DE2729768C3 - Process for the generation of temperature-controlled aerosol for the treatment of humans or animals and device for its implementation - Google Patents

Description

The invention relates to a method and a device for generating temperature-controlled aerosol for the treatment of humans or animals, in particular with nebulized brine, in which the treatment liquid or brine with a gaseous drive medium, in particular air, atomized and a patient or a Room in which the patient is to be supplied Aerosol flow is formed.

When nebulizing liquids, e.g. brines, especially when using nozzle nebulizers, d. H. Nebulization by means of a gaseous drive medium, there is an adiabatic cooling of the nebulized Liquid and thus a relatively rapid cooling of the aerosols generated. This adiabatic cooling is within tolerable limits if only small amounts of treatment liquid are nebulized should. When nebulizing large quantities of treatment liquid, especially when nebulizing brine, the adiabatic cooling that occurs during atomization is disadvantageously noticeable, so that upon impact on biological membranes (mucous membranes) equipped with temperature senses, such aerosols as feel hypothermic. The drying of biological membranes caused by air currents dissolves additional temperature-negative effects. Aerosols of this type therefore dissolve biological ones Membranes generate a cold stimulus, which leads to disruptive constrictions of the airways through reflective Measures, if necessary to stimulate a cough or other negative, the inhalation effect impairing or even triggers questioning phenomena.

When nebulizing local healing springs

has so far managed to warm up the solutions or brines to be nebulized and thus the to counteract adiabatic cooling. However, if you wanted to prevent the cooling effects entirely, you would have to ί you heat the treatment liquid to such a temperature that a considerable partial Evaporation occurs and thereby the composition of the treatment liquid in the course of the aerosol treatment would be changed considerably, or even

ίο the treatment liquid would be decomposed.

The object of the invention is therefore to create a method and a device that enables the generation of temperature-controlled aerosol, specifically to an optimal temperature for the patient to be treated, which can be just above body temperature, for example 37 ° C, without that a heating of the treatment liquid would be necessary with the associated disadvantages.
The invention is characterized by the claims

■ One could imagine trying to solve this problem by doing this for the Nebulization used drive gas is heated. However, it has been found that this option works as a solution the task at hand is not suitable because the previously heated drive gas when nebulizing the Treatment liquid is cooled again by the adiabatic cooling and thereby the previously Any increase in temperature is lost again. In addition, the setting of a Desired final temperature of the aerosol with previously heated and, when nebulized, adiabatic cooling subject to driving gas difficult to control in practice.

According to the invention, the object is achieved in that the aerosol flow when leaving of the nebulizer is surrounded by heated gas, in particular air, flowing parallel to it, and that enveloping gas before supplying? .u to the patient or the room receiving the patient into the Aerosol stream is mixed in. The invention makes it easy to control and good in practice reproducible temperature control of the aerosol enables the heated enveloping gas supplied heat is completely transferred to the aerosol by mixing the heated Enveloping gas with the aerosol flow creates turbulence within the aerosol flow both the coolness used in nebulization

^The driving gas as well as the aerosol particles are brought into effective contact with the mixed and heated gas, so that the aerosols are heated quickly and effectively

^ the aerosol flow is initially caused a limited heat exchange in the heated enveloping gas and the aerosol flow. This prevents premature aging of the aerosol, since aerosol particles tend to aggregate more strongly in a cold gas environment, so that slow, limited warming of the propellant gas counteracts such aggregation. The mixing of the heated enveloping gas into the aerosol flow increases the aging of the aerosol particularly strongly

^M measure and lastingly counteracted, so that the aerosol is absorbed by the patient to be treated practically without aging.
By tempering the aerosol after the

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25th

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Nebulization of the treatment liquid eliminates all of the disadvantages associated with heating the treatment liquid. There are also no disadvantages that could arise from the impact of preheated treatment gas on the treatment liquid. "> Rather, optimal, cool nebulization of the treatment liquid can be carried out. Although the heated, enveloping gas must be heated above the value of the final temperature of the aerosol, there is hardly any local temperature in the aerosol itself in the process according to the"> invention generated significantly above the final aerosol temperature It is of particular advantage that, due to the parallel flow of the enveloping gas and the aerosol flow ^{| 5,} considerable amounts of heat are transferred by conduction from the enveloping gas to the aerosol flow, so that the temperature of the enveloping gas before it is mixed in is already noticeably reduced in the aerosol stream.

