EA042742B1 - NOZZLE FOR NANOAEROSOL - Google Patents

Description

Technical field

The present invention relates to a device containing a nanoaerosol nozzle for releasing an aerosol with very fine particles.

State of the art

Various devices for releasing aerosols are known. The main problem with these devices is that the aerosol can still contain large amounts of relatively large particles larger than 200 nm. In FIG. 8 is a graph showing the particle size of an atomized aerosol versus concentration. The bell curve shows that there are many particles having a size of 200 nm or more, which leads to the accumulation of a mass of particles with a size of more than 200 nm. In other words, most of the mass of the sprayed aerosol is in the form of large particles that will not be released into the environment, which reduces the efficiency of the device.

WO 2011/082838 A1 discloses a method and apparatus for generating a nanoaerosol, wherein at least one liquid is sprayed as liquid particles in a nozzle through a nozzle opening along the discharge direction, the sprayed liquid particles are deflected from the discharge direction, and the larger liquid particles are at least least partially separated from the smaller liquid particles, the separated larger liquid particles are returned to the liquid to be sprayed, and the smaller liquid particles are released into the environment. The nozzle contains a float and a protrusion of the lower part. The sides and the upper part of the protrusion of the lower part are located at the same distance from the float. A cartridge is used, in which the nozzle and the liquid to be sprayed are located. According to the invention, a carrier gas flow is formed in a nozzle and at least one liquid to be sprayed is in contact with the carrier gas. However, despite the fact that this embodiment of the invention is improved, the device continues to produce many relatively large particles.

The essence of the invention

An object of the invention is to reduce the overall particle size of the sprayed aerosol in such a way as to reduce the mass of relatively large particles (from 200 to 300 nm or more). This problem is solved thanks to the device according to claim 1 of the claims. Other preferred embodiments of the invention are reflected in the dependent claims.

The aerosol dispensing device of the present invention comprises a cylindrical top body with a cylindrical top ledge extending downward from the top wall (preferably centrally in the top wall) such that a predetermined space is formed between the inside of the top body and the outside of the cylindrical top ledge, the top ledge contains a rod extending downward from the lower end of the upper ledge, while the upper housing contains at least one opening for discharging aerosol, a cylindrical lower housing with a lower base, also containing a lower opening in the lower base of the lower housing, preferably made in the center, a cylindrical lower a protrusion enclosing the bottom opening and extending upwards so as to provide a predetermined space between the inner side of the lower housing and the outer side of the cylindrical lower protrusion to form an aerosol container, a support frame rigidly attached to the inner side of the base and/or to the side of the lower housing, and a float covering the cylindrical lower ledge, wherein the inner circumferential shape of the float corresponds to the outer shape of the cylindrical ledge and the float is supported by a support frame so that the distance C between the lower ledge and the float is substantially the same around the entire circumference, and the distance T from the upper end of the float to the inner side of the upper end of the cylindrical lower lip is larger than the corresponding circumferential distance C. The greater distance on the top of the lower lip provides a larger space or compartment in which the surface tension of the liquid to be sprayed is completely relaxed and the particle size is significantly affected. This makes it possible to reduce the average particle size and, accordingly, to reduce the amount of mass accumulated in larger particles with a size of more than 200-300 nm. This improves the efficiency of the device compared to the prior art. The term cylindrical is used to describe any irregular shape or regular polygonal or circular shape, such as a square shape, a rectangular shape, a hexagonal shape, up to a circle.

Preferably, the lower or upper housing includes a side channel for introducing the aerosol into the container. Such a side channel can be used in more unlimited cases compared to a pre-filled device. Another option would be to introduce an aerosol-liquid through an air channel through an opening in the base of the device.

The distance between the lower end of the rod and the upper part of the float is preferably 3-6 mm, preferably 4.5-5.5 mm, most preferably substantially 5 mm. Such distances are ideal for spraying the liquid ejected from the nozzle.

