JP2023003375A - Fragrance device - Google Patents

Abstract

To provide a fragrance device that enables the volume of air passing through a second cartridge to be smaller than the volume of air passing through a first cartridge, thereby allowing the intensity of a fragrance sensed from the air having passed through the first and second cartridges to be an intended intensity.SOLUTION: A fragrance device 10 comprises: a first cartridge 13 that contains a first fragrance inside; a second cartridge 14 that contains a second fragrance inside; a housing 12 holding the first cartridge 13 and the second cartridge 14 in an interior space 123; and first to fourth doors 15-18 provided in the interior space 123. The interior space 123 is provided with a bypass channel 124 through which air flows bypassing the first cartridge 13 and the second cartridge 14. The first to fourth doors 15-18 switch between a first state in which air going from an inlet 121 of the housing 12 to an outlet 122 flows inside the first cartridge 13 and a second state in which the air flows inside the second cartridge 14 and through the bypass channel 124.SELECTED DRAWING: Figure 1

Description

The present invention relates to fragrance devices.

Patent Literature 1 discloses a fragrance device that blows air containing perfume. This prior art fragrance device contains two cartridges, a first cartridge and a second cartridge, inside a housing. The first cartridge contains a first perfume, which is a liquid perfume. The second cartridge contains a second perfume, which is a liquid perfume.

In this fragrance device, the air flowing in from the inlet of the housing passes through the first cartridge and flows toward the outlet of the housing, and the wind flowing in from the inlet of the housing passes through the second cartridge and flows toward the outlet of the housing. The flow is switched by the switching unit. As the air passes through each cartridge, the liquid fragrance volatilizes and the volatilized fragrance is carried in the air. The air containing fragrance is blown out from the outlet of the housing, reaches the person, and the person perceives the fragrance.

Japanese Patent No. 6211692

In the fragrance device configured as described above, in order to make the strength of the fragrance sensed from the wind that has passed through the first and second cartridges the desired strength, the volume of the wind that passes through the second cartridge is adjusted to the second level. It may be necessary to reduce the amount of air that passes through one cartridge.

One example is when the types of the first flavor and the second flavor are different, and the volatilization speed of the second flavor in the second cartridge is lower than the volatilization speed of the first flavor in the first cartridge. . In this case, the second perfume volatilizes more easily than the first perfume. Therefore, in order to make the intensity of the first and second fragrances nearly equal, the volume of air passing through the second cartridge may be made smaller than the volume of air passing through the first cartridge. is necessary.

Another example is a case where the types of the first fragrance and the second fragrance are different, and the threshold for the fragrance of the second fragrance is lower than the threshold for the fragrance of the first fragrance. The fragrance threshold is the concentration of the fragrance that allows the fragrance to be scented at an appropriate intensity. Even if the concentration of volatilized perfume in the air is the same, the strength of the scent perceived by humans differs depending on the type of perfume. In this case, the second fragrance is easier to smell than the first fragrance. Therefore, in order to make the intensity of the first and second fragrances nearly equal, the volume of air passing through the second cartridge may be made smaller than the volume of air passing through the first cartridge. is necessary.

Another example is a case where the types of the first fragrance and the second fragrance are the same, and the intensity of the fragrance of the second fragrance is desired to be weaker than that of the first fragrance. In this case, it is necessary to make the amount of air passing through the second cartridge smaller than the amount of air passing through the first cartridge.

However, in Patent Literature 1, when the airflow is switched by the switching unit, the air volume when the air passes through the second cartridge is made smaller than the air volume when the air passes through the first cartridge. Not listed. In the fragrance device of Patent Literature 1, the volume of air passing through each of the first and second cartridges is the same. For this reason, the strength of the scent sensed from the wind that has passed through one of the first and second cartridges can only be adjusted to the desired strength, and the strength of the scent that is sensed from the wind that has passed through the first and second cartridges can only be adjusted to the desired strength. It is not possible to make the strength of the scent to be the strength of the aim.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a fragrance device capable of adjusting the intensity of fragrance sensed from winds passing through the first and second cartridges to a desired intensity.

In order to achieve the above object, according to the invention of claim 1,
A fragrance device that blows air containing perfume,
a first cartridge (13, 42) containing a liquid first perfume therein;
a second cartridge (14, 43) containing a liquid second flavor therein;
It has an inlet (121, 411) through which the wind flows in and an outlet (122, 412) through which the wind flows out. The first cartridge and the second cartridge are held in the internal space in a state in which the headed wind can pass through the inside of each of the first cartridge and the second cartridge, and the wind directed from the inlet to the outlet is directed to the first cartridge and the second cartridge. a housing (12, 41) defining a bypass flow path (124, 415) in the interior space that flows around the cartridge;
A first state provided in the internal space, in which the air flowing from the inlet to the outlet flows through the inside of the first cartridge and does not flow through the inside of the second cartridge and the bypass channel, and the air flowing from the inlet to the outlet flows into the inside of the second cartridge. and a switching unit (15, 16, 17, 18, 45, 46, 48, 49, 50, 51) for switching between a second state in which the fluid flows through the bypass channel and a second state in which the fluid does not flow inside the first cartridge.

