RU2070062C1 - Ultrasonic inhaler - Google Patents

Abstract

FIELD: medical equipment, in particular, inhalers intended for individual treatment and prophylaxis of diseases of upper respiratory tracts and lungs with liquid aerosols. SUBSTANCE: ultrasonic inhaler, using a casing with a cover and outlet branch pipe, focusing vibrator excited by a radio-frequency generator, atomizing chamber with ports for delivery of air from without, reservoir with inducing liquid and a cuvette for atomized liquid, is furnished with an appliance for magnetodynamic activation of aerosol installed on an additional branch pipe brought out to the atomizing chamber and supported in cantilever on the casing cover in alignment with the outlet branch pipe; the appliance is secured on the additional branch pipe in the area of forming and inertial precipitation of a spout of large drops produced by ultrasound. EFFECT: enhanced efficiency. 1 dwg

Description

 The invention relates to medical equipment, namely, to inhalers intended for individual treatment and prevention of diseases of the upper respiratory tract and lungs with liquid aerosols.

 Various inhaler designs are known, including those based on the method of generating therapeutic aerosols using ultrasonic vibrations. Closest to the present invention is the technical solution according to a. from. N 1623663, M. cl. A 61 M 11/00, 15/00, B.I. N 4 1991 (prototype).

 The known inhaler contains a high-frequency generator, a focusing ultrasound emitter, a spray chamber with holes for external air to enter, a geyser (fountain) reflector, a reservoir with matching liquid, a funnel-shaped lid and a cell for spraying liquid. The generator creates high-frequency oscillations, which are converted by the focusing emitter into ultrasonic vibrations. Ultrasound is focused in the focal region where the nebulization of liquid medications in the cuvette takes place. Fine aerosol is collected in the spray chamber, large droplets are reflected by the reflector and flow through the holes in the lid into the cuvette. Aerosol from the spray chamber is supplied to the patient through the outlet pipe.

 The peculiarity of this inhaler is that as the atomized liquid is consumed, its level in the cuvette decreases, the cuvette becomes lighter and rises relative to the matching fluid level, which ensures that the level of the atomized liquid is within the boundaries of the focal region of the emitter. As a result, the inhaler provides complete atomization of the liquid in the cuvette.

 A disadvantage of the known inhaler is the ability to obtain only aerosols based on previously prepared liquid media from decoctions of herbs, mineral waters and aqueous solutions of organic and inorganic substances, i.e. aerosols activated by a chemical factor. The preparation of such solutions requires perfect knowledge of their pharmacological and physico-chemical properties, the storage time of the prepared solutions, the degree of preservation of the structure and medicinal properties of the drug after exposure to focused ultrasound, the susceptibility of the body to this drug (aerosols from drugs often give adverse side effects), etc. d.

 In this regard, considerable attention has recently been paid to the use of aerosols, the healing properties of which are achieved by their activation by physical factors, in particular, by treatment with an electric field (ionization) directly in the apparatus (F. G. Portnov. Electroaerosol therapy. Riga, 1976). However, such inhalers require the use of high-voltage power supplies, which complicates their operation in terms of safety standards.

 At the same time, other methods of physical activation of liquids are known, in particular, a method based on the magnetohydrodynamic effect, known as the method of “magnetizing” liquids (V.I. Klassen. Magnetization of water systems. M. Chemistry, 1982, 296 pp.). The essence of the method is to pass water at a speed of 0.5 to 2.5 m / s relative to the magnetic field with optimal values of induction within 0.07 0.2 T. Thus magnetized water has unique properties used in technology, industry, agriculture and medicine.

 As for the medical aspects of using magnetized water, its use is known for treating purulent wounds and ulcers, lowering blood pressure, increasing kidney function and urine output, and dissolving kidney stones. Extensive material has also been accumulated, confirming the enhancement of the healing properties of aqueous solutions of drugs and biologically active substances during their magnetization.

, где v скорость потока,

индукция магнитного поля. Подбор необходимой индукции поля осуществляется также числом секций омагничивания, порядком их размещения и реверсирования направления вектора магнитной индукции (чередованием полярности полюсов в направлении движения потока жидкости). Необходимо также указать на то, что эффективность омагничивания жидкости резко возрастает при одновременной или предварительной ее турбулизации, которая может достигаться обработкой жидкости ультразвуковыми колебаниями в режиме кавитации (Ю.М.Сокольский. Омагниченная вода: правда или вымысел. Л. Химия, Ленингр. отдел. 1990, 144 с. ).The simplicity of the technical implementation of the method of magnetohydrodynamic activation of liquids attracts, since its implementation requires only permanent small-sized magnets with a relatively small magnetic field strength. Ensuring optimal magnetization modes are achieved by selecting the product value v •

where v is the flow rate,

magnetic field induction. The selection of the required field induction is also carried out by the number of magnetization sections, the order of their placement and the reversal of the direction of the magnetic induction vector (by alternating the polarity of the poles in the direction of fluid flow). It should also be pointed out that the efficiency of fluid magnetization increases sharply with simultaneous or preliminary turbulization, which can be achieved by treating the fluid with ultrasonic vibrations in the cavitation mode (Yu.M. Sokolsky. Magnetized water: true or fiction. L. Chemistry, Leningrad department . 1990, 144 p.).

