JP2016179471A - Aerosol spray device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an aerosol spray device capable of easily spraying with a simple structure, and obtaining higher "feeling of cooling effect".SOLUTION: An aerosol spray device sprays a propellant-containing liquid sealed inside through a spray flow channel 7. At a spray orifice 11 of the spray flow channel 7, a fine particle generating part 12 making a spray sound greater than or equal to 90 dB when background is 35 dB and spraying the liquid in a mist form is arranged.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an aerosol injection device.

  There is a product that provides comfort by cooling articles covering the body such as clothing and shoes (Patent Document 1). The shoe swell improvement spray of Patent Document 1 sprays a liquid that lowers the temperature by vaporization heat on the inside of the shoe. Thereby, when this liquid is sprayed on the inside of the shoe, the temperature in the shoe can be instantaneously lowered, and the shoe stuffiness is improved.

  As an apparatus for injecting the liquid as described above, there are aerosol injection apparatuses as shown in Patent Document 1 and Patent Document 2. In the aerosol injection device described in Patent Document 2, a resonance chamber communicating with the injection flow path is provided on the side opposite to the injection port on the outer peripheral surface of the button. Thereby, the injection sound generated at the injection port and the vicinity thereof is increased in the resonance chamber, and the injection sound can be set to 100 dB when the background volume is 40 dB. For this reason, the injection sound becomes a volume that can be easily heard by humans, and it is possible to more easily recognize that the injection is being performed.

JP 2003-106724 A JP 2001-293402 A

  By the way, in order to improve the cooling effect of the injection target (for example, an article covering the body), a cooling sensation material such as menthol or lactate menthyl is used rather than injecting the liquid described in Patent Document 1 onto the injection target. It is thought that it is more effective to spray the contained liquid onto the object to be ejected, but these cooling sensations give a burning sensation or irritation to the skin when the concentration exceeds a certain level, so there is an upper limit to the concentration that can be used. is there. Accordingly, in order to maximize the cooling effect felt by humans, it is necessary to set the concentration of the cooling sensation material to a maximum usable concentration. However, in recent years, a higher cooling effect is desired by consumers. In this case, the concentration of the cooling sensation material cannot be increased any more, so a factor different from the adjustment of the concentration of the cooling sensation material is added to enhance the cooling effect actually felt by consumers, or psychological cooling. It is necessary to make the effect feel high, that is, to increase the “cooling effect”.

  In addition, when the liquid is ejected to an article covering the body, particularly a narrow closed space such as the inside of a shoe, it is necessary to reduce the size of the button. In addition, as described above, in order to inject a liquid containing a cooling sensation material in order to enhance the cooling effect, it is necessary to inject the liquid as widely as possible inside the shoe to widen the range in which the effect of the liquid can reach. There is. However, in the aerosol device as described in Patent Document 2, since the button is enlarged, when the operator tries to inject into the shoe, it is difficult to inject, and the injection area becomes narrow due to deviation in the injection area. There is a fear.

  An object of the present invention is to solve these problems of the prior art, and to provide an aerosol injection device that is easy to inject with a simple configuration and can obtain a higher “cooling effect”.

  In order to achieve the above object, the present invention provides an aerosol injection apparatus for injecting a liquid containing a refreshing agent and a propellant encapsulated therein via an injection flow path, and a background at an injection port of the injection flow path. The present invention provides an aerosol injection device characterized by including a fine particle generation unit for injecting a liquid in the form of a mist with an injection sound of 90 dB or more when the value is 35 dB.

  According to the aerosol injection device of the present invention, the injection port includes the fine particle generation unit, and the fine particle generation unit has a function of setting the injection sound when the background is 35 dB to 90 dB or more and the liquid in a mist shape. It has the function to inject. That is, at the injection port, an explosion occurs when the liquid propellant constituting a part of the liquid is instantly vaporized. By this explosion, the liquid is turned into particles and becomes a mist, and the vibration of the mist resonates in the injection flow path to generate an injection sound. The fine particle generation unit sets the ejection sound generated at this time to 90 dB or more when the background is 35 dB. In that case, since the fine particle generation unit can eject the liquid as a mist, the injection area can be wide. Here, the mist form is a general term for fine liquid particles, which means a state in which the liquid is evaporated and condensed, and a state in which the injected liquid can be visually recognized as white smoke. . As described above, in the present invention, the injection sound can be set to 90 dB or more by the fine particle generation unit, and a psychologically high cooling effect feeling can be obtained due to the influence of the sound, and the injection area can be widened and the liquid can be used. The effect is easily obtained.

