RU2033815C1 - Inhalation device - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: device is provided with a gas feeding means, mixing chamber, mask, and evaporation chamber to which are connected the main and the first additional pipes at the level at which wicks are fastened. The first end of the wick is placed in the air space of the evaporation chamber; its second end is placed in the liquid components space. The second additional pipe is connected with its inlet to the air space of the evaporation chamber, and with its outlet - to the mixing chamber. The first and second pipes are provided with air flows switches. The mixing member is made in the form of a truncated cone. The main pipe communicates with the mixing chamber via a throttle opposite the smaller base of the cone. EFFECT: higher efficiency and reliability. 1 cl, 1 dwg

Description

 The invention relates to medical equipment, in particular to devices for creating respiratory mixtures for inhalation, in particular for creating mixtures of essential oils with air.

 A device is known for creating air streams with liquid vapors, comprising a source of air flow, an evaporation chamber, a container for evaporating liquid, a tube connecting the container to the evaporation chamber. In the known device, a jet of liquid is sprayed in the air stream, followed by its evaporation. A disadvantage of the known device is the inability to ensure uniform evaporation of the liquid at its very low flow rates (milligrams per hour).

 The closest set of features to the invention is an apparatus for anesthesia with chloroform, which contains means for supplying air, an air flow regulator, a supply air duct, an adjustable air flow divider, an evaporation chamber with chloroform, equipped with a wick, a mixing chamber with a connecting element and a mask. The air flow divider is used to control the flow directed into the main pipeline and an additional one connected to the evaporation chamber.

 The device operates as follows. From the means for supplying air (a cylinder with a reducer), the air flow passes through a flow regulator, which provides the air flow necessary for the patient to breathe, this flow enters the flow divider, in which this flow is divided into main and additional. An additional stream passes through an evaporation chamber with chloroform, where this stream is saturated with ether vapors, after which it combines with the main stream and enters a breathing mask. The regulator of the concentration of the chemical substance changes the value of the additional air flow through the evaporation chamber, depending on the established concentration.

 The disadvantage of this known device for creating mixtures of chemicals with air is that it allows you to create mixtures only if the chemical substance consists of one component, or a mixture of several components with the same volatility. If the chemical substance consists of several components with different volatilities, as in the case of essential oils, then the concentration and composition of the vapors will continuously change over time as the volatile oil filled in the evaporation chamber evaporates. First, the most volatile component will evaporate predominantly at a high rate, then as it decreases in the essential oil remaining in the evaporation chamber, the proportion and concentration of heavier components in the air will increase with a decrease in the total concentration of the components of the essential oil in the air.

 Another disadvantage of the device for inhalation anesthesia is its inefficiency, due to the fact that the high pressure of the air coming from the air source is reduced to the pressure necessary for breathing without doing useful work.

 The disadvantage of the prototype, like any other known device for the preparation of mixtures of chemicals with air, is the inability to control the composition of the components of a chemical substance in an air mixture (if a chemical substance consists of several components) in a different way, except for replacing the chemical substance poured into the device with a substance with a different ratio components. Regulation of the composition of the components of essential oils in air for inhalation may be useful, as there are indications that, for example, when applying fir oil, its more volatile components have a better therapeutic effect.

 The problem to which the invention is directed, is to prepare an air mixture containing a given amount of essential oil in each liter of the mixture (about 1 microgram per liter). The device should be compact enough, with its performance, allowing to use it for individual use, i.e. in the production of 20-25 liters per minute, sufficient for the breathing of one person. The content and composition of the components of the essential oil should be stable in time both during the inhalation session and as the portion of the essential oil placed in the device is consumed. The device should allow changing the composition of the components of the essential oil in the air mixture.

 The implementation of the invention will allow for the treatment of patients with inhalation of vapors of essential oils individually, i.e. if necessary, it is easy to change the essential oils themselves (take peppermint, fir, anise, etc.), their concentration, and also change the ratio of light and heavy oil components in inhaled air to some extent.

 The proposed device consists of a compressor, a buffer tank, the main air duct, two additional air ducts, a flow divider, a regulator of the concentration of essential oil vapors in the air combined with a thermocompressor, an evaporation chamber, a mixing chamber, an inhalation duct containing a mask with a connecting element.