 The objective of the invention is the creation of an ultrasonic inhaler, which allows to obtain aerosols with enhanced healing properties due to their magnetization directly during operation of the apparatus.

 The technical result of the invention is expressed in the development of an inhaler in which aerosol activation is achieved without the use of additional high-voltage sources and without increasing the energy cost of giving them enhanced healing properties. An increase in the efficiency of magnetization of aerosols is achieved by such arrangement in the apparatus of devices for magnetohydrodynamic activation, in which there is a maximum interaction of the turbulized medium due to the processes of ultrasonic cavitation with a magnetic field. The device for activation does not increase the size of the inhaler, has an almost unlimited service life, and low cost.

 The essence of the invention lies in the fact that an ultrasonic inhaler containing a housing with a cap and an outlet, placed in the housing a focusing ultrasound emitter excited by a high-frequency oscillation generator, a spray chamber with openings for incoming air from outside, a reservoir with matching fluid and a cuvette for sprayed liquid is provided device for magnetohydrodynamic activation of an aerosol located in the area of formation and inertial deposition of the fountain from large drops, created called by focused ultrasound. A device for magnetohydrodynamic activation of the aerosol is mounted on a nozzle inserted into the spray chamber and cantileverly mounted on the housing cover, while the nozzle and the spray chamber are aligned with each other.

 The essence of the technical solution is illustrated by the drawing, which schematically shows an image explaining the design and principle of operation of the ultrasonic inhaler.

 The inhaler contains a generator of high-frequency oscillations 1, which excites a focusing emitter 2, including a piezoelectric element 3 and a focusing lens 4. The emitter 2 is placed at the bottom of the reservoir 5 with matching fluid located in the housing 6. A cuvette 7 for the sprayed fluid 8 floats in the matching fluid of the reservoir 5. The cuvette 7 on the side surface has a shoulder 9, which it rests on the protrusion 10, made on the inner surface of the housing 6, with an empty tank 5. The upper part of the housing 6 above the protrusion 10 forms a chamber ra dusting 11. The housing 6 is closed by a cover 12 with the possibility of rotation of the latter in the horizontal plane. On the side surface of the lid 12 and the housing 6 there are ventilation openings 13 and 14, the combination of which, when the lid 12 is rotated, makes it possible to control the amount of external air entering the spray chamber 11. The intake of air from the outside of the chamber 11 is due to the pressure drop created by the fountain, entraining the flow of air and aerosol during the operation of the inhaler. The inner part of the lid 12 has a collar in the form of a sleeve, which forms a ventilation gap 15 between the wall of the sleeve and the wall of the cuvette 7. On the outer surface of the lid 12 is attached a technological cover 16, on the inside of which a pipe 17 is mounted cantileverly entering coaxially into the spray chamber 11. Technological the cap 16, which is part of the cap 12, facilitates the assembly and disassembly of the inhaler at the stages of production and home maintenance. Outside the lid 12 there is an outlet 18 in the form of a knee-shaped interchangeable mouthpiece through which the aerosol is inhaled. A magnetic head 19 is attached to the nozzle 17, forming together with the nozzle 17 a device for magnetohydrodynamic activation of the aerosol. The drawing shows the simplest head design, including a cylindrical bipolar magnet, the north and south poles of which are located on the end planes of the cylindrical magnet. The field lines of the field created by such a magnet are perpendicular to the axis of the nozzle 17 for a portion of the length. The head 19 can contain a larger number of magnets, which allows both to increase the total strength of the created field and to create its reversal to increase the magnetization effect of liquid aerosols. In the drawing, digital designation 20 shows the focal region in which ultrasound is concentrated, and 21 a fountain (geyser) formed during operation.