The rod may be rounded or tapered at the end pointing down towards the float. Due to this geometry, the aerosol ejected by the nozzle is better atomized and the release of small particles can be facilitated.

The base of the lower housing is inclined so that the liquid in the container flows towards the center of the lower housing. This allows more efficient use of the aerosol liquid that has not been properly atomized into the air and has been returned to the container.

The spray aerosol outlet may be provided in the upper part of the upper body above a predetermined space. This ensures that only small particles exit the device.

In addition, the opening of the float nozzle is preferably made tapered downwards, i.e. it decreases in the downward direction. This improves the atomization of the aerosol liquid. The opening of the lower protrusion is usually round in shape and does not have a slope. In a preferred embodiment of the invention, the side walls of the nozzle opening in the float form an angle with the longitudinal axis of the device of 30-34°, preferably 31-33°, most preferably 32°.

The support frame may be below the float, i.e. if the frame contains support walls, they do not protrude axially higher than the float. This facilitates the release of the aerosol, since the upper region of the device does not contain walls or other obstacles to the opening for the release of the sprayed aerosol.

Brief description of the drawings

In FIG. 1 shows a side view of the device.

In FIG. 2 is a longitudinal sectional view taken along line A-A in FIG. 1.

In FIG. 3 shows a bottom view of the device of FIG. 1.

In FIG. 4 is a plan view of the device of FIG. 1.

In FIG. 5 shows a bottom view of the device of FIG. 1 with protective film removed.

In FIG. 6 shows an enlarged part I of the nozzle of FIG. 2.

In FIG. 7 is a plot of aerosol spray particle size versus availability for the present invention.

In FIG. 8 shows a graph of the size of the atomized aerosol particles against their presence according to devices of the prior art.

Preferred embodiments of the invention

In the following description, the terms axial, radial, circumferential are used with reference to the longitudinal axis shown in FIG. 1 and also used as an indicator for section A-A. Axial means along the axis, radial is the direction perpendicular to the axis, and circumferential means around the axis. When using terms indicating up, down, left, or right directions, these terms are used with reference to FIG. 1 or 2.

In FIG. 1 shows an aerosol dispensing device 1 comprising an upper housing 3 and a lower housing 2. Section A-A of FIG. 1 is shown in FIG. 2. The upper case 3 is supported by the lower case by mating elements 40, 42 arranged around the circumference of the cases 2, 3 so that the relative position of the upper case 3 and the lower case 2 is fixed. This makes it possible to use the space inside the housings 2, 3 without having to use support elements of the upper housing 3 on the inside.

Upper body 3 is cylindrical in shape and includes a cylindrical or tubular upper lip 30 which extends downward from the upper wall 32 towards the lower body 2. The upper lip 30 is preferably circular. Between the upper protrusion 30 and the inner wall of the upper housing 3 is a space in which the atomized aerosol can float and be released into the environment. To release the aerosol, the device 1 comprises at least one opening 7, which can be provided in the upper part of the upper body 3 anywhere on the side or top surface. Most preferably, a plurality of holes 7 are provided above the space 34 as shown in FIG. 4. The upper protrusion 30 includes a rod 18 located on the underside of the lower end 36 of the protrusion 30. The rod 18, also extending downward in the direction of the lower housing, more specifically extends to the float 12 and the lower protrusion 13 (as described below).

The lower body 2 is also cylindrical in shape and contains an opening in the lower base 9. This opening serves as an inlet for compressed air, which is used to atomize the aerosol liquid. In the initial position, the reverse side of the lower housing 2 can be covered with a seal 23 to protect the device from contamination. The seal can be easily removed before using the device 1. On the inside of the lower housing 2, the lower protrusion 13 accommodates the lower opening 5 and serves as a channel 8 for air. The lower protrusion 13 is hollow in order to act as a first channel for directing compressed air to the nozzle 10. On the top of the lower protrusion 30 there is an opening 28 through which air can flow. Hole 28 is a drilled hole, preferably without any wall inclination. Hole 28 has a diameter of about 0.4-0.8 mm, more preferably 0.6 mm. Between the lower protrusion 30 and the inner side of the walls of the lower housing 2 there is a space 11 serving as a container for the aerosol liquid. In addition, the lower housing includes a support frame 15 attached to it by means of the lower base 9 and/or side walls. The support frame supports a float 12 located on top of the lower ledge.