  The fine particle generation unit is preferably configured by setting the inner diameter of the injection flow path to 1.0 mm to 2.0 mm, and further, the inner diameter of the injection flow path is set to 1.2 mm to 1.8 mm. More preferred. When the fine particle generation unit has such a configuration, the propellant is effectively vaporized at the injection port, and the liquid can be injected in a mist-like manner, and a sufficient space in which the injection sound generated by the explosion resonates is sufficient. And the injection sound can be effectively 90 dB or more. In addition, since the fine particle generation unit can be configured only by setting the inner diameter size of the injection flow path within the above-described range, the configuration can be simplified and injection can be easily performed.

  It is preferable that the injection flow path is a straight type. Here, the straight type means that the injection port and the injection flow path are linearly connected.

  The said structure WHEREIN: The said liquid can be injected with respect to the inner side of shoes. A relatively hard material is used for shoes, and a closed space is formed. As a result, when liquid is ejected to the inner side of the shoe, the sound generated from the ejection port reflects and resonates in the closed space formed on the inner side of the shoe, effectively generating a sound of 90 dB or more. Can do. Moreover, the mist-like liquid can be blown back inside the shoe to enlarge the spray area.

  The propellant is preferably liquefied petroleum gas or dimethyl ether. Liquefied petroleum gas (LPG) or dimethyl ether (DME) is instantly vaporized by contact with air, and can effectively generate an explosion. Thereby, the injection sound can be set to 90 dB or more, and the effect of making the liquid mist can be easily obtained.

  As described above, according to the present invention, it is easy to inject with a simple configuration, and a higher cooling effect can be obtained.

It is a fragmentary sectional view showing a 1st embodiment of an aerosol injection device concerning the present invention. It is sectional drawing of the modification of the injection button of the aerosol injection apparatus shown in FIG. It is sectional drawing of the injection button which shows 2nd Embodiment of the aerosol injection apparatus which concerns on this invention. It is an injection button which shows 3rd Embodiment of the aerosol injection apparatus which concerns on this invention, (a) is sectional drawing, (b) is a front view of a microparticle generation | occurrence | production part. It is sectional drawing which shows the injection button of the aerosol injection apparatus of the implementation goods used in the Example. It is the graph and table | surface which show the relationship between the magnitude | size of the internal diameter of an injection flow path, and an injection sound. It is a graph which shows the relationship between the magnitude | size of the internal diameter of an injection flow path, and a cooling effect feeling. It is a perspective view which shows the method of spraying to a Kim towel from an ejection opening.

  Hereinafter, an aerosol injection device according to an embodiment of the present invention will be specifically described with reference to the drawings. The same or similar parts in the drawings are denoted by the same reference numerals and description thereof is partially omitted.

  This aerosol ejecting apparatus ejects liquid onto a body wearing tool as an ejected object. In each of the following embodiments, the liquid is composed of a liquid agent to be ejected onto an object to be ejected and a liquid propellant. The liquid agent is a mixture of a solvent such as ethanol and a refreshing agent such as menthol or menthol lactate. By injecting this liquid onto the body wearing device, the body wearing device has a cooling effect for a predetermined time. Become. As the propellant, liquefied petroleum gas (LPG) or dimethyl ether (DME) is preferably used. In this embodiment, liquefied petroleum gas is used. In this embodiment, the ratio of the propellant in the liquid is increased (for example, liquid agent: propellant = 3: 7).

  As shown in FIG. 1, the aerosol injection device according to the first embodiment includes an aerosol container 2 that stores a liquid and an injection button 1. The injection button 1 has a so-called straight-type injection flow path, forms an upper surface, and has a corrugated pressing portion 3 to be a pressing portion of the injection button 1 and an upper end of the aerosol container 2 provided on the inner diameter side. A stem connection portion 4 that is externally fitted to a stem 5 of a protruding valve mechanism (not shown), an outer peripheral wall 14 that forms an outer peripheral surface, and an injection nozzle 15 that has a liquid injection port 11 are provided. The injection nozzle 15 has a tapered portion and a cylindrical portion whose outer diameter side is reduced in diameter toward the opposite outer peripheral wall side, and the cylindrical portion is fitted in the horizontal hole 10 that opens in the outer peripheral wall. On the inner diameter side of the injection nozzle 15, a hole portion is formed which has a constant inner diameter D and forms a linear injection flow path. The tip of the injection nozzle 15 protrudes from the outer peripheral wall 14 to the outer peripheral side.