According to this, when the air flow is switched by the switching unit, the air volume when the air passes through the second cartridge can be made smaller than the air volume when the air passes through the first cartridge. For this reason, in order to set the strength of each of the first and second fragrances to the desired strength, the volume of air passing through the second cartridge is made smaller than the volume of air passing through the first cartridge. The strength of the scent sensed from the wind passing through each of the first and second cartridges can be the target strength, if desired.

It should be noted that the reference numerals in parentheses attached to each component etc. indicate an example of the correspondence relationship between the component etc. and specific components etc. described in the embodiments described later.

1 is a cross-sectional view of the fragrance device of the first embodiment; FIG. 1 is a cross-sectional view of part of the fragrance device of the first embodiment when air flow is in the first mode; FIG. Fig. 2 is a cross-sectional view of part of the fragrance device of the first embodiment when the airflow is in the second mode; FIG. 4 is a cross-sectional view of part of the fragrance device of Comparative Example 1 when the air flow is in the first mode; FIG. 5 is a cross-sectional view of part of the fragrance device of Comparative Example 1 when the air flow is in the second mode; Fig. 10 is a cross-sectional view of part of the fragrance device of the second embodiment when the air flow is in the first mode; FIG. 4 is a cross-sectional view of part of the fragrance device of the second embodiment when the air flow is in the second mode; FIG. 11 is a cross-sectional view of part of the fragrance device of the second embodiment when the air flow is in the third mode; FIG. 10 is a cross-sectional view of part of the fragrance device of the third embodiment when the airflow is in the first mode; FIG. 11 is a cross-sectional view of part of the fragrance device of the third embodiment when the air flow is in the second mode; FIG. 11 is a cross-sectional view of part of the fragrance device of the fourth embodiment when the air flow is in the second mode; FIG. 11 is a cross-sectional view of part of the fragrance device of the fifth embodiment when the airflow is in the second mode; FIG. 11 is a cross-sectional view of part of the fragrance device of the sixth embodiment when the air flow is in the second mode; FIG. 12 is a cross-sectional view of part of the fragrance device of the seventh embodiment when the air flow is in the second mode;

An embodiment of the present invention will be described below with reference to the drawings. In addition, in each of the following embodiments, portions that are the same or equivalent to each other will be described with the same reference numerals.

(First embodiment)
The fragrance device 10 of the present embodiment shown in FIG. 1 is mounted in a position in the passenger compartment of a passenger car in such a manner that a seated passenger cannot visually recognize it, in such a manner that the cartridge can be replaced. Positions that cannot be visually recognized by the occupant include the inside of the dashboard, the inside of the console, and the like. Note that the fragrance device 10 may be arranged at a position in the vehicle interior that can be visually recognized by a seated passenger. A vertical direction D1 and a horizontal direction D2 in FIG. 1 indicate directions when the fragrance device 10 is mounted on a vehicle. The vertical direction D1 corresponds to the first direction. The lateral direction D2 corresponds to the second direction.

As shown in FIG. 1, the fragrance device 10 includes a blower 11, a housing 12, a first cartridge 13, a second cartridge 14, a first door 15, a second door 16, a third door 17, A fourth door 18 is provided.

Air blower 11 is connected to housing 12 . The blower 11 sucks in the air in the vehicle interior and sends the air to the housing 12 . The blower 11 blows air by rotating an impeller.

Housing 12 has an inlet 121 and an outlet 122 . The inlet 121 is an opening through which the wind sent from the blower 11 flows. The outlet 122 is an opening through which air containing fragrance flows out of the housing 12 .

The outlet 122 communicates with the vehicle interior space. The wind that flows out from the outlet 122 is blown into the vehicle interior space and reaches the occupant in the vehicle interior. Alternatively, the outlet 122 is connected to a duct connected to an outlet such as a face outlet of an air conditioner (not shown). In this case, the air flowing out from the outlet 122 joins the conditioned air from the air conditioner and reaches the occupant from the air outlet provided in the passenger compartment.

An internal space 123 communicating with an inlet 121 and an outlet 122 is formed inside the housing 12 . The housing 12 holds the first cartridge 13 and the second cartridge 14 in the internal space 123 in such a manner that the air flowing from the inlet 121 to the outlet 122 can pass through the interiors of the first cartridge 13 and the second cartridge 14 . .

The housing 12 forms a bypass channel 124 in the interior space 123 . The bypass flow path 124 is a flow path through which air flowing from the inlet 121 to the outlet 122 bypasses the first cartridge 13 and the second cartridge 14 . The bypass channel 124 is arranged between the first cartridge 13 and the second cartridge 14 .