Through detailed tests it has been established that the tempered by a heated sheath flow Medicinal aerosols, preferably coarse aerosols, no bronchostrictive reaction when applied cause and effectively heat the air flow, which has been cooled by adiabatic effects, up to Mucosal temperature.

Finally, an economic improvement is also achieved since the heating of the liquid aerosol parts would be associated with a high expenditure of energy, and these liquid aerosol parts are heated relatively strongly would have to because they only have a small proportion of the total volume of the aerosol. In contrast the use of a heated envelope stream or several heated envelope streams offers considerable benefits Advantages in terms of energy consumption.

In the context of the invention, a device for the aerosol treatment of humans or animals, in particular with nebulized brine, is created in which a nebulizer operated with a gaseous drive medium, in particular air, for treatment liquid and the aerosol flow formed to a patient connection piece or a channel conducting the patient receiving space are provided. According to the invention, the aerosol Füiirungskanal in such a device in the area between the nebulizer and the patient connection slip or the introduction into the room receiving the patient should be surrounded by a heated, gaseous medium to be operated heating jacket, and in flow - ^V1 direction of the aerosol flow in front of the patient connection piece or the introduction into the room receiving the patient, an inlet for the gas flow guided in the heating jacket into the aerosol flow. ^r "s

This device according to the invention is characterized by a particularly simple structure and high operational reliability the end.

To achieve a high degree of efficiency when mixing the hot air with the aerosol stream, * " at least one flow guide directing the hot air into the aerosol flow at the mixing point to be appropriate.

An embodiment of the invention is explained in more detail below with reference to the drawing. It shows ^Μ

F i g. 1 Vorrichfcing to generate a tempered aerosol flow, schematically in axial

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2 shows the device according to FIG. 1 in section II-f! and

3 shows a modified embodiment of the device in a representation corresponding to FIG. 1.

In the example according to FIGS. 1 and 2, a nozzle nebulizer 11, for example an annular nozzle nebulizer, a treatment liquid, for example a brine, in the order of magnitude of inhalable Converted into aerosols. In the scheme shown, the ring nozzle nebulizer 11 is at room temperature The air held as the drive medium is fed through the line 12, while the air to be nebulized Liquid, for example brine, through line 13, likewise at about room temperature, into the nebulizer 11 is introduced. Then occurs from the nozzle opening 14 the mist formed from the arrangement of the annular slot nozzle 11 at the open end of the aerosol tube

15 is picked up by this and directed to the application end 16. The aerosol tube. ·> .5 is from a Surrounding jacket pipe 17, which is connected to the aerosol pipe 15 forms an annular guide channel 18 for warm air, which is located at the rear end of the aerosol tube 15 is completed, while at the transition from the aerosol tube 15 to the application end 16 an annular arched flow guide 19 is attached, the transition from the jacket tube 17 to the application end

16 forms. Within the flow guide 19 is between the aerosol tube 15 and the application end 16, an annular passage 20 is formed. The one between the aerosol tube 15 and the jacket tube 17 formed ring channel 18 is connected at its rear area to a tub air generator 21, at its open end shown above in the drawing, a fan 22 and in its interior a heating coil 23 contains The heating coil 23 is preferably of an electrical type, for example a helix of resistance wire, and is set by a control device 24 to the respectively desired heating power controlled The control device 24 itself is connected to a Whcatstone bridge 25, to the two Temperature measuring probes 26 and 27 are attached. The one temperature measuring probe 26 is inside of the aerosol tube 15 and the second temperature measuring probe 27 in the application end 16, ie in Direction of flow arranged behind the mixing point 20a. The temperature measuring probes can in essentially made up of electrical components, for example temperature-sensitive electrical resistors or thermocouples. With the temperature sensor arranged in the aerosol tube 15 is the temperature of the mist generated in the nebulizer 11 and flowing in the aerosol tube 15 and with the in the application end 16 arranged temperature measuring probe 27 djs temperature of the tempered Aerosols measured. The of the two temperature measuring probes 26 and 27 to the as measured value comparator Wheatstone Bridge serving 25 measured values are compared Jort. The comparison value is then passed to the controller 24 to turn the heating coil 23 on and off, or more or heat up less strongly. As indicated by the arrows in FIG. I is indicated in the mixing area 20 an intensive mixing of the coming from the nebulizer 11 and flowing through the aerosol tube 15 Fog caused by the warm air flowing through the ring channel, so that the patient connection piece or a treatment room connected

This application end 16 of the device delivers an evenly tempered aerosol. Thereby occurs a Warming up of the mist coming from the nebulizer 11 within the aerosol tube 15, because this is already the case The aerosol tube is warmed up by the warm air flowing around it, and gives off heat to the mist. This release of heat prevents premature aging of the mist due to agglomeration.

