas mixes with the water vapor in the venturi chamber 146 and flows out through two noz zles 147. The baffie includes a knife-edge cusp memher 161 (instead of the point-cusp member 61) so as to take care of bothnozzles 147. Otherwise, operation is identical with the form described in Figs. l-4.

We claim:

1. A humidifier for gas under pressure, including in combination: a container body adapted to be partially filled with water; a cover adapted to seal said container, said cover having a vertical inlet for dry gas and a radial horizontal outletfor humidified gas connected to a conduit through said cover leading from a cover opening inside said container near said vertical inlet; a hollow mufiler tube depending from said cover and surrounding both said vertical inlet and said cover opening, said muffier tube having radial perforations spaced downwardly a substantial distance from said cover; a vaporizer as sembly supported below said perforations by said mufiier tube, said assembly including a housing defining a venturi chamber having orifice means for dry gas, an inlet opening for water, and nozzle means in line with said orifice means through which a mixture of gas and water issues; an imperforate tube connecting said orifice means with said dry gas inlet means; a tube for water leading from the lower part of said container body to said water inlet opening; and a cusp'shaped baffie depending from said muflier tube below and in line with said nozzle means, above the water level, whereby the dry gas draws water into said venturi chamber, issues as a stream of wet gas from said nozzle means, is deflected by said bafiie out into the space between said container walls, said muffier tube, said cover, and the water, is forced by the presusre in said container through said perforations into said mufiler tube and thence to said cover opening and said outlet, said bafiie and the subsequent labyrinthine path of the wet gas serving to shake out suspended droplets of water from the humidified gas.

2. The humidifier of claim 1 in which said orifice means comprises a plurality of orifices and said nozzle means comprises a corresponding plurality of nozzles, each in line with one said orifice.

3. The humidifier of claim 1 in which the orifice means comprises a single orifice, the nozzle means a single nozzle, and the baffie means a cusp-shaped cone-like member axially aligned with said nozzle and orifice.

4. The humidifier of claim 1 in which the orifice means comprises a plurality of aligned orifices, the nozzle means a corresponding plurality of similarly aligned nozzles; and said bafiie means a member having a relatively sharp upper edge aligned with said nozzles, a cusped surface curving downwardly and outwardly from said edge.

References Cited in the file of this patent UNITED STATES PATENTS 1,222,421 Lambert Apr. 10, 1917 1,625,419 McCaa Apr. 19, 1927 1,810,131 Daily June 16, 1931 2,049,158 Eckert July 28, 1936 2,054,850 Deming Sept. 22, 1936 2,129,482 Severin Sept. 6, 1938 2,230,201 Hermann Jan. 28, 1941 2,428,277 Heidbrink Sept. 30, 1947 2,437,526 Heidbrink et a1. Mar. 9, 1948 2,565,691 Ketelsen Aug. 28, 1951 2,588,312 Walker Mar. 4, 19'"

Claims (1)

1. A HUMIDIFIER FOR GAS UNDER PRESSURE, INCLUDING IN COMBINATION: A CONTAINER BODY ADAPTED TO BE PARTIALLY FILLED WITH WATER; A COVER ADAPTED TO SEAL SAID CONTAINER, SAID COVER HAVING A VERTICAL INLET FOR DRY GAS AND A RADIAL HORIZONTAL OUTLET FOR HUMIDIFIED GAS CONNECTED TO A CONDUIT THROUGH SAID COVER LEADING FROM A COVER OPENING INSIDE SAID CONTAINER NEAR SAID VERTICAL INLET; A HOLLOW MUFFLER TUBE DEPENDING FROM SAID COVER AND SURROUNDING BOTH SAID VERTICAL INLET AND SAID COVER OPENING, SAID MUFFLER TUBE HAVING RADIAL PERFORATIONS SPACED DOWNWARDLY A SUBSTANTIAL DISTANCE FROM SAID COVER; A VAPORIZER ASSEMBLY SUPPORTED BELOW SAID PERFORATIONS BY SAID MUFFLER TUBE, SAID ASSEMBLY INCLUDING A HOUSING DEFINING A VENTURI CHAMBER HAVING ORIFICE MEANS FOR DRY GAS, AN INLET OPENING FOR WATER, AND NOZZLE MEANS IN LINE WITH SAID ORIFICE MEANS THROUGH WHICH A MIXTURE OF GAS AND WATER ISSUES; AN IMPERFORATE TUBE CONNECTING SAID ORIFICE MEANS WITH SAID DRY GAS INLET MEANS; A TUBE FOR WATER LEADING FROM THE LOWER PART OF SAID CONTAINER BODY TO SAID WATER INLET OPENING; AND A CUSP-SHAPED BAFFLE DEPENDING FROM SAID MUFFLER TUBE BELOW AND IN LINE WITH SAID NOZZLE MEANS, ABOVE THE WATER LEVEL, WHEREBY THE DRY GAS DRAWS WATER INTO SAID VENTURI CHAMBER, ISSUES AS A STREAM OF WET GAS FROM SAID NOZZLE MEANS, IS DEFLECTED BY SAID BAFFLE OUT INTO THE SPACE BETWEEN SAID CONTAINER WALLS, SAID MUFFLER TUBE, SAID COVER, AND THE WATER, IS FORCED BY THE PRESSURE IN SAID CONTAINER THROUGH SAID PERFORATIONS INTO SAID MUFFLER TUBE AND THENCE TO SAID COVER OPENING AND SAID OUTLET, SAID BAFFLE AND THE SUBSEQUENT LABYRINTHINE PATH OF THE WET GAS SERVING TO SHAKE OUT SUSPENDED DROPLETS OF WATER FROM THE HUMIDIFIED GAS.

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