 Unlike the evaporation chamber of the prototype apparatus for inhalation anesthesia, the evaporation chamber of the invention does not consist of one tank, but two. The lower tank is designed for pouring essential oil. A rod of material with capillary conductivity is partially immersed in the essential oil being poured. This wick rod is fixed in the hole connecting the upper and lower containers, and the end, not immersed in essential oil, passes inside the upper containers. The upper container has openings for air inlet and two openings for air outlet containing vapors of essential oil, the opening for air inlet being close to the fixed portion of the rod, one of the openings for output also near the fixed end, and the other at the free end of the wick rod.

 To enable the use of a less powerful compressor, the mixing chamber is made in the form of an effective ejector pump, the nozzle of which is connected to the main air stream from the compressor, a pipeline is connected to its suction chamber from one of the openings for discharging the air mixture from the evaporation chamber, and the outlet bell of the ejector pump is aligned with an inspiratory duct connection. The efficiency of the ejector pump is ensured by the shape of the inspiratory air duct, namely the form of its connecting element (to the mixing chamber), the connecting element is made in the form of a truncated cone, and the main pipeline is connected to the mixing chamber by means of a throttle (nozzle) located opposite the small base of the cone. The geometrical dimensions of the parts of the ejector pump and the taper of the connecting element are optimized for the means for supplying the gas stream used in the design (for its productivity and output pressure).

 The use of a wick rod with capillary conductivity as part of the device, through which the essential oil is supplied from the essential oil tank to the evaporation tank and from the surface of which the components of the essential oil pass into the air blown through this tank, ensures a constant composition and concentration of the preparation air mixture. This result is achieved because in the steady state of the device, the amount of volatile oil evaporating from the surface of the wick rod is equal to the amount coming from the reservoir, while the volatile and hardly volatile components obviously arrive at the same speed.

 On the part of the wick rod, which is in the tank for evaporation, there is an essential oil enriched with heavy components. If the air mixture exits through an opening in the evaporation tank located behind the free end of the wick rod, so that air blown through the evaporation tank passes along the wick rod, then the components of the essential oil are distributed unevenly on it. Near the place of its fixing, the composition of the oil on the wick rod is identical to the composition of the oil in the reservoir. The closer to the free end of the wick rod, the more non-volatile components are on its surface, since volatile evaporate faster during the time that the oil reaches the end of the wick rod.

 If you additionally open the outlet of the air mixture through the hole near the fixed end of the wick rod, then part of the air flow will flow around the section of the wick rod, on the surface of which there are relatively many volatile components. This part of the air flow will be enriched with these volatile components. Since in both parts of the stream the amount of components of the evaporated essential oil remains equal to the number of components of liquid essential oil entering the wick from the reservoir through the rod, in the other part of the air stream the proportion of light components of the essential oil will be less than in the liquid oil. By giving the patient one or another other part of the air flow, it is possible to give a mixture noticeably enriched with either light or heavy components. The unused second part of the flow can be discharged into the ventilation system or even into the air in the room. Analysis of the composition of the vapors traveling along these two parts of the air flow showed that the composition really varies markedly. So, in one of the experiments, the proportion of the volatile component of pinene in the evaporating fir oil was about 90% in one part of the stream and less than 5% in the other. By varying the magnitude of the air flows through both holes, it is easy to obtain any content of pinene vapors within the specified limits. The compactness of the device is achieved by the fact that, using the ejector pump in the device, a low-power compressor can be used, providing an air flow of about 3 l 1 per minute at a pressure of about 400 mm water column. At the outlet of the ejector pump, an air flow of 20-25 liters is created in 1 min.

 The drawing shows a diagram of a device for inhalation.

 A device for inhalation of vapors of mixtures of chemicals, in particular essential oils, consists of a compressor 1, a buffer tank 2, air ducts 3, a flow divider 4, a flow regulator 5, which together with a thermometer 6 and interchangeable scales 7 is designed to adjust the flow depending on temperature, the evaporation chamber 8, the ejector pump 9, to which the air duct of the inspiratory 10 with a breathing mask 11 is connected.

 The evaporation chamber 8 consists of a tank 12 for pouring essential oil 13 and a container for evaporation 14. In the opening of the partition between the tank 12 and the tank for evaporation 14, a wick rod 15 of material with capillary conductivity is fixed. One end of the rod 15 is immersed in essential oil, and the other is located in the evaporation tank 14. The evaporation tank 14 has an opening 16 for entering the air flow near the fixing point of the rod 15, a hole 17 near the fixing point of the rod 15 for the exit of the air mixture enriched with volatile components essential oils and the hole 18 near the free end of the rod 15 for the exit of the air mixture, enriched in the volatile components of essential oils.