The drive air supplied to the nebulizer through line 12 can be kept at a relatively small volume so that the air introduced there and subjected to adiabatic cooling on a for the Nebulising the necessary minimum amount is maintained.

The mist emerging from the nebulizer 5 creates an injection effect at the rear end of the Aerosol tube 15 generated. In addition, the warm air passing through the annular gap 20 generates a certain amount of air Suction on the aerosol tube 15 so that at the rear open end of the aerosol tube 15 Fresh air is sucked in, which is not subjected to adiabatic cooling and ils additional The carrier medium for the generated fog is used. The sucked in at the rear end of the aerosol tube 15 The amount of fresh air can be regulated by means of flaps or screens.

In the operation of this device, the temperature the treatment liquid and the drive gas are approximately at room temperature, while the temperature of the envelope gas to achieve a physiological aerosol temperature, for example at 37 ° C, at the Treatment point is regulated while keeping the envelope gas flow rate substantially constant. These Process management is particularly advantageous because it is particularly simple, optimal conditions when nebulizing the treatment liquid can be complied with and on the other hand the composition of the dem Aerosol supplied to the patient can be predetermined for each application.

However, it is also possible to conduct the process in which the temperature of the treatment liquid and of the friction gas is approximately at room temperature and the flow rate of the envelope gas to achieve a te arrives.

In the modified embodiment according to FIG. 3, the basic structure is the same as in the embodiment according to FIG. I and 2, so that the same reference numerals for designating the same parts as in the example of FIG. I and Ί are inserted. In addition, a further temperature measuring probe 28 is provided in the example according to FIG. Furthermore, the control device 24 is connected to the motor 29 of the blower 22 via a control connection. The control device 24 is designed in such a way that it switches over its control effect as follows when it reaches a threshold temperature determined by the temperature measuring probe 28 and set or adjustable on it:

If the hot air temperature ascertained by the temperature measuring probe 28 is below this temperature threshold set, for example, to 60 ^° C., then, as in the example in FIG. I and 2. The comparison value determined at the Wheatstone bridge 25 for the temperature measurements on the temperature measuring probes 26 and 27 are converted into a control of the heating coil 23. However, if the temperature determined by the temperature measuring probe 28 reaches this threshold value, then the control advantage 24 switches to control of the fan motor 29. This can take place by means of an electronic device for controlling the speed of the motor 29. However, Fs can also be sufficient for many application purposes to design the fan motor 29 for two speeds and to switch on the higher speed of the fan motor 29 with the control device 24 when the temperature threshold is reached in the hot air. In this latter case, the fine control can still be carried out by controlling the heating coil 23. By using this supplemented circuit and control it is achieved that the temperature of the hot air does not exceed a ^{threshold value of, for example, 60 ° C. that is previously established or can be set on the control device 24.} Through this

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37 ^C C. is regulated at the treatment site while essentially keeping the envelope gas temperature constant. This type of process management is particularly suitable in those applications in which it is not essential that an aerosol is strictly adhered to, only harmless warm air, but no dangerous hot air being supplied. Otherwise, the method of operation of the device according to FIG. 3 the same as that of the device according to FIG. I and 2.

For this purpose 3 sheets of drawings

Claims (3)

Patent claims: 1. Process for generating temperature-controlled aerosol for treatment of humans or animals which nebulises the treatment liquid by means of a gaseous drive medium, in particular air, and an aerosol flow to be supplied to the patient or to a room receiving the patient is formed, characterized in that the aerosol flow when leaving the nebulizer with heated gas flowing in parallel, in particular air, is enveloped, and the enveloping Gas in the aerosol stream before it is supplied to the patient or the room receiving the patient is mixed in. 2. Apparatus for performing the method according to claim 1, characterized in that the Aerosol guide channel (15) in the area between the nebuliser (11) and the patient connection piece (16) b £ w. the introduction into the patient receiving room with a with a current is surrounded by heated, gaseous medium to be operated heating jacket (17, 18), and in Direction of flow of the aerosol stream in front of the patient connection piece (16) or the introduction In the room receiving the patient there is an inlet (20, 2IaJ for the one in the heating jacket (17, 18) Gas flow is arranged in the aerosol flow 3. Apparatus according to claim 2, characterized in that at least one of the hot air in the Aerosol flow-directing flow guide (19) is attached to the mixing point (20aj