  The injection button 1 is provided with a first injection flow path 6 that is continuous with a hole 13 formed on the inner diameter side of the stem connection portion 4 and extends in the axial direction (vertical direction) of the stem 5. And a second injection flow path 7 extending in a direction (horizontal direction) substantially orthogonal to the first injection flow path 6 is provided. The second injection channel 7 has a constant inner diameter D and is circular in cross section.

  Accordingly, the valve mechanism is opened by pressing the pressing portion 3 and pushing down the stem 5 to the aerosol container 2 side via the stem connecting portion 4, and the liquid in the aerosol container 2 is introduced into the injection button 1. . The liquid introduced from the stem 5 into the first injection flow path 6 is introduced into the second injection flow path 7, can flow through the second injection flow path 7, and can be injected from the tip thereof. Thus, the tip of the second ejection flow path 7 becomes the ejection port 11 that ejects the liquid. Here, the injection port 11 refers to, for example, a region indicated by a range A in FIG. That is, the ejection port 11 in the present invention refers not only to the distal end edge of the second ejection flow path 7 but also the distal end region including the distal end edge.

  The injection port 11 of the second injection flow path 7 includes a fine particle generation unit 12. The fine particle generation unit 12 has both a function of making the injection sound 90 dB or more when the background is 35 dB and a function of ejecting the liquid in a mist form. That is, an explosion occurs when the liquid propellant that constitutes a part of the liquid is instantaneously vaporized at the injection port 11. By this explosion, the liquid is turned into particles and becomes a mist, and the vibration of the mist resonates in the injection flow path to generate an injection sound. The fine particle generation unit 12 sets the ejection sound generated at this time to 90 dB or more when the background is 35 dB. At that time, since the fine particle generation unit 12 can eject the liquid as a mist, the spray area can be wide. Here, the mist form is a general term for fine liquid particles, which means a state in which the liquid is evaporated and condensed, and a state in which the injected liquid can be visually recognized as white smoke. . The fine liquid particles to be ejected in the aerosol ejecting apparatus of the present invention are those having a particle diameter of, for example, 10 μm to 50 μm.

  The fine particle generation unit 12 has an inner diameter D (a diameter when the cross section of the injection flow path is circular and a short axis when the injection flow path is circular) of 1.0 mm to 2.0 mm. More preferably, the thickness is 1.2 mm to 1.8 mm. In the present embodiment, the fine particle generation unit 12 is configured with the inner diameter D of the second injection flow path 7 being 1.2 mm. When the fine particle generation unit 12 has such a configuration, the propellant is effectively vaporized at the injection port 11 and the liquid can be injected in the form of a mist, and the space in which the injection sound generated by the explosion resonates. Can be sufficiently secured, and the injection sound can be effectively 90 dB or more. In addition, since the fine particle generation unit 12 can be configured only by setting the inner diameter size of the second injection flow path 7 within the above-described range, the configuration can be simplified and injection can be easily performed.

  If the inner diameter D is smaller than 1.0 mm (usually the inner diameter size is 0.5 mm to 0.7 mm), a sufficient resonance space cannot be secured and the injection sound becomes smaller than 90 dB. Further, liquid is clogged in the ejection flow path 7 and vaporization is hindered, and generation of fine particles is not promoted, making it difficult to eject in the form of a mist, resulting in a narrow ejection area. When the inner diameter D exceeds 2.0 mm, the resonance space becomes too wide and resonance is not promoted, and the injection sound becomes smaller than 90 dB. In addition, when the liquid propellant comes into contact with air at the injection port 11, the pressure drop is insufficient and vaporization is hindered. It becomes.

  Moreover, in order to effectively set the jetting sound to 90 dB or more, the jetting amount of the liquid is preferably 1.5 g to 3.0 g per second, and more preferably 2.0 g to 2.5 g. Is more preferable.

  By the way, the liquid in the present embodiment has a cooling effect for a predetermined time by being sprayed on an article covering the body. By providing the fine particle generation unit 12 in the aerosol injection device of the present invention, the injection sound can be 90 dB or more, and a psychologically high cooling effect can be obtained due to the influence of the sound. In addition, the spray area can be widened, and the cooling effect by the liquid can be easily obtained. In this way, the user can obtain a high cooling effect feeling by adding a cooling effect feeling felt from the jetting sound at the time of liquid jetting to the actual cooling effect felt from the liquid component.

