JP2009106402A - Aroma source and aroma generator using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an aroma generator capable of stably generating aroma for a long period of time by providing a vent hole for accelerating the vaporization of aroma components present inside an aroma capsule, on the aroma capsule encapsulated by high polymer. <P>SOLUTION: By providing a single or a plurality of vent holes on the aroma capsule 6 formed from the high polymer, the aroma is stably generated for a long period of time. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a scent source for stably generating a plurality of types of scents for a long time, and an apparatus therefor.

  Conventionally, regarding a technique for generating a scent, various methods such as a method of vaporizing a liquid and a method of generating a droplet and vaporizing it have been proposed. On the other hand, in order to make the scent source easy to handle, it is composed of a solid scent source as described in Patent Document 1 and Patent Document 2, that is, a porous material and a liquid scent component adhering to the surface of the porous material. There are examples using a fragrance source, and a fragrance source comprising a solid or gel-like fragrance described in Patent Document 3, or a solid fragrance impregnated with a liquid fragrance. On the other hand, Patent Document 4 describes a cartridge method capable of easily exchanging a plurality of scent substances.

JP 2003-310740 A JP2003-343870 JP2004-121594A JP 2005-304609 A

Compared with a liquid scent source, the use of a solid scent source makes it very easy to handle such as no liquid leakage during transportation. However, as described in Patent Documents 1, 2, and 3, when a fragrance source is a material attached to the surface of a porous material or a solid material impregnated with a liquid fragrance, the fragrance component inside the material is vaporized. The speed is very slow compared to the vaporization rate of the scent component on the surface of the material.If all the scent sources on the surface of the material are evaporated, the supply of the scent is substantially stopped and the scent is stable for a long time. There is a disadvantage that it cannot be generated.
For this reason, in order to generate a scent for a long time, it is necessary to prepare a plurality or a large number of solid materials having the same scent component, and a large amount of space in the apparatus is used for one scent component. There was a need. Furthermore, the vaporization rate of the scent component on the surface of the solid material becomes sensitive to changes in the temperature of the scent generator itself that incorporates it, and it is difficult to finely control the amount of scent component generated. It was.

  In addition, as described in Patent Document 4, by replacing a plurality of scent components into cartridges, the scent components can be easily replaced, but it is determined by yourself when to replace the cartridge. There was a drawback of having to.

In order to solve the above problems, in the present invention, in order to encapsulate a liquid scent component in a polymer film and to promote the vaporization of the scent component enclosed therein, a single scent component vent hole is provided. Alternatively, a plurality of scent capsules are used. In order to process the air holes in the scent capsule itself, a polymer film that is easy to process is used as the material of the scent capsule.
Further, in order to generate a plurality of scent components, a scent generating apparatus including a cartridge in which a plurality of scent capsules are arranged is used. At this time, in order to clarify the replacement time of the scent capsule or the cartridge itself, the usage state of the scent capsule is measured and the cartridge replacement time is displayed. The usage status of the scent capsule is confirmed by counting the number of times the valve provided in a pair with the scent capsule is opened or closed, placing a semiconductor sensor near the scent capsule, and measuring its intensity change. On the other hand, by making the cartridge into a unit, even if the scent component to be generated increases, it can be easily added.

  Deliver fragrance capsules and compact multitude of scents that satisfy the requirements of being a solid material that has a vapor pressure equivalent to that of liquid scent components, maintains scent for a long time, and is easy to process and safe. A possible scent generator can be provided.

  In FIG. 1, the fragrance generator 1 which is the first Example is shown. The scent generating device 1 includes a scent generating unit 2, which includes a cylinder control circuit 3, a cylinder control circuit cable 4, a valve 5, a scent capsule 6, a scent capsule cartridge 7, a heater 8, The scent capsule cartridge support 9 is configured. The scent component generated in the scent capsule cartridge 7 is sent out of the apparatus from the blower outlet through the blower guide 11 by the blower fan 10. The scent capsule cartridge 7 is fixed in the casing of the scent generating device 1 by a scent capsule cartridge support 9. Further, the angle of the air outlet 12 with respect to the horizontal plane can be varied through the fragrance generating device support 13 by an angle varying lever 14 provided on the fragrance generating device base 15. This is because the position of the air outlet 12 is changed depending on the position of the person who smells the scent from the scent generator 1.

  FIG. 2 is a view of the scent generator 1 as seen from the front. The control of the valve 5 and the heater 8 is performed by the scent generator control unit 16 via the cylinder control circuit cable 4.

