FR3127142A1 - venturi device with multiple injection port for ONE liquid formulation atomization - Google Patents

Abstract

A Venturi device having a multiple injection port for liquid formula atomization A Venturi device (100) comprising: a central longitudinal axis (X1); a mounting flange (160) on which a liquid reservoir (200) containing a liquid formula (L) is removably and liquid-tightly mounted; and an internal passage (110) extending along the longitudinal central axis (X1), the internal passage comprising: a converging section (130) comprising an inlet (132) with an inside diameter (D1) and an outlet (134) with an inner diameter (D4) respectively located on each of its ends; a diverging section (140) including an inlet (142) with an inside diameter (D5) and an outlet (144) with an inside diameter (D2) respectively located on each of its ends; and an accelerating and mixing section (150) comprising an inlet (152) with an inner diameter (D3) and an outlet (154) with an inner diameter (D3) respectively located at each of its two ends; wherein the output (134) of the converging section (130) is connected to the input (152) of the accelerating and mixing section (150), and the output (154) of the accelerating and mixture (150) is connected to the inlet (142) of the diverging section (144), characterized in that two or more injection ports (120) are formed in the mounting flange (160), which penetrate the flange assembly (160) in the internal passage (110), and in that the liquid formula (L) has a viscosity greater than 0.5 Pa･s. Figure for abstract: 2

Description

venturi device with multiple injection port for ONE liquid formulation atomization

The present invention relates to a Venturi device having a multiple injection port for atomizing and injecting a liquid formula, such as water, oil, lotion or the like, for transdermal delivery. The present invention also relates to an injection system comprising such a Venturi device.

[Background of the invention].

A liquid formula, such as a liquid lotion including hyaluronic acid, is typically applied to specific parts of the user's body, such as the face, hands, and arms, via shallow transdermal delivery (i.e. i.e. shallow dermal administration).

In particular, many studies have found that the transdermal absorption effect is enhanced when 100 m/s or more is achieved by accelerating particles of the liquid formula. The use of a Venturi tube to atomize and deliver the liquid formula is well known in the prior art.

US20180099104A1 (Gold NanoTech Inc.) discloses a liquid introduction device transferring a fixed amount of liquid into atomized particles. The liquid introduction device includes a vial containing liquid and a Venturi tube that is in fluid communication with the vial. A pressurized gas flows through the Venturi tube and atomizes the liquid contained in the vial.

US20110137281A1 (Gold NanoTech Inc.) discloses a drug delivery device for injecting cosmetic and medical agent. The delivery device includes a drug delivery pressurization tube having a Venturi tube shape and a container that contains the drug and in fluid communication with the drug delivery pressurization tube. A pressurized gas flows through the medication delivery pressurization tube and atomizes the liquid in the container.

However, when a Venturi tube with a general injection port was used, a flow instability phenomenon called Karman vortex was observed, and it had a negative effect on the liquid formula injection, causing a problem. increase in particle size or reduction in acceleration and mixing ability of the Venturi tube.

Typically the Venturi tube has one fluid inlet and one outlet. In order to achieve liquid injection and acceleration and mixing at the same time, it is necessary to provide a connection passage through which the formula can be injected at the midpoint of the Venturi tube, i.e. say the point where the acceleration and mixing of the fluid is maximized. Usually the connection passage is located in an acceleration and mixing section of the Venturi or closer to the fluid inlet. When the flow of the fluid is accelerated, this passage spontaneously induces the liquid towards the center of the Venturi tube where the strong pressure and the high speed of the fluid cause a reduction of particles of the induced liquid and its transfer towards the exit.

However, during injection, the result of the injection is irregular, especially when injecting a high viscosity liquid. The liquid formula injected through the outlet has a speed of 100 m/s or more, which must give a higher capacity for transdermal absorption of the cosmetic composition. The higher the velocity of the injected particles, the more unstable the particle size distribution. It is a well-known phenomenon in fluid dynamics, more specifically, a Karman vortex which exhibits a repeated pattern of vortices, responsible for the unstable separation of fluid flow around an obstacle in the flow direction. In the Venturi system, the single liquid injection port acts as the obstacle, and the injection result generates a Karman vortex.