  Further, when the article covering the body is used as a shoe and the liquid is ejected to the inside of the shoe, a higher cooling effect can be obtained. A relatively hard material is used for shoes, and a closed space is formed. As a result, when the liquid is ejected to the inside of the shoe, the sound generated from the ejection port 11 reflects and resonates in the closed space formed on the inside of the shoe, effectively generating a sound of 90 dB or more. be able to. Moreover, the mist-like liquid can be blown back inside the shoe to enlarge the spray area.

  Thus, according to the aerosol injection apparatus which concerns on this invention, it is easy to inject with a simple structure and can obtain a higher feeling of cooling effect.

  FIG. 2 shows a modification of the aerosol injection device of the first embodiment. The aerosol injection device in FIG. 2 is different from the aerosol injection device according to the first embodiment in the form of the injection port. As shown in FIG. 2, this aerosol spray device is one in which the spray nozzle 15 is omitted and has a mounting body 16 attached to the horizontal hole 10. The mounting body 16 includes a flange portion 18 and a cylindrical portion 20, and the mounting body 16 is mounted by fitting the cylindrical portion 20 into the horizontal hole 10. An axial hole 26 is formed on the inner diameter surfaces of the flange 18 and the cylindrical part 20, and this axial hole 26 becomes the second injection flow path 7.

  In this modification, the injection port 11 refers to a region indicated by a range A in FIG. Thus, in the modification, the injection port 11 is located on the inner diameter side of the outer peripheral wall 14. The injection port 11 includes a fine particle generation unit 12. In the present modification, the fine particle generation unit 12 is provided at the tip of the second injection flow path 7. That is, the fine particle generation unit 12 is configured by setting the inner diameter of the axial hole portion 26 to, for example, 1.8 mm.

  FIG. 3 shows an aerosol injection device according to a second embodiment of the present invention. This aerosol injection device is different from the aerosol injection device according to the first embodiment in the form of the second injection flow path 17 and the fine particle generation unit 22.

  The 2nd injection channel 17 of a 2nd embodiment extends in the direction (horizontal direction) substantially orthogonal to injection channel 6, and the tip is an opening shape. The second injection flow path 17 has a constant inner diameter (for example, 0.9 mm), a first part 20 that forms a linear flow path, and a smaller diameter (for example, 0.8 mm) than the first part 20. It has the 2nd part 24 which comprises a linear flow path, and the 3rd part 25 which expands from the front-end | tip part of the 2nd part 24, and becomes bell shape.

  The aerosol injection device according to the second embodiment also includes the fine particle generation unit 22 at the injection port 21 (for example, the range A in FIG. 3) of the second injection flow path 17. In the present embodiment, the fine particle generation unit 22 includes the second part 24 and the third part 25 of the second injection flow path 17. That is, the pressure of the liquid introduced into the second injection flow path 17 is increased in the second part 24, and the amount of the propellant coming into contact with the air in the third part 25 can be increased. For this reason, vaporization can be accelerated | stimulated by the 2nd part 24 and the 3rd part 25, and the injection sound by the explosion which arises in that case can be 90 dB or more. In addition, resonance can be promoted by the third portion 25, and the fluid can be diffused in all directions, and sprayed in the form of a mist to increase the spray area.

  FIG. 4 shows an aerosol injection device according to a third embodiment of the present invention. This aerosol injection device is different from the aerosol injection device according to the first embodiment in the form of the second injection flow path 27 and the fine particle generation unit 32.

  The second injection flow path 27 of the third embodiment has a constant inner diameter and is a linear flow path. The inner diameter of the second injection flow path 27 is, for example, 2.1 mm.

  As shown in FIG. 4A, the aerosol injection device according to the third embodiment also includes a fine particle generation unit 32 at the injection port 31 of the second injection flow path 27. In the present embodiment, the fine particle generation unit 32 is configured by a film member that is stretched around the distal end edge of the second injection flow path 27. As shown in FIG. 4B, the film member has a large number of holes 40 formed throughout. Thereby, when the liquid introduced into the ejection port 31 is ejected, the liquid passes through the hole 40 and becomes fine particles, and is ejected in the form of a mist, so that the ejection area can be enlarged. At the same time, the injection sound generated by the explosion at the injection port 31 is resonated by the film member, so that the injection sound can be 90 dB or more.