In FIG. 3, the detail of the fragrance generating part 2 is shown. In this example, a valve using an artificial muscle made of a shape memory alloy is used which contracts when the wire itself is energized and returns to its original state when the energization is stopped. When this valve 5 is opened, the scent component evaporated from the scent capsule 6 sealed in the scent capsule holding hole 35 comes out, and the wind from the blower fan 10 indicated by an arrow in FIG. Is sent out of the scent generator. Here, a fan is used to send out the scent component, but a pump such as a diaphragm pump can also be used.
This shape memory alloy will damage the material if energization is continued, so energization on / off control is required, but it is possible to hold the valve tip almost in place by energization on / off control, It has features such as quiet opening and closing, low power consumption by on / off control, and high minute movement. The artificial muscle 24 is supported by the artificial muscle guide 18 supported by the scent generating part column 7 and the scent generating part block 19 through the artificial muscle support 28 provided inside the cylinder 27. ing. With this structure, when the artificial muscle 24 is energized, the artificial muscle contracts and the valve tip 29 rises from the valve guide 22 to open the space above the scent capsule 6 present in the scent capsule cartridge 7. The scent component from 6 will leak out. At this time, it is preferable that the scent capsule 6 is fixed by a scent capsule presser 30 having a mesh-like structure so as not to roll out. In addition, since the artificial muscle 24 is energized, the portion in contact with this material needs to be an insulating material. Therefore, the artificial muscle guide 18, the cylinder 27, and the valve tip 29 shown in the figure are insulating materials such as a Vespel material, a PEEK material, and the like.

  On the other hand, when the energization of the artificial muscle 24 is stopped, the length of the artificial muscle 24 returns to the original, so that the valve tip 29 fits in the valve guide 22. In order to shorten the time constant when the valve is closed, it is important to provide a valve spring 25 between the artificial muscle guide 18 and the spring retainer 26 so as to push back the opened valve. In order to secure a driving distance of 5 mm at the valve tip 29, the total length of the artificial muscle 24 is set to about 100 mm in consideration of the expansion / contraction distance of the artificial muscle 24 being about 5%.

  In the scent capsule cartridge 7 in FIG. 3, the scent capsule 6 having a diameter of about 5 mm is disposed in nine cylindrical vertical holes having a diameter of 5 mm and a depth of 5 mm. The scent capsule cartridge 7 can be controlled from room temperature to about 100 ° C. via a heater cable 31 by a heater 8 such as a cartridge heater. In order to improve the contact between the surface of the scent capsule cartridge 7 and the valve guide 22, the surface of the scent capsule cartridge 7 is pressed against the surface of the valve guide 22 by the leaf springs 32a and 32b for the scent capsule cartridge. It is important to prevent the scent from escaping.

  The scent capsule 6 is prepared as a capsule having a diameter of about 5 mm with a polysaccharide or alginic acid, which is one of dietary fibers, using natural or synthetic fragrances, and the scent capsule 6 is manufactured by a submerged curing coating method. Specifically, it utilizes the fact that an aqueous sodium alginate solution enters into a potassium chloride solution and becomes a gel and solidifies in a jelly form. The scent component is flowed inside the double nozzle and the aqueous sodium alginate solution is flowed outside. A scent capsule is produced by dropping into a potassium chloride solution.

As shown in FIG. 4 (a), the appearance is spherical, and the color reflects the original color of the fragrance contained therein, resulting in a yellow or orange capsule. The polymer membrane material used for the scent capsule 6 needs to be considered for human safety, and as described above, it is preferable to use a safe material such as alginic acid, which is a polysaccharide and one of dietary fibers.
Further, when the capsule is cut, as shown in FIGS. 4B and 4C, a mononuclear structure having one fragrance nucleus or a multinuclear structure having a plurality of fragrances are formed. In addition, when the scent capsule 6 is used, as shown in FIG. 5, vent holes are provided so that the core scent component present therein is easily vaporized. When the vent hole of the scent capsule 6 is opened from the surface toward the center, when penetrating through the center from the surface, when providing a plurality of them, when opening a large number of vent holes radially from the surface, or combining them Thus, the vaporization of the scent component inside the scent capsule is promoted.

  5A is an external view of the scent capsule 6 in the case where one scent capsule 34 is provided in the scent capsule 6, and FIG. 5B is a cross-sectional view of the scent capsule 6. Has come to the center of the. FIG. 5C shows a case where the vent hole 34 b penetrates the scent capsule 6. FIG. 5D shows a case where the vent holes 34 c are provided radially with respect to the scent capsule 6. FIG. 5E shows a case in which the fragrance capsule 6 is provided with vent holes 34 d parallel to each other. Thus, various forms exist in the vent hole. The same vent can be provided even in the case of a polynuclear scent capsule.

  The usefulness of the vent is shown in FIGS. 6 shows the intensity change of the scent component from the scent capsule 6 when the vent hole is provided, and FIG. 7 shows the intensity change of the scent component from the scent capsule 6 when no vent hole is provided. The scent component signal is also detected by the semiconductor sensor. 6 and 7 show the case of a fragrance capsule made of alginic acid having a diameter of about 5 mm enclosing natural fragrance petitgrain and sage as fragrance components, but the same applies to other components. As shown in FIG. 7, when no vent hole is provided, the signal of the scent component decreases rapidly with time, and in the case of sage, it is almost zero in about 5 hours. This is because the vaporization rate of the scent component inside the scent capsule is very small compared to the vaporization rate of the scent component attached to the surface. This is because there is almost no vaporization. On the other hand, the result at the time of providing a vent hole in the scent capsule 6 is shown in FIG. At this time, a vent hole having a diameter of 0.5 mm is opened to the center of the scent capsule 6.