The object of the present invention is to improve the performance of a Venturi tube, with the key to improving the stability of the injection performance. In particular, the present invention aims to improve the atomization performance by using a cosmetic formula having a high viscosity (such as greater than 0.5 Pa･s).

In order to achieve the object mentioned above, the present invention provides a Venturi device comprising: a longitudinal central axis; a mounting flange on which a liquid reservoir containing a liquid formula is detachably and liquid-tightly mounted; and an internal passage extending along the longitudinal central axis, the internal passage comprising: a converging section comprising an inlet with an internal diameter and an outlet with an internal diameter respectively located on each of its two ends; a diverging section comprising an inlet with an inner diameter and an outlet with an inner diameter respectively located on each of its two ends; and an accelerating and mixing section comprising an inlet with an inner diameter and an outlet with an inner diameter respectively located at each of its two ends; wherein the outlet of the converging section is connected to the inlet of the accelerating and mixing section, and the outlet of the accelerating and mixing section is connected to the inlet of the diverging section, characterized in that that two or more injection ports are formed in the mounting flange, which penetrate the mounting flange into the internal passage, that the liquid formulation has a viscosity of at least 0.5 Pa･s and that the size of the inner diameter of the inlet is 0.1-3mm, preferably 0.3-0.6mm.

In an embodiment according to the present invention, the injection ports penetrate the acceleration and mixing section, and the two or more injection ports are aligned in a direction perpendicular to the longitudinal central axis.

In one embodiment according to the present invention, a ratio inside diameter of the inlet of the converging section: inside diameter of the acceleration and mixing section: inside diameter of the outlet of the diverging section is 2:1: 2 to 3:1:3. The inside diameter of the converging section decreases linearly or exponentially from the inlet to the outlet, and the inside diameter of the diverging section increases linearly or exponentially from the inlet to the outlet.

The present invention also provides an injection system comprising: the Venturi system mentioned above; a reservoir containing a liquid formula to be injected and in communication with the internal passage of the Venturi system; and a device coupled to the inlet of the converging section of the Venturi system and supplying it with pressurized gas.

In one embodiment according to the present invention, the device comprises a gas tank containing pressurized gas or a cylinder and a piston arranged and slidable in the cylinder to pressurize the gas to be supplied to the Venturi system.

In one embodiment according to the present invention, the piston is driven by means of an electric motor. The gas under pressure is air, CO ₂ , N ₂ , N ₂ O, NO, O ₂ , or a non-toxic gas with bioavailability.

The present invention may be better understood by reading the following description of its non-limiting embodiments, and by examining the accompanying schematic drawings, in which:

- there shows a cross-sectional view along a central longitudinal axis of an embodiment of a Venturi device according to the present invention;

- there shows a plan view of the Venturi device according to the present invention;

- there shows a cross-sectional view of an injection system with the Venturi device according to the present invention;

- there shows a plan view of the Venturi device used in a performance test;

- there shows a cross-sectional view along section AA on the ;

- there shows a schematic view of the system used in the performance test;

- there shows a result of the particle velocity measured at two points when using the prior art Venturi device;

- there shows a result of the particle velocity measured at two points when using the Venturi device according to the present invention;

- there shows a result of distribution frequency versus particle diameter and its cumulative volume when using a Venturi device in the prior art; And

- there shows a result of the distribution frequency versus the particle diameter and its cumulative volume when using the Venturi device according to the present invention.

[Description of Embodiments].

Some exemplary embodiments of the present invention will now be described with reference to Figures 1-5e. In each figure, the scale ratio between the width, length, height, diameter or the like of each element may not be constant and may differ from the actual ratio. It should be noted that in some figures, certain elements or features are drawn larger or smaller than they actually are, to emphasize these.