The aerosol injection device of the present invention was actually manufactured, and an experiment was conducted to measure the magnitude of the injection sound generated during injection. The actual length dimension of the injection button was as shown in FIG. Samples A to I are manufactured as aerosol injection devices. Samples A to G have straight type injection flow paths, and the inner diameters of the injection ports are 0.7 mm, 1.0 mm, and 1 as shown in FIG. 2 mm, 1.6 mm, 1.8 mm, 2.4 mm, and 2.6 mm. Samples H and I have a so-called mechanical breakup type injection channel, and the inner diameter of the injection channel is 0.5 mm and 0.6 mm. Samples B, C, D, and E are examples, and samples A and F to I are comparative examples. The configuration other than the injection button is common to all samples. Specifically, the liquid ejected by the ejection device is 100 ml with a ratio of the liquid agent (Table 1) to be ejected to the ejected object and the liquid propellant (liquefied petroleum gas (LPG)) being 3: 7. The tin can was filled. A stem hole (not shown) that is opened when the spray button is pressed down has a hole diameter of 0.6 mm × 1, and the amount of liquid sprayed per second was 2.0 to 2.5 g. For Samples A to F, H, and I, the injection sound when injecting toward the inside of the shoe and the injection sound when injecting without an injection object were measured. For sample G, only the injection sound was measured when it was injected toward the inside of the shoe.

  Next, an experimental method will be described. A microphone of a sound level meter (manufactured by Sansho Co., Ltd .: Model STM-102) was set on the shoe mouth, and each injection device was arranged so that the distance between the injection port and the microphone was about 10 cm. In this state, the liquid was jetted for 2 seconds inside the shoe, and the maximum value of the jetting sound was measured. Even when there was no target to be ejected, the liquid was ejected for 2 seconds so that the distance between the ejection port and the microphone was about 10 cm, and the maximum value of the ejection sound was measured. The background volume was measured under a condition of 35 dB or less. FIG. 6 shows the result of measuring each sample 6 times and averaging them. In the graph of FIG. 6, “without hatching” indicates a case of spraying toward the inside of the shoe, and “with hatching” indicates a case of spraying without an injection target.

  As shown in FIG. 6, in the case of having a straight type injection flow path, the sample D (inner diameter 1.6 mm) is the peak and the inner diameter is the same regardless of whether it is injected toward the inside of the shoe or there is no injection target. The smaller the diameter is, the smaller the injection sound becomes, and the smaller the inner diameter becomes, the smaller the injection sound becomes, the smaller the angle becomes, the larger the angle becomes. Thereby, it is considered that the largest injection sound is obtained when the inner diameter is 1.0 mm to 2.0 mm.

  Even in the samples H and I having the mechanical breakup type injection flow path, it is considered that the same tendency as in the straight type is observed. That is, the injection sound is larger in the sample I (inner diameter 0.6 mm) than in the sample H (inner diameter 0.5 mm). Accordingly, it is considered that the same tendency as in the straight type is observed even in the mechanical breakup type, and it is considered that the magnitude of the injection sound becomes the largest when the inner diameter is set to 1.0 mm to 2.0 mm.

  Next, when comparing the case of injecting toward the inside of the shoe and the case of injecting without the injection target object, in all samples, the inner side of the shoe than the injection sound injected without the injection target object It can be seen that the injection sound injected toward is loud. In particular, the samples B, C, D, and E have an injection sound of 90 dB or more. This is considered to be because the sound generated from the injection port reflects and resonates in the closed space formed on the inner side of the shoe. In particular, in sample B (inner diameter 1.0 mm), the injection sound in the state where there is no injection target is 74.7 dB, and the injection sound injected into the shoe reaches 95.5 dB. In the sample C (inner diameter: 1.2 mm), the injection sound in a state where there is no injection target is 72.5 dB, and the injection sound injected into the shoe reaches 95.9 dB. That is, it was found that in the aerosol injection device configured as in the present invention, in order to effectively obtain an injection sound of 90 dB or more, it is particularly effective to inject inside the shoe.