  As can be seen from this result, the signal of the scent component of the scent capsule 6 lasts for a long time as compared with the case where the vent hole of FIG. 7 is not provided, and the signal level in the first few hours is about double. You can see that In FIG. 6, the signal strength is high in the first stage because the fragrance components from the fragrance capsule surface and the fragrance capsule are vaporized together, and the fragrance component on the fragrance capsule surface disappears. After 4 hours, only the scent component is vaporized from the inside of the scent capsule, which is stable for at least 24 hours. From this result, it can be seen that it is useful to provide a vent hole in the scent capsule.

The range of the radius of the hole of one through hole can be determined as follows. For example, as shown in FIG. 8, the amount of scent generated from the scent capsule when the vent of radius r ₀ is provided through the center of the scent capsule is simply the inside of the exposed scent capsule. Therefore, it is expressed by the following equation using the radius r _{0 of the} passage hole.
I∝S = 4πr ₀ (R ² −r ₀ ² ) ^1/2
Where R is the radius of the scent capsule. For example, consider a scent capsule with R = 2.5mm.
I∝S = 4πr ₀ (2.5 ² −r ₀ ² ) ^1/2
It becomes. The relationship between S and r ₀ in this case shown in FIG. As can be seen from this result, the surface area is maximized when the radius is about 1.8 mm. From the viewpoint of maximizing the amount of scent generated from the scent capsule, It is desirable to do. On the other hand, it is not desirable to provide such a large passage hole in a scent capsule made of a polymer film such as alginic acid because the structure of the scent capsule becomes fragile, and judging from the actual processing state, the passage hole Should be kept below the value when the value of 4πr ₀ (R ² −r ₀ ² ) ^1/2 is maximum. Considering the current state of processing technology in which the minimum radius of a metal drill that can be used for a scent capsule such as a polymer membrane is about 0.015 mm, the radius of the passage hole is 0.015 mm to 4πr ₀ (R ² -r ₀ ² ) It is good to be between the values when the value of ^1/2 is maximized. The diffusion of the gas scent component molecules from the scent capsule is sufficient if the radius is 0.015 mm, and as can be seen from FIG. 8, changing the radius of the pass scent Since it corresponds to changing the generation amount, it is also possible to control the generation amount of the scent.

On the other hand, even when a plurality of vent holes are provided, the radius is almost the same, and the radius of one passage hole is larger than the value when the value of 4πr ₀ (R ² −r ₀ ² ) ^1/2 is maximum. However, it is important to limit the radius of the air hole so that the structure of the scent capsule can be maintained.

  FIG. 10 shows the result of actually setting a scent capsule provided with three types of vent holes, petit grain, peppermint, and sage, in a scent generator and measuring with a semiconductor sensor. In order to open the three valves, as shown in FIG. 9, about 8V is applied for 1 second and the energization pause for 1 second is repeated for each valve. During this time, the blower fan 10 is always operated with the same air volume, and the air volume can be varied by voltage control. The air volume is controlled in accordance with the conditions to be used, but in the case of the scent generating device as in the present invention, it is between 1 ml / sec and 1000 ml / sec. As described above, by using the scent capsule 6 with the valve 5 and the vent hole, it becomes easy to switch out a large number of scent components according to the desire of the user. In addition, there are graphs indicated by a solid line and a broken line in the figure, but the results of performing the same measurement three times are shown at the same time, and it can be seen that the present invention can stably generate different fragrances.

  FIG. 11 shows an example of the structure of the scent capsule cartridge 7. One of the problems when handling scented capsules is how to supply scented capsules. It is very important in industry to be able to stably store and supply fragrance components that are easily vaporized for a long period of time. In the scent capsule using the polymer membrane as in the present invention, a stable supply method of the scent capsule using the fact that the scent component inside the scent capsule has a low vaporization rate is possible. FIG. 11A shows a state in which a scent capsule lid 36 with a scent capsule holder 37 a with a drill is provided on the scent capsule cartridge 7. Immediately before using the scent capsule 6, the scent capsule holder 37 a with a drill is manually screwed to create a vent hole in the scent capsule holding hole 35, and then the scent capsule cartridge 7 is inserted into the scent generator 1. And start using the scent generator. As shown in FIG. 3, the scent capsule cartridge 7 can be easily mounted by sliding it between the valve guide 22 and the leaf springs 32a and 32b for the scent capsule cartridge. It is very important to work in a short time so as not to spread too much.

  On the other hand, there is a usage as shown in FIG. FIG. 12A shows a scent capsule cartridge 7 provided with a scent capsule lid 36 and scent capsule holders 37a and 37b with drills. In order to use the scent capsule 6 existing in the scent capsule holding hole 35 when supplied as the scent capsule cartridge 7 covered with the scent capsule lid 36, the following procedure is used.

  First, immediately before use, the scent capsule holders 37a and 37b with drills provided in the scent capsule cartridge 7 are manually screwed to provide a vent hole in the scent capsule 6 existing in the scent capsule holding hole 35. An example of the structure of the scent capsule cartridge 7 at this time is shown in FIG. 12B. By screwing a drill 38 attached to the tip of the scent capsule holders 37a and 37b with a drill as shown in FIG. The vent hole can be easily opened in the scent capsule 6 existing in the scent capsule holding hole 35. After opening the vent hole, the drill 38 is returned to the original position so that a fragrance is easily generated from the vent hole. Since the scent capsule is fixed by the scent capsule presser 30, this operation is possible. At this time, it is important from the viewpoint of effective use of space that the scent capsule holders 37a and 37b with drills can be operated from the side surface of the scent capsule cartridge 7 in correspondence with as many scent capsules as possible.