There schematically illustrates a cross-sectional view along a central longitudinal axis X ₁ of an embodiment of a Venturi device 100 according to the present invention with a liquid reservoir 200 containing a liquid formula L to be injected. There schematically illustrates a plan view of the Venturi device 100. The Venturi device 100 includes a mounting flange 160 to which the liquid reservoir 200 is detachably and liquid-tightly mounted by suitable means. Reservoir 200 may include a flange 210 on its opening side, which matches flange 160 of Venturi device 100. By way of example, but not limited to, liquid reservoir 200 may be threaded onto the flange. mounting bracket 160. Any other suitable fastener may be used.

The Venturi device 100 comprises an internal passage 110 extending continuously along the central longitudinal axis X ₁ . As illustrated on the , the internal passage 110 comprises a convergent section 130, a divergent section 140 and an acceleration and mixing section 150, which are continuously connected along the central longitudinal axis X ₁ . The accelerating and mixing section 150 is arranged between the converging section 130 and the diverging section 140.

The converging section 130 has an inlet 132 and an outlet 134 respectively located on each of its ends. The acceleration and mixing section 150 also has an inlet 152 and an outlet 154 respectively located on each of its ends. In addition, the diverging section 140 has an inlet 142 and an outlet 144 respectively located on each of its two ends. The output 134 of the converging section 130 is connected to the input 152 of the acceleration and mixing section 150 in a regular and continuous manner. Similarly, the output 154 of the acceleration and mixing section 150 is connected to the input 142 of the diverging section 140 in a regular and continuous manner.

The inlet 132 and the outlet 134 of the converging section 130 have an inside diameter (maximum inside diameter) D ₁ and an inside diameter (minimum inside diameter) D ₄ , respectively. Likewise, the inlet 142 and the outlet 144 of the diverging section 140 have an inside diameter D ₅ (minimum inside diameter) and an inside diameter (maximum inside diameter) D ₂ , respectively. In this embodiment, the inside diameter of converging section 130 decreases linearly from inlet 132 to outlet 134, while the inside diameter of diverging section 140 increases linearly from inlet 142 to outlet. 144. However, the inner diameters of converging section 130 and diverging section 140 can decrease and increase exponentially, respectively.

In this embodiment, the accelerating and mixing section 150 has a constant inside diameter D ₃ from inlet 152 to outlet 154. Accordingly, in this embodiment, the inside diameter D ₄ of outlet 134 of the converging section 130 is the same as the inside diameter D ₃ of the accelerating and mixing section 150, and the inside diameter D ₅ of the inlet 142 of the diverging section 140 is also the same as the inside diameter D ₃ of the accelerating and mixing section 150. A D ₁ :D ₃ :D ₂ ratio is preferably from 2:1:2 to 3:1:3. Other reports can also be used as needed.

As best illustrated by the , two injection orifices 120 are formed in a mounting flange 160 and arranged symmetrically with respect to the central longitudinal axis X ₁ . In other words, the injection orifices 120 are aligned in a direction perpendicular to the longitudinal central axis X ₁ . Each of the injection ports 120 penetrates the mounting flange 160 into the internal passage 110. Accordingly, the internal passage 110, particularly the acceleration and mixing section 150, is in fluid communication with the liquid reservoir 200 mounted to mounting flange 160 via injection ports 120. Two injection ports 120 are formed in this embodiment, while three or more injection ports 120 may be formed.

With reference to the , a cross-sectional view of an exemplary embodiment of an injection system 300 comprising the Venturi device 100 according to the present invention is schematically illustrated. The injection system 300 mainly comprises a housing 302, an electric motor 304, a gearbox 306, a cylinder 308, a piston 310, a compression spring 312, a battery 314, an injection nozzle 316, a fixing 318, and a 320 muffler.

The piston 310 is inserted in the cylinder 308 and can slide rearward (away from the injection nozzle 316) and forward (towards the injection nozzle 316) in the cylinder 308. The compression spring 312 is attached to housing 302 at one end and is coupled to piston 310 at the other end. The electric motor 304 is coupled to the gearbox 306, and a pinion of the gearbox 306 engages a rack provided on the piston 310. The motor 304 is powered by the battery 314. The Venturi device 100 is fixed to the housing 302 by means of fastener 318 so that inlet 132 of converging section 130 is arranged next to injection nozzle 316. Silencer 320 is arranged to surround outlet 144 of diverging section 140.