The support frame 15 can be made in any way while retaining the function of holding it in place. In the preferred embodiment of the invention shown in FIG. 2, the support frame is made up of a plurality of walls which are arranged circumferentially around the lower protrusion 13. These walls have small support recesses 29 in the upper portion connected to the support handle 27 of the float 12 also for axial stabilization of the float 12. The hole 16 of the float 12 has a size about 3-6 mm, preferably 4.5-5.5 mm, more preferably substantially 5 mm.

The float 12 is made in the form of a hollow cylindrical body. The outer part of the float 12 must be compatible with the support frame 15, so that the position of the float 12 is given inside the lower housing 2. The float 12 is located on the lower ledge 13 and accommodates it. Between the inner circumferential part of the float 12 and the outer circumferential part of the lower protrusion there is a distance C forming a second channel 14. This second channel 14 in the present preferred embodiment of the invention has an annular shape and a diameter of preferably 0.2 to 0.6 mm, more preferably 0 .35-0.45 mm, most preferably 0.4 mm. The upper portion of the lower protrusion and the upper portion of the float 12 are narrowed, respectively. Preferably, the distance between the constricted portions of the lower protrusion 13 and the float 12 is less than the distance C, and more precisely this distance is 0.1 mm less than the distance C, in particular it is 0.3 mm. It also improves liquid atomization. At the top of the lower protrusion 13, the inner surface of the float and the outer surface of the lower protrusion differ from each other, so that the distance T between them is larger than the distance C, so that a compartment 31 or space 31 is formed between them. In this compartment 31, liquid is sprayed into the first times thanks to a sudden increase in space and compressed air, which was directed through the internal channel of the lower ledge. The float 12 includes an opening 16 on the top through which fluid is ejected into the interior of the device. The opening 16 is preferably tapered so that the top end of the opening is wider than the bottom end. In this way, a kind of Venturi effect is achieved. In its smallest section, the hole 16 has a diameter of about 0.7-1.1 mm, preferably substantially 0.9 mm. The float 12 will not touch the base of the lower housing 2 so that there is a gap 25 between the base of the lower housing and the float 12 so that aerosol fluid can be introduced into the second channel 14.

On the side of the lower body 3, a side channel 22 may be provided for filling the container with an aerosol fluid. The side channel may be covered by a cover 24. Essentially, there are three ways to fill the container with aerosol fluid. First, it can be pre-filled so that the device can essentially be used once. Secondly, the aerosol fluid can be introduced through the bottom opening 5 and the first channel 8. To this end, an air hose for supplying compressed air to the device must be connected to a hose for supplying the aerosol fluid. This means that the aerosol fluid is initially introduced through the compressed air passage and only the larger particles will flow back into the container, as described below. And third, the device can be filled via the side channel 22. This allows the device to be reused without contaminating other parts such as the first channel.

Further, the use of the device 10 is described as shown in the figures. First, the seal 23 is removed and the opening 5 is connected to an air source which supplies compressed air to the channel 8. The pressure can be, for example, 2 bar, but it can be adjusted for certain applications of the device 1. The side channel 22 is connected to a source of aerosol fluid. Then, the aerosol fluid is introduced into the container 11 and the air flows through the channel 8, the nozzle 10 (i.e. holes 28 and 16) into the interior of the device 1. Due to the air flow, the second channel is formed under pressure (negative pressure), and then the aerosol in the container 11 is sucked into the second channel 14 and transferred to the compartment 31. In this compartment, the surface tension of the fluid is completely released and the fluid is atomized for the first time. Then it is ejected through the opening 16 into the spray section 19 of the internal space of the device and is directed to the side by the rod 18. In the space 17, cyclones are formed that rotate vertically around the nozzle. Then the atomized particles with a size less than 200-300 nm are carried by the air flow and released into the environment. Larger particles will then settle back into the containers 11 for further spraying.