  FIG. 13 shows an arrangement example of the plurality of scent capsule holding holes 35. As shown in FIG. 13 (a), when the scent capsule holding holes 35 are arranged in a line on one side, the scent capsule holder 37a with a drill must be introduced from the side, so the scent capsule The holding holes 35 can be arranged only in two vertical rows. As shown in FIG. 13A, for example, when the scent capsule holding hole 35 having a diameter of 5 mm is arranged in a 30 mm square block as the scent capsule cartridge 7, a total of eight scent capsules are arranged in two rows of four vertically. Only the holding hole 35 can be provided. On the other hand, even if the blocks have the same size, if the scent capsule holding holes 35 are arranged by shifting the position from the side in the two outer rows and the two inner rows, a total of twelve scent capsule holding holes 35 are arranged in four vertical rows. Can be provided. Further, in the case as shown in FIG. 13 (a), when the number of scent capsules is to be increased, the longer the scent capsule cartridge 7, the more the number increases. Such a defect can be alleviated by adopting a structure such as 13 (b). In addition, when the scent cartridge 7 is not used, it is useful to screw the drills 38 at the tips of the scent capsules 37a and 37b with drills into the scent capsule again to suppress volatilization of the scent component from the scent capsule.

The actual size of the scent capsule cartridge 7 is designed as follows. When the diameter of the shaft portion of the drill 38 of the scent capsule holders 37a and 37b with a drill is R _C mm (several mm), and the number of the scent capsule holding holes 35 arranged vertically in the outer row and the inner row is N, the scent capsule cartridge Minimum vertical length required for the operation = N × L + (N−1) × R _C + 0.7L
It is expressed. Here, Lmm is the size of the portion of the valve collar 65 of the valve tip 29 necessary to close the scent capsule holding hole 35. For example, if a brim portion having a diameter of 7 mm is used to close a scent capsule holding hole having a diameter of 5 mm, L = 7 mm. As shown in FIG. 13C, 0.7L in the last term is a value considering the case where the valve tip including the collar part is inscribed. On the other hand,
Minimum lateral length required for scent capsule cartridge = 2L + 1.4L = 3.4L
It is expressed. From the minimum vertical length and the minimum horizontal length required for the scent capsule cartridge obtained here, the design is performed in consideration of the number (4N) of the required scent capsule holding holes.

  After the vent hole is opened in the scent capsule as described above, the scent capsule cartridge 7 is slid between the valve guide 22 and the leaf springs 32a and 32b for the scent capsule holding part as shown in FIG. Put it on.

  It is also possible to automate the driving of the scent capsule holders 37a and 37b with drills. As shown in FIG. 13, the drill 38 at the tip of the scent capsule holder 37a, 37b with drill is not manually rotated, but the drill 38 at the tip can be driven by a small stepping motor controlled by a PC. In this case, the following sequence can be considered. That is, when the scent generating device 1 is first started up, the scent capsule holders 37a and 37b with drills are rotated by the small stepping motor provided in the scent capsule cartridge 7, and all the scent capsules 6 are rotated. Vent holes are provided in Moreover, before stopping the scent generator 1, the drill 38 can be screwed into the scent capsule 6 again, and the sequence which suppresses volatilization of the scent component inside the scent capsule 6 can also be given. As another sequence, when the order of the scents to be generated is programmed, immediately before the time at which the scents are generated, the drill 38 is driven by a small stepping motor, and the target scent capsule 6 is vented. You may make it open and it opens a valve on it. Also at this time, after the generation of the scent, the drill 38 can be screwed into the scent capsule 6 again to have a sequence for suppressing volatilization of the scent component inside the scent capsule 6.

  Up to now, the case where only one valve is operated at the same time has been described, but it is naturally possible to operate a plurality of the valves simultaneously to mix the scents. At this time, when a valve using a shape memory alloy as described above is used, a current amount used to open two valves by constructing a sequence as shown in FIG. Can be suppressed. That is, energization is alternately performed between the valve 1 and the valve 2, and the amount of current to be used is suppressed to the same level as when one valve operates. This utilizes the fact that a valve using a shape memory alloy takes a long time to close the valve. The time required to open the valve is from several tens of milliseconds to several hundred milliseconds, and the time required to close the valve is 1 to 2 seconds. By alternately energizing, three or more valves are opened simultaneously. Needless to say, a plurality of valves can be driven simultaneously.