In use, battery 314 powers motor 304, and the power output of motor 304 is transmitted to piston 310 via gearbox 306. Rotation of an axis of motor 304 is converted into linear reverse motion piston 310 into cylinder 308 via gearbox 306 and the rack provided on piston 310. Rearward movement of piston 310 compresses compression spring 312. When piston 310 returns to a certain position, the rack disengages from the gearbox 306, which has the effect of advancing the piston 310 thanks to an elastic force of the compression spring 312. The advance of the piston 310 compresses the air in the cylinder 308, and the air compressed air is injected into the internal passage 110 via the injection nozzle 316. The compressed air flowing through the internal passage 110 is further accelerated at the accelerating and mixing section 150 and generates negative pressure to suck the liquid formula contained in the reservoir 200 into the acceleration and mixing section 150 via the injection ports 120. The sucked liquid formula is atomized by the compressed air and injected through the outlet 144 of the divergent section 140.

A more detailed configuration and action of the injection system is disclosed in Japanese Patent Application No. 2020-213550. Instead of the motorized piston, the injection system can use a gas tank (shown on the ) containing gas under pressure. The gas under pressure can be air, CO ₂ , N ₂ , N ₂ O, NO, O ₂ or a non-toxic gas with bioavailability.

The inventor implemented the test to confirm the improvement of the Venturi device according to the present invention over a prior art Venturi device. A Venturi device illustrated in Figures 4a and 4b is used. The difference between the Venturi device according to the present invention and that of the prior art is the number of injection ports. The Venturi device according to the present invention has two injection ports, whereas the Venturi device of the prior art has a single injection port.

The dimension of the Venturi device used in the test is as follows.

- Venturi tube length: 52.5 mm

- Injection orifice diameter: 0.3 mm

- Acceleration and mixing section diameter: 3.5 mm

- Outlet diameter: 9 mm

The liquid used is a mixture of water and a formula comprising 1% hyaluronic acid solution with 0.7% phenoxyethanol. The viscosity of the liquid is 3.37 Pa･s. The input gas is CO ₂ , air, nitrogen, or any other gas that does not interact with the cosmetic ingredients or formulas. The inlet gas pressure is 1 to 10 bar.

There schematically illustrates the model for measuring the velocity of the injected fluid. Point 1 is located at the radial and longitudinal center of the accelerating and mixing section to which the liquid is supplied from the reservoir. Point 2 is located at the radial center of the output.

Figures 5b and 5c respectively illustrate graphs showing variations in liquid velocity as a function of the duration of the injection, in which the duration is represented on a transverse axis and the liquid velocity is represented on a vertical axis. There shows the result when using a Venturi device having a single injection port, while the shows the result when using a Venturi device with two injection ports. The inventor has observed the result that the Venturi device having two injection ports can obtain a more stable liquid velocity than that of the Venturi device having a single injection port.

Figures 5d and 5e illustrate graphs showing fluctuations in liquid particle size. The figure shows the result when using a Venturi device having a single injection port, while the shows the result when using a Venturi device with two injection ports. Further, Table 1 shows an average diameter in the cumulative volume distribution of particle diameter. "Dv10 (small 10%)" in Table 1 means the 10th percentile of the cumulative volume distribution, which is a size below which 10% of the sample volume falls, so it is used to track changes in finest particles in the population. "Dv50 (small 50%)" in Table 1 means the 50th percentile counted from the fine side of the cumulative volume distribution. "Average_D66%" in Table 1 means an average of 66% of the average particle diameter in the cumulative volume distribution. “Deviation” indicates the percentile of the difference in average diameter between the single orifice and the two orifices with respect to the average diameter of the single orifice. The inventor has observed that the Venturi device having two injection ports can obtain finer particles than the Venturi device having a single injection port.