 The operation of the inhaler is as follows. Before turning on the apparatus, the reservoir 5 with the cover 12 removed (complete with the cover 16, nozzles 17 and 18, the magnetic head 19) and the cuvette 7 removed from the spray chamber 11 is filled to the level of the protrusion 10 with matching liquid (ordinary water). The required amount of sprayed liquid 8 is poured into the cuvette 7 and placed in the tank 5 so that it is in a floating state. After that, the housing 6 is closed by a cover 12 (assembled) and the generator 1 is turned on. The generator 1 creates high-frequency electric oscillations (2.64 MHz), which are converted by the focusing emitter 2 into ultrasonic vibrations collected in the focal region 20 on the surface of the sprayed liquid 8, contained in the cuvette 7. Due to the cavitation processes in the liquid in the focal region 20, a fountain (geyser) 21 is initiated, consisting of large droplets with a diameter of up to 1 mm flying upward at a speed of 1.2 1.6 m / s. At the same time, tiny droplets with a diameter of 0.1 to 10 microns (average particle size of 0.5 to 5 microns with a monodispersity of 50 to 90% depending on the adjustment of the operating modes) are generated in the gushing area, forming a stable fog of considerable density. Some of the large droplets flying to a height of several centimeters lose their kinetic energy and are returned to the cell due to inertial deposition processes. Another part of the large drops reaches the knee of the curved outlet pipe (mouthpiece) 18, and hitting it as a reflector, flow down the inner surface of the pipe 17. Large drops flying up the pipe 17 entrain air flow, resulting in a spray cavity chamber 11 under the influence of the resulting pressure drop is sucked in through the openings 13 and 14 of the surrounding air. This air flow (shown by arrows) passes through the gap 15, enters the cavity of the nozzle 17 and, entraining the smallest drops of fog (aerosol), carries it through the mouthpiece 18 to the consumer. As the sprayed liquid 8 is consumed, its level in the cuvette 7 decreases, however, due to a decrease in its mass, the cuvette 7 simultaneously floats in the matching liquid located in the reservoir 5. Due to this, the level of the sprayed liquid is always in the focal region 20 of the ultrasonic emitter oscillations 2, which ensures, on the one hand, its complete consumption, and on the other hand, high stability of the dispersed composition of the aerosol and its density.

, скорость v прохождения жидкости должна быть не менее 0,5 м/с и не более 2,5 м/с. Для достижения оптимума необходимо было бы принятие альтернативных решений по применению более сильных магнитов, наращиванию их числа или применению эффекта реверсирования (перемены направления вектора индукции на 180^o), что повлекло бы за собой существенные усложнения конструкции. Во-вторых, при предлагаемом размещении приспособления для магнитогидродинамической активации в области существования крупных капель фонтана последние, многократно поднимаясь вверх и осаждаясь вниз, каждый раз подвергаются омагничиванию в поле силовых линий, что эквивалентно использованию системы последовательно установленных магнитов с реверсивно расположенными полюсами. Очевидно, что предлагаемый вариант более приемлем ввиду своей простоты.In accordance with the invention, aerosol and large droplets, flying across the lines of force of the magnetic field generated by the magnetic head 19, undergo magnetization, thereby acquiring healing properties. In principle, the magnetization system can be fixed outside the housing to the outlet pipe 18, through which only the finely dispersed component of the fountain passes, i.e., a clean aerosol. However, activation will be far from maximum. Firstly, this is due to the low velocity of the aerosol along the outlet pipe 18, amounting to several centimeters per second. At the same time, it was previously indicated that in order to achieve the magnetization optimum determined by the product v •

, the velocity v of the fluid passage should be at least 0.5 m / s and not more than 2.5 m / s. To achieve the optimum, it would be necessary to take alternative decisions on the use of stronger magnets, increase their number or apply the reversal effect (change of direction of the induction vector by 180 ^o ), which would entail significant design complications. Secondly, with the proposed arrangement of devices for magnetohydrodynamic activation in the region of existence of large drops of the fountain, the latter, repeatedly rising up and settling down, are magnetized each time in the field of field lines, which is equivalent to using a system of sequentially mounted magnets with reversed poles. Obviously, the proposed option is more acceptable due to its simplicity.

 In connection with these circumstances, in order to achieve maximum magnetization efficiency in the present invention, the magnetic head is mounted on a nozzle cantilevered on the cover 12 (complete with cover 16) inside the spray chamber 11, i.e. in the zone of existence of the fountain from large drops. In this case, both fine aerosol and large droplets that have velocities lying in the range of the magnetization optimum move relative to the lines of force of the magnetic field used. Moreover, in this section of the pipe 17 there is a developed process of cavitation of the liquid, which contributes to the enhancement of the magnetization effect. The margin of magnetization efficiency can be transformed into a decrease in the requirements for the strength of magnets and the number of steps for reversing the vector of magnetic induction, which, in turn, can reduce the dimensions and cost indicators of the apparatus.

 Thus, it is easy to see that the proposed inhaler has a number of features that can increase the therapeutic effectiveness of aerosols and improve its operational and technical characteristics.

Claims (2)

 1. An ultrasonic inhaler comprising a housing with a cap and an outlet pipe, a focusing ultrasound emitter excited by a high-frequency oscillation generator, a spray chamber with openings for incoming air from outside, a reservoir with matching fluid and a cell for spraying fluid, characterized in that it is provided with a device for magnetohydrodynamic activation of an aerosol located in the area of formation and inertial deposition of a fountain from large drops created by a focuser Awesome ultrasound.  2. The inhaler according to claim 1, characterized in that the device for magnetohydrodynamic activation of the aerosol is mounted on a nozzle inserted into the spray chamber and cantileverly mounted on the housing cover, while the nozzle and the spray chamber are aligned with each other.