FIG. 15 shows changes in the signal intensity of the scent component depending on the temperature of the scent capsule 6. It can be seen that the signal rapidly increases as the temperature rises. In general, the saturated vapor pressure P of the liquid pure component is expressed as follows using the temperature T (absolute temperature K) by the equation of Antoine.
P = exp (A−B / (T + C))
Here, A, B, and C are component-specific constants. Assuming that the sensor signal intensity is proportional to the saturated vapor pressure and that AB / (T + C) can be approximated to αT + β (α and β are constants) in the narrow temperature range, the sensor signal strength I is I = γexp (αT)
And can be simply expressed as: At this time, γ is a constant. When actually applied to the result of FIG. 15 (fragrance component petit grain), as shown in the same figure, the signal intensity change obtained this time is I = 3 × 10 ⁻⁷ exp () with a high correlation coefficient of 0.97. 0.0619T)
It can be expressed as. This means that the amount of the scent component generated from the scent capsule 6 of the alginic acid membrane produced this time is approximately approximated by a function of the saturated vapor pressure of the solution. It is an important indicator. That is, the amount of scent components generated can be changed within a dynamic range of about one digit. The same can be said for other scent components, although the values of γ and α are different.

This result can also be used to estimate the lifetime of the scent capsule 6. For example, a fragrance capsule having a vent hole of 0.5 mm and a diameter of about 5 mm is set to one of the maximum use temperatures of the fragrance capsule, T ₀ (for example, 60 ° C.), and how long a fragrance does not occur is measured. To do. Since this time t _A is the time until the scent component disappears, it is a method for judging the life of the scent capsule based on how much relative use time it has become. For example, the time _{t 1} when the valve opens at a temperature _{T 1,} the time _{t 2} when the valve opens at a temperature _{T 2,} when driven at a temperature _{T 3} at time _{t 3} when the valve opens, the relative use time _{t R} is ,
t _R = (t ₁ / exp (α × (T ₁ −T ₀ ))
+ (T ₂ / exp (α × (T ₂ −T ₀ ))
+ (T ₃ / exp (α × (T ₃ −T ₀ ))
It becomes. Here, α is a constant determined by the scent. The relative lifetime _{L R} scented capsule _is represented by _{(t R / t A) ×} 100%. Thereby, by assembling an algorithm as shown in FIG. 16, it is possible to issue a warning message about the usage status and replacement time of the scent capsule. In this algorithm, _{L R} is 70%, or _{L R} is adapted to issue a warning when exceeding 90%. Since t _A varies depending on the type of scent and the state of the vent, a database of t _{A in} various states is created and the state of the scent capsule (scent type, vent hole In accordance with the state), the display result for _LR may be output based on the above-described calculation formula of (t _R / t _A ) × 100%.

On the other hand, it can also be estimated as follows. For example, for a scent capsule having a vent hole of 0.5 mm and a diameter of about 5 mm (a scent component amount of about 10 microliters), it is set at one of the maximum use temperatures of the scent capsule T ₀ (for example, 60 ° C.) The time t _{A at} which no scent is generated is measured. When the amount of vaporization V ₀ per unit time at this time is measured by gas chromatography, gas chromatography / mass spectrometry or the like, the total amount of vaporization V ₁ from the scent capsule is:
V ₁ = V ₀ × t _A
It becomes. Since V ₀ varies depending on the scent component and the state of the vent, it is preferable to accumulate the data in each state and create a database. Therefore, the time t ₁ when the valve opens at a temperature T _1, the time t ₂ when the valve opens at a temperature T _2, when driven at time t ₃ when the valve opens at a temperature T _3, the total amount of vaporization from the aroma capsules V ₂ is
_{V 2 = (V 0 × t1} × exp (α × (T 1 -T 0))
+ (V ₀ × t 2 × exp (α × (T ₂ −T ₀ ))
+ (V ₀ × t 3 × exp (α × (T ₃ −T ₀ ))
Can be estimated. Here, α is a constant determined by the scent. The relative lifetime _{L R} scented capsule _is represented by _{(V 2 / V 1) ×} 100%. Thereby, by assembling an algorithm as shown in FIG. 16, it is possible to issue a warning message about the usage status and replacement time of the scent capsule. In this algorithm, _{L R} is 70%, or _{L R} is adapted to issue a warning when exceeding 90%. Since V ₀ varies depending on the type of scent and the state of the vent, a database of t _{A in} various states is created, and the state of the scent capsule (scent type, vent hole In accordance with the state), the display result for _LR may be output based on the calculation formula of (V ₂ / V ₁ ) × 100% described above.

  It is also possible to grasp the replacement time by arranging a semiconductor sensor in the vicinity of the scent capsule and measuring the intensity change.

  FIG. 17 shows a case where there are a plurality of scent capsules and the temperatures are individually controlled. In order to individually control the temperature, it is useful to use the Peltier element 40. In this case, the scent capsule holding block 39 containing the scent capsule 6 keeps the heat transfer with the adjacent block low. It is necessary to sandwich the heat insulating material 41 therebetween.

  The temperature control of the scent capsule 6 has been described above, but it is also useful to control the temperature of the scent capsule cartridge 7 as a whole with a Peltier element. This is because the scent capsule cartridge 7 can be cooled to an appropriate temperature when the outside air temperature is high, and can be heated to an appropriate temperature when the outside air temperature is low. As a result, it can be used even in places where the temperature changes drastically, such as outdoors and in automobiles.