Dv10 (small 10%) Dv50 (small 50%) Average_D66% Single orifice 54.24μm 629.4μm 138.3μm Two holes 18.01μm 226.6μm 46.36μm Gap 66.6% 64.5% 66.5%

The specific data of an example of the Venturi device according to the embodiment described above is listed below. However, the present invention is not limited to these values:

- length of the Venturi device: 30 to 100 mm;

- internal diameter of the acceleration and mixing section: 3.5 mm;

- diameter of the inlet of the converging section and of the outlet of the diverging section: 2 to 3 times greater than the internal diameter of the acceleration and mixing section;

- diameter of the injection orifice: 0.1 to 1 mm, preferably 0.1 to 0.6 mm.

The preferred embodiments of the present invention have been explained above in detail with reference to the drawings. However, the present invention is not limited to these embodiments, and various modifications and changes may be made to the embodiments described above without departing from the scope of the present invention, and such modifications and changes are also included within the scope of the present invention.

Claims (10)

Venturi device (100) comprising:
a longitudinal central axis (X1);
a mounting flange (160) on which a liquid reservoir (200) containing a liquid formula (L) is detachably and liquid-tightly mounted; And
an internal passage (110) extending along the central longitudinal axis (X ₁ ), the internal passage comprising:
a converging section (130) comprising an inlet (132) with an inside diameter (D ₁ ) and an outlet (134) with an inside diameter (D ₄ ) respectively located on each of its two ends;
a diverging section (140) comprising an inlet (142) with an inside diameter (D ₅ ) and an outlet (144) with an inside diameter (D ₂ ) respectively located on each of its ends; And
an accelerating and mixing section (150) comprising an inlet (152) with an inner diameter (D ₃ ) and an outlet (154) with an inner diameter (D ₃ ) respectively located on each of its ends;
wherein the output (134) of the converging section (130) is connected to the input (152) of the accelerating and mixing section (150), and the output (154) of the accelerating and mixture (150) is connected to the inlet (142) of the divergent section (144),
characterized in that two or more injection ports (120) are formed in the mounting flange (160), which penetrate the mounting flange (160) into the internal passage (110), and in that the liquid formula ( L) has a viscosity greater than 0.5 Pa･s. Venturi device (100) according to claim 1, wherein the injection ports (120) enter the acceleration and mixing section (150). Venturi device (100) according to claim 1 or 2, wherein the two or more injection ports (120) are aligned in a direction perpendicular to the central longitudinal axis (X ₁ ). Venturi device (100) according to any one of claims 1 to 3, in which a ratio inside diameter (D ₁ ) of the inlet (132) of the converging section (130): inside diameter (D ₃ ) of the converging section acceleration and mixing (150): inside diameter (D ₂ ) of the outlet (144) of the diverging section (140) is 2:1:2 or greater. Venturi device (100) according to any one of claims 1 to 4, wherein the inside diameter of the converging section (130) decreases linearly or exponentially from the inlet (132) to the outlet (134), and in wherein the inside diameter of the diverging section (140) increases linearly or exponentially from the inlet (142) to the outlet (144). Injection system (300) comprising:
the Venturi system (100) according to any one of claims 1 to 5;
a reservoir (200) containing a liquid formula (L) to be injected and in communication with the internal passage (110) of the Venturi system (100); And
a device coupled to the inlet (132) of the converging section (130) of the Venturi system (100) and supplying gas under pressure thereto An injection system (300) according to claim 6, wherein the device comprises a gas reservoir containing pressurized gas to be supplied to the Venturi system (100). Injection system (300) according to claim 6, in which the device comprises a cylinder (308) and a piston (310) arranged to be able to slide in the cylinder (308) in order to pressurize the gas to be supplied to the Venturi system. (100). Injection system (300) according to claim 8, in which the piston (310) is driven by means of an electric motor (304). Injection system (300) according to any one of claims 6 to 9, in which the pressurized gas is air, CO ₂ , N ₂ , N ₂ O, NO, O ₂ , or a non-toxic gas at bioavailability.