As can be seen from FIG. 7, the invention provides a distribution in which the curve is not bell-shaped like the curve in the prior art graph of FIG. 8. This means that the largest part of the mass consists of particles with a size of less than 200 nm and, accordingly, the atomization of particles is greatly improved.

Reference designations.

- Device;

- lower case;

- upper case;

- bottom hole

- hole;

- first channel;

- lower base;

-

Claims (4)

10 - nozzle; 11 - space forming a container; 12 - float; 13 - cylindrical lower ledge; 14 - second channel; 15 - support frame; 16 - nozzle opening; 17 - cyclone space; 18 - rod; 19 - spray section; 20 - base of the lower case; 22 - side channel; 23 - removable seal; 24 - cover; 25 - bottom clearance; 27 - support handle; 28 - hole of the lower protrusion; 29 - reference recess; 30 - cylindrical upper ledge; 31 - department; 32 - upper wall; 34 - space in the upper case; 36 - lower end of the upper ledge; 40, 42 - mating elements. CLAIM 1. A device (1) containing a nanoaerosol nozzle for aerosol release, comprising a cylindrical upper body (3) and a cylindrical lower body (2), with the lower body (2) supporting the upper body (3), while the upper body (3 ) contains the top wall (32); a cylindrical protrusion (30) of the upper body (3) extending downward from said upper wall (32), so that a space (34) is formed between the circumferential inner side of the upper body (3) and the outer side of the cylindrical protrusion (30) of the upper body (3) , wherein the protrusion (30) of the upper body (3) contains a rod (18) extending downward from the lower end (36) of the protrusion (30) of the upper body (3), and the upper body (3) contains at least one hole (7) for the release of sprayed aerosol; wherein the specified lower body (2) contains the base (9) of the lower body (2) and also contains the lower hole (5) in the base (9) of the lower body (2); cylindrical protrusion (13) of the lower body (2), covering the lower opening (5) and extending upwards, so that a space (11) is formed between the inner side of the lower body (2) and the outer side of the cylindrical protrusion (13) of the lower body (2) with forming an aerosol container; a support frame (15) rigidly attached to the inside of the base (9) of the lower body (2) and/or to the inside of the lower body (2); and a float (12) covering the cylindrical ledge (13) of the lower body (2), wherein the inner circumferential shape of the float (12) corresponds to the outer shape of the cylindrical ledge (13) of the lower body (2), while the float (12) is supported by the support frame ( 15), so that the distance C between the protrusion (13) of the lower body (2) and the float (12) is essentially the same around the entire circumference, characterized in that the largest distance T from the upper end of the cylindrical protrusion (13) of the lower body (2) to the inner side of the float (12) along the longitudinal axis of the cylindrical protrusion (13) of the lower body (2) is greater than the specified distance C, and the upper section of the protrusion (13) of the lower body (2) and the upper section of the float (12) are respectively narrowed. 2. Device (1) according to claim 1, in which the distance between the narrowed sections of the protrusion (13) of the lower body (2) and the float (12) is less than the corresponding specified distance C. 3. Device (1) according to any one of the preceding claims, wherein the lower or upper housing (2, 3) comprises a side channel (22) for introducing the aerosol into the container. 4. Device (1) according to any one of the preceding claims, wherein the distance d between the lower end of the rod (18) and the upper end of the float (12) is essentially 3-6 mm, preferably 4.5-5.5 mm, most preferably 5 mm. -