  It is also possible to expand the dynamic range of the scent intensity by combining the temperature control of the scent capsule and the simultaneous driving of a plurality of valves. For example, four scent capsules of the same type are put in, and the scent is generated almost simultaneously from the four scent capsules by the simultaneous driving sequence of the plural valves described above, and the strength of the scent is increased about four times. Is possible. By combining this with the temperature control of a scent capsule having a dynamic range of about an order of magnitude, a dynamic range with a scent intensity of 4 × 10 = 40 times can be ensured. That is, a dynamic range of about two digits with respect to the intensity of the scent can be realized by the present invention.

  As for the valve, the case of a valve using a shape memory alloy has been described. However, the essence of the present invention is a scent capsule made of a polymer film provided with a vent hole. As a scent generating device, a solenoid valve, a stepping motor Needless to say, other types of valves, such as the above-described valve, may be used.

  On the other hand, when the scent capsule cartridge 7 is unitized, even if the scent component to be generated is greatly increased, the scent capsule cartridge 7 can be easily added. When the structure shown in FIG. 3 is unitized, when nine scent capsules can be held in one scent capsule cartridge unit 42a, 42b, 42c, the types of scent capsules that can be stored are 9 × 3 in the case of FIG. = 27 can be easily added. This is a useful method considering the case where the original odor of the scent has not been determined and many scent components must be prepared in order to generate various scents.

Further, in the case where the scent component is originally a solid, the form of the scent capsule is not necessary. As shown in FIG. 19, a scent container 43 including a solid sample 44 and having a scent container vent 45 may be disposed in the scent capsule holding hole 35. At this time, the scent capsule 6 for the originally liquid scent component and the scent container 43 for the originally solid scent component coexist in the scent capsule cartridge 7.
In addition, the scent capsule is not limited to a spherical shape, and may be a three-dimensional shape such as a cylindrical shape or a prism shape.

  According to the present invention, it is possible to easily generate a plurality of scent components, and thus there are various applications. One of them is an electronic bulletin board 46 with a scent of a restaurant area in a station, department store, city, or the like.

  FIG. 20 shows an example. On the scented electronic bulletin board 46 at the store, the sound from the speakers 48 a and 48 b and the fragrance generating port 47 are displayed in accordance with the image of today's menu on a display 49 of a restaurant. Presenting the scent, helping customers to increase their appetite and increase sales. FIG. 21A shows an enlarged view of the scented electronic bulletin board 46. Here, the case of the scented bulletin board 46 for introducing a special menu in a certain restaurant will be described. When the push button 51 under the display 50 introducing today's special menu (for example, domestic high-quality beef steak) is pressed, the database (cooking images, cooking sounds, cooking fragrances) stored in the storage is displayed. Necessary information is read out from a set of data sets as one combination), and the image of the chef cooking domestic high-quality beef is displayed on the display 49, and at the same time it is called succulent when grilling meat Sound flows from the speakers 48a and 48b, and a fragrance when the meat is baked is generated from the fragrance generating port 47. As a result, the person standing in front of the bulletin board is stimulated not only by visual and auditory senses but also by olfaction, and the appetite for the presented menu increases.

  On the other hand, the scent generating port 47 needs to be devised for reliably sending the scent to the person standing in front of the scented electronic bulletin board 46. As shown in FIG. 21A, if only the flat scent generating port 47 is provided, it is necessary to bring the nose close to the scent generating port 47, making it difficult to see the image on the display. Therefore, as shown in FIG. 21 (b) or FIG. 21 (c), the half-scented scent guide 52 or the full-scented scent guide 53 is provided in the scent generating port 47 so that the scent can be surely smelled even from a position where the image is easy to see. It is effective to make it. Further, as shown in FIG. 22A, the panel 54 with speaker, the scent generating unit, and the panel 55 with speaker are folded with respect to the display 49 so that a person standing in front of the scented electronic bulletin board 46 can be used. On the other hand, sound and aroma may be easily delivered. In addition, a half-sided scent guide 52 and a full-sided scent guide 53 as shown in FIGS. 21 (b) and 21 (c) are provided on this, or in various directions as shown in FIG. 23 (b). It is also effective to provide a bellows-type scent guide 56 that can be bent.

  An example of the system configuration of the scented electronic bulletin board 46 based on the above is shown in FIG. When a command from the push button 51 is input, it is stored in the memory 60 through the CPU 57. The memory 60 has a program (display program on the display 49, an operation program of the speakers 48a and 48b, a scent providing program from the scent generating device 1) and data (in the example of the restaurant described above) necessary for processing the command. A data set including a combination of cooking video, sound during cooking, and aroma during cooking is read from the storage 61. The CPU 57 retrieves information from the memory 60 and processes the command (in the above restaurant example, the cooking video is displayed on the display 49 corresponding to the push button 51, and the cooking sound is provided from the speakers 48a and 48b. , Provision of fragrance during cooking from the fragrance generating device 1), and the result (video used, sound, number of pressed buttons for fragrance and time of pressing, etc.) are written in the memory. Thereafter, necessary information is written from the memory 60 to the storage 61. Further, since necessary information can be taken out via the network 62, maintenance including replacement of the scent capsule 6 of the scent generating device 1 in the scented electronic bulletin board 46 can be performed based on this information. it can. Furthermore, the information obtained by such a system can be used for marketing. This is because the number of push buttons 51 pressed according to the information on the display 50 indicates an interest in the display. In particular, information when the same push button 51 is continuously pressed is important, and is evidence that the display and information are very interesting.