  Next, the aerosol injection device of samples A to G, a device that rotates the roll to the application site and directly applies the liquid to the application site (hereinafter referred to as a roll), and a device that sprays the liquid in a mist form using a pump mechanism ( Hereafter, seven test subjects performed sensory evaluation on whether there was a difference in how the cooling effect was felt by the action of injecting liquid onto the injection target (shoes / clothing). Each subject uses each sample A to G, roll, and pump mist to actually inject or apply a fluid to the object to be injected, and then attach the object to be injected, and evaluate the cooling effect felt at that time. And scored up to 100 points. The higher the point, the higher the cooling effect.

  As shown in FIG. 7, the roll and the pump mist had a low cooling effect. On the other hand, samples B, C, D and E have a score of 80 or more. With the sample D (inner diameter of 1.6 mm) as a peak, the cooling effect feeling becomes smaller as the inner diameter becomes smaller than 1.6 mm, and the cooling effect feeling becomes smaller as the inner diameter becomes larger than 1.6 mm. . This tendency is consistent with the relationship between the magnitude of the injection sound and the inner diameter in FIG. Thereby, it turned out that a higher cooling effect feeling can be acquired, so that an injection sound is large. That is, the samples B, C, D, and E with a large injection sound can obtain the greatest cooling effect, and a larger injection sound can be obtained when the injection is performed on the inside of the shoe. When E is sprayed on the inside of the shoe, the highest cooling effect can be obtained.

Next, an experiment was conducted to confirm the dispersion state of the liquid ejected by the aerosol ejecting apparatus of the present invention. In addition to samples A to G, this experiment was also performed on sample J having an injection port inner diameter of 0.3 mm and sample K having an injection port inner diameter of 4.0 mm. As shown in FIG. 8, the experimental method is to place a Kim towel at a position about 30 cm away from the spray port, spray the liquid on the Kim towel for 0.5 seconds, spray area (the degree of spreading of the liquid), The concentration degree (particle size) was observed. The results are shown in Table 2.

  The liquids ejected from Samples A to E became clean particles, and the area on which the Kim Towel was wet was moderately wide and almost uniform throughout. Samples F and G are clean particles, but the particles are slightly large and the area on which the kim towel gets wet is moderately large but slightly concentrated in the center. Sample J did not become clean particles, the wetted area was narrow, and the liquid concentrated in the center. Sample K did not become clean particles, and the particle diameter of the mist was large. Therefore, the spray marks became a vertically long ellipse, and the liquid was concentrated in part. Accordingly, if the inner diameter size is too small (0.3 mm in this embodiment) or too large (4.0 mm in this embodiment), the particles are not clean and the injection area becomes narrow. Thereby, it became clear particle | grains and it turned out that the internal diameter range of the injection port which has a wide injection area is 0.7 mm-2.4 mm.

  From the above experiments, in order to set the injection sound to 90 dB or more when the background is 35 dB and to spray the liquid in the form of a mist, the inner diameter range of the injection port should be 1.0 mm to 2.0 mm. I understood.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to this, A various change is possible. The injection flow path may be a so-called mechanical breakup type instead of a straight type. Even the aerosol injection device of the second embodiment or the third embodiment can be a type of injection button that does not have an injection nozzle as in the modification of the first embodiment. The component of the liquid is not limited and may be one that does not contain a refreshing agent. The cross-sectional shape of the second injection channel is not limited to a circle, but may be various shapes such as an ellipse and a polygon, and the length may be various.

6, 7, 17, 27 Injection channel 11, 21, 31 Injection port 12, 22, 32 Particulate generating part D Inner diameter

Claims (6)

In an aerosol injection device for injecting a liquid containing a refreshing agent and a propellant enclosed therein via an injection flow path,
An aerosol injection device, comprising: an injection port of the injection flow path having a fine particle generation unit that makes an injection sound when a background is 35 dB be 90 dB or more and jets a liquid in a mist form.   The aerosol injection apparatus according to claim 1, wherein the fine particle generation unit is configured such that an inner diameter of the injection flow path is 1.0 mm to 2.0 mm.   The aerosol injection device according to claim 1, wherein the fine particle generation unit is configured such that an inner diameter of the injection flow path is 1.2 mm to 1.8 mm.   The aerosol injection device according to any one of claims 1 to 3, wherein the injection flow path is a straight type.   The aerosol spray device according to any one of claims 1 to 4, wherein the liquid is sprayed toward an inner side of a shoe.   The aerosol spray device according to any one of claims 1 to 5, wherein the propellant is liquefied petroleum gas or dimethyl ether.