 The ejector pump has a nozzle 19, a suction chamber 20 with holes for suctioning air 21, an outlet bell 22. In the suction chamber there are also holes 23, which include pipelines connected to the holes for the exit of the air mixture from the evaporation tank. These pipelines are equipped with airflow switches 24 and 25.

 The device operates as follows.

 When the compressor 1 is turned on, air from it enters the buffer tank 2, in which pressure fluctuations are smoothed out. From the buffer tank, in which increased pressure is created (about 400 mm water column), air enters the air ducts. The main air flow goes to the nozzle 19 of the ejector pump 9. An additional air stream, which is much smaller than the main one, formed in the flow divider 4 by the additional flow regulator 5, enters the inlet 16 of the evaporation chamber 8. The additional flow is established by regulator 5, at which the capacity for evaporation of 14 from the rod-wick 15 into the additional stream passed the required amount of essential oil. The temperature of the air in the additional stream before it enters the evaporation chamber 8 is measured with a thermometer 6. The position of the regulator 5 is selected depending on the temperature, using interchangeable scales for each concentration of essential oil in the air stream and for each type of essential oil, or using nomograms. If enrichment of the air mixture with volatile or hardly volatile components of the essential oil is not required, one of the flow switches 24 or 25 is set to the position where the flow is shut off and the other is directed to the suction chamber of the ejector pump. In the evaporation chamber 8 from the surface of the wick 15 in a stream of additional air flow there is continuous evaporation of the essential oil, and due to capillary forces the same amount of new essential oil flows through the wick rod 15 to its surface located in the evaporation tank 14. The main air stream going in the air duct 3 under high pressure exits through the nozzle 19 of the ejector pump at high speed and enters the outlet bell 22. As a result, a vacuum is created in the suction chamber of the ejector pump, and Erez holes for sucking air to the air sucked from the surrounding atmosphere. The flow of this intake air is several times greater than the main air flow coming from the compressor 1. An additional air stream also passes into the intake chamber, passing through the evaporation chamber 8 and containing vapors of essential oil. All flows exit through the outlet bell 22 at a low speed. In the ejector pump, an effective mixture of an additional stream of air containing essential oil vapors is mixed with the rest of the air, and this mixture enters the breathing mask 11 to the patient through the inspiratory duct 10. The breathing mask does not fit snugly on the patient's face or has openings for the free exit of the air mixture. If the flow of the air mixture is 20-25 L in 1 min, which exceeds the minute volume of calm breathing 4-5 L in 1 min, and is approximately equal to the volumetric rate of inspiration, then this flow is enough to provide the desired therapeutic atmosphere in the breathing zone. The excess mixture freely enters the atmosphere of the room or is carried away by local exhaust ventilation.

 If it is necessary to enrich the air mixture with the volatile components of the essential oil, the air mixture flow switch 24 is set to the position passing the flow to the suction chamber of the ejector pump, and the air mixture from the outlet 18 to the ventilation is discharged by the flow switch 25.

 If it is necessary to enrich the air mixture with the volatile components of the essential oil, the flow switch 25 directs the air mixture flow from the outlet 18 to the suction chamber of the ejector pump, and the switch 24 discharges the air mixture from the outlet 17 to the ventilation.

Claims (2)

 1. DEVICE FOR INHALATION, for example, with essential oils, containing, in parallel, connected between the gas flow supply means and the displacement chamber with the mask and the connecting element, the main pipeline and the first additional one connected to the intermediate evaporation chamber at the level of the wick fastening, one end of which is located in its air cavity, and the other in its cavity for liquid components of inhalation, as well as an air flow regulator, characterized in that it is equipped with a second additional pipeline, while The neck cavity and the cavity for liquid components are made isolated from one another, and the wick is made in the form of a rod and fixed in the place of separation of the cavities of the evaporation chamber, while the second additional pipeline is connected in parallel to the first additional entrance to the air cavity from the side of the corresponding free end of the rod, and the exit to the mixing chamber, and additional pipelines are equipped with flow switches.  2. The device according to claim 1, characterized in that the free end of the connecting element is placed in the mixing chamber and is made in the form of a truncated cone, and the main pipe is connected to the mixing chamber by means of a throttle located opposite the small base of the cone.

Images