  On the other hand, when the scent generating apparatus 1 according to the present invention is used, different scents can be easily produced, so that images of different menus can be continuously flowed and different sounds and scents can be presented accordingly. It is effective to switch the push-button mode in which the content of interest of the person is operated by the push button 51 after attracting the person by operating the scented electronic bulletin board 46 in such a continuous mode.

The present invention can also be applied to an automobile. One of them is a system that presents a scent to the driver and passengers in accordance with the information of the car navigation system that indicates where the driver is driving in conjunction with a car navigation system or a display in the backseat of a luxury car. When driving along the ocean, you can enjoy the scent of the tide, and when you drive through the grassland, you can enjoy the scent of flowers, so you can enjoy driving on the land even when the window is closed. it can. At that time, music may be played simultaneously. Specifically, a main menu called “fragrance” is provided in the menu of the display in the car navigation system or the backseat of a luxury car, and when this menu is turned on, the scent corresponding to the map information of the car navigation system is presented. That's it. However, since it is not realistic to mount a large amount of scent components in the car according to various landscapes, it is effective to prepare the following submenu according to the drive of the day. In the scent generating device 1 according to the present invention, the scent capsule cartridge 7 can easily change the set of scent capsules, which is possible.
(1) Main menu (mode to scent according to car navigation information)
(2) Sub-menu (1) (Urban driving mode (eg, calming scent set))
Submenu (2) (Forest zone operation mode (eg, setting the scent of forest)
Submenu (3) (grassland driving mode (eg, flower fragrance set))
Submenu (4) (Coastal zone operation mode (ex: sea scent set))
Submenu (5) (Favorite driving mode (example: set your favorite fragrance))
In accordance with this submenu, information on the driving location (city area, forest area, grassland area, coastal area, etc.) is extracted from the map information, and the submenu is activated. Further, as the number of sub-menus increases in this way, the number of the scent capsule cartridges 7 increases. Therefore, as shown in FIG. 25, the scent generating device 1 is preferably provided in the trunk of the car 64. From there, through the pipe 63, in the vicinity of the rear seat or the driver's seat (the headrest portion of the seat seat as shown in FIGS. 25 (a) and 25 (c), or the ceiling portion in the vehicle as shown in FIG. 25 (b)). A scent may be generated.

  It is also useful to simply change the scent in the vehicle at a constant cycle. This is because the olfactory cells present in the human nose tend to get tired, so if you smell the same scent for a long time, you will not feel the scent. Presenting a different scent of grapefruit, mandarin, orange, etc. to a driver or passenger who prefers a citrus scent at regular intervals will arouse the driver and passengers to drive and awaken the driver It is also useful from the viewpoint of calming the feelings of the driver and passengers even during traffic jams. In addition, in order to prevent a drowsy driving and aside driving during long driving, it is also possible to provide a system that periodically presents wakeful scents such as menthol to the driver to ensure vehicle safety Is important from the point of view.

  The present invention can also be applied to a product information display that places importance on fragrance. For example, in perfume, olfactory information of the scent itself is important, but it is also important to consider visual information such as what kind of clothes suits and what kind of place suits. In such a case, a product information display that considers the image of a perfume by showing the fragrance of the perfume gradually and strongly while watching a video of a woman walking here in a certain outfit is useful. Such a merchandise information display can be applied to cosmetics other than perfume, beverages such as coffee, food, spices, and the like.

  The present invention can be applied to a game full of realism. Until now, games have been created mainly with visual and auditory information, but by using the present invention, they will also have olfactory information and create new game genres such as games with scent cartridges. Is possible. For example, a person who has a scent generating device in addition to the game machine main body can enjoy a scent tailored to the game by purchasing a scent cartridge attached to a certain game. A wide variety of game contents such as cooking recipe game contents, world cooking game contents, coffee-scented game contents, wine-scented game contents, and forest bath game contents are possible.

  The present invention can also be applied in an office. It is said that grapefruit, peppermint and other fragrances are good for recovery from fatigue, but it is possible to increase work efficiency by regularly presenting them during work. For example, as a break of work for one hour, a system that generates and refreshes the fragrance that an individual likes, and a system that generates fragrance for recovery from fatigue during a long meeting are possible.

  The present invention is also applicable in the home. Individuals can enjoy multiple scents that they like, and can be used as a means of brain activation by presenting scents that are linked to the old videos and music to the elderly. .

  The scent generating device according to the present invention is an information field such as a scented display, a product guide display, an automobile field for realizing a comfortable drive space, an office field for improving work efficiency, a game field for realizing a game full of realism, A wide range of applications can be expected, such as the home field for creating comfortable spaces.

Sectional drawing of the fragrance generating apparatus of this invention. The external view of the fragrance generating apparatus of this invention. The valve figure of the fragrance generating apparatus of this invention. The scent capsule external view and sectional drawing of this invention. The external view and sectional drawing of the fragrance capsule with a vent hole of this invention. The time change of the discharge | release amount of the scent from the scent capsule which provided the vent hole of this invention. Change over time in the amount of scent released from scent capsules without vents. The relationship between the radius of the vent hole in the present invention and the exposed surface area inside the scent capsule. The valve control sequence of this invention. The example of discharge | release of the different fragrance by valve | bulb control in this invention. The figure of an example of the scent generator cartridge of the present invention. The figure of an example of the scent generator cartridge of the present invention. The figure of an example of the scent generator cartridge of the present invention. The sequence at the time of driving the several valve | bulb of the fragrance generating apparatus of this invention. The temperature change of the intensity | strength of the fragrance in the scent capsule of this invention. The cartridge replacement time display algorithm of the scent generator of the present invention. The figure of the individual temperature control of the fragrance generating apparatus of this invention. The figure of the scent capsule cartridge unit of this invention. The figure of the scent container for solid samples of the present invention. The figure of the electronic bulletin board with a fragrance of this invention. The figure of an example of the display of this invention. The figure of an example of the display of this invention. The figure of the fragrance guide of the display of this invention. The figure of the control part of this invention. The figure of the utilization in the motor vehicle of this invention.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Fragrance generating device, 2 ... Fragrance generating part, 3 ... Cylinder control circuit, 4 ... Cable for cylinder control circuit, 5 ... Valve, 6 ... Scent capsule, 7 ... Aroma capsule cartridge, 8 ... heater, 9 ... fragrance capsule cartridge support, 10 ... blower fan, 11 ... blower guide, 12 ... blower outlet, 13 ... fragrance generator support , 14... Angle changing lever, 15... Scent generating device stand, 16. Scent generating device control unit, 17. Scent generating unit support, 18.・ Scent generating part block, 20... Scent generating part blow guide, 21... Cylinder guide, 22 .. valve guide, 23 .. scent generating part support plate, 24.・ Valve springs, 26 ... Spring 27 ... cylinder, 28 ... artificial muscle support, 29 ... valve tip, 30 ... scent capsule presser, 31 ... heater cable, 32a, 32b ... scent capsule holding plate Spring, 33a, 33b ... scent component core, 34a, 34b, 34c ... scent capsule vent, 35 ... scent capsule holding hole, 36 ... scent capsule lid, 37a, 37b ... Scent capsule press with drill, 38 ... Drill, 39 ... Scent capsule holding block, 40 ... Peltier element, 41 ... Heat insulating material, 42a, 42b, 42c ... Scent capsule cartridge unit, 43 ... scented container, 44 ... solid sample, 45 ... vent hole for scented container, 46 ... scented electronic bulletin board, 47 ... fragrance generating port, 48a, 48b ..Speaker, 49... Display, 50... Display, 51... Push button, 52... Half-sided scent guide, 53. ... Panel with fragrance generating part and speaker, 56 ... Bellows scent guide, 57 ... CPU, 58 ... Bus, 59a, 59b ... Chipset, 60 ... Memory, 61 ... -Storage, 62 ... network, 63 ... fragrance piping, 64 ... car, 65 ... valve collar.

Claims (12)

A scent source that generates scents,
A holding unit for holding the scent source therein;
A valve that controls to open and close the flow path of the scent discharged from the holding unit;
A control unit for controlling the valve,
The scent source has a vent hole that exists from the surface of the scent source toward the center. In the scent generating device according to claim 1,
The scent source has a polymer film covering a scent component, and the polymer is generated from alginic acid. In the scent generation device according to claim 1 or 2,
A fragrance generating device characterized in that a diameter of a vent hole provided in the polymer portion is 10 micrometers or more. In the scent generating device according to claim 1,
A scent generating device comprising means for heating the scent source. In the scent generating device according to claim 1,
A scent generating apparatus having a blower mechanism for sending out scent components from the scent source. In the scent generating device according to claim 1,
A scent generating device characterized in that the angle of the scent component outlet from the scent source is variable. In the scent generating device according to claim 1,
The scent source is taken out by a scent capsule cartridge that holds a plurality of the scent sources. The scent generating device according to claim 7,
The scent capsule cartridge has a drill for opening a vent hole in the scent source. A scent source that generates scents,
An outlet for releasing the scent component released from the scent source to the outside;
A valve that controls to open and close the flow path of the scent discharged from the scent source;
Heating means for heating the scent source;
A blowing mechanism for sending out the scent component to the outside;
A control unit that controls at least opening and closing of the valve;
The scent source is a scent capsule covered with a polymer film and having a liquid scent component on the surface or inside of the film,
A plurality of the scent capsules are held, and a cartridge capable of taking out each scent source is provided,
A scent generating apparatus comprising a drill for opening a vent hole in the scent capsule. A scent capsule which is covered with a polymer film and has a liquid scent component on the surface or inside of the film, and has a vent hole existing from the surface toward the center. The scent capsule according to claim 10,
A scent capsule, wherein the polymer is produced from alginic acid. The scent capsule according to claim 10,
A scent capsule characterized in that the diameter of the air hole provided in the polymer portion is 10 microns or more.

Images