Specifically, the housing 12 has a first holding portion 21 . The first holding portion 21 holds the first cartridge 13 in a state in which air can pass through the first cartridge 13 . The first holding portion 21 includes a first holding portion inlet 211 communicating with the first inlet 13 a of the first cartridge 13 and a first holding portion outlet 212 communicating with the first outlet 13 b of the first cartridge 13 . The wind that has flowed into the first holding portion inlet 211 flows out from the first holding portion outlet 212 after passing through the first cartridge 13 .

The housing 12 has a second holding portion 22 . The second holding portion 22 holds the second cartridge 14 in a state in which air can pass through the second cartridge 14 . The second holding portion 22 includes a second holding portion inlet 221 communicating with the second inlet 14 a of the second cartridge 14 and a second holding portion outlet 222 communicating with the second outlet 14 b of the second cartridge 14 . The wind that has flowed into the second holding portion inlet 221 flows out from the second holding portion outlet 222 after passing through the second cartridge 14 .

The first holding portion 21 has a first wall 213 that covers the sides of the first cartridge 13 . The second holding portion 22 has a second wall 223 that covers the sides of the second cartridge 14 . A bypass channel 124 is formed between the first wall 213 and the second wall 223 .

The first cartridge 13 and the second cartridge 14 are replaceable parts for the housing 12 . The first cartridge 13 contains a liquid first perfume therein. The second cartridge 14 contains a liquid second perfume therein. The primary and secondary perfumes are cosmetic perfumes and are called fragrances.

The first cartridge 13 has a first container 131 and a first impregnating material 132 . The first container 131 has a first inlet 13a and a first outlet 13b. The first inlet 13a is an opening through which wind flows. The first outlet 13b is an opening for air to flow out. The first inlet 13a is provided on one end side in one direction. The first outlet 13b is provided on the other end side in one direction. In this embodiment, the first cartridge 13 is held by the housing 12 such that one direction coincides with the vertical direction D1, the first inlet 13a is on the upper side, and the first outlet 13b is on the lower side. Therefore, air can pass through the inside of the first cartridge 13 from top to bottom.

The first impregnating material 132 is arranged inside the first container 131 . The first impregnating material 132 is made of a material that can be impregnated with liquid, such as a porous body. The first impregnating material 132 is impregnated with the first fragrance. Thus, the first perfume is contained inside the first cartridge 13 while being impregnated with the first impregnating material 132 . As the wind passes through the inside of the first cartridge 13, the first perfume volatilizes.

The second cartridge 14 has a second container 141 and a second impregnating material 142 . The second container 141 has the same shape and size as the first container 131 and has a second inlet 14a and a second outlet 14b. The second impregnating material 142 is arranged inside the second container 141 . The second impregnant 142 is made of the same material as the first impregnator 132 and has the same shape and size. That is, the size of the second cartridge 14 is the same as the size of the first cartridge 13 . The second impregnating material 142 is impregnated with the second perfume. Thus, the second perfume is contained inside the second cartridge 14 in a state impregnated with the second impregnating material 142 . The second perfume volatilizes as the wind passes through the inside of the second cartridge 14 .

The kind of fragrance differs between the first fragrance and the second fragrance. The volatilization rate of the second fragrance is greater than the volatilization rate of the first fragrance. That is, the first perfume is less likely to volatilize than the second perfume. The second perfume is more volatile than the first perfume. Further, the first fragrance and the second fragrance have the same relationship between the concentration of the fragrance when the volatilized fragrance is carried in the wind and the intensity of the fragrance from the wind containing the fragrance. That is, the first fragrance and the second fragrance have the same intensity of fragrance when the concentrations of the fragrances are the same.

The inlet 121 of the housing 12 is provided on one side of the housing 12 in the lateral direction D2. The outlet 122 of the housing 12 is provided on the other side of the housing 12 in the lateral direction D2. The outlet 122 of the housing 12 is arranged below the inlet 121 of the housing 12 in the vertical direction D1. The first cartridge 13 , the second cartridge 14 and the bypass channel 124 are arranged at positions between the inlet 121 and the outlet 122 in the vertical direction D<b>1 in the internal space 123 of the housing 12 .

The first cartridge 13, the second cartridge 14 and the bypass channel 124 are arranged in the lateral direction D2. The first cartridge 13 is arranged on one side of the internal space 123 in the horizontal direction D2. The second cartridge 14 is arranged on the other side of the internal space 123 in the lateral direction D2. The bypass channel 124 is arranged between the first cartridge 13 and the second cartridge 14 in the lateral direction D2.

The first door 15, the second door 16, the third door 17, and the fourth door 18 switch the air flow in the internal space 123 of the housing 12 between the first mode air flow and the second mode air flow. Department.

The first door 15 is provided in the internal space 123 on the side of the first inlet 13 a of the first cartridge 13 . The first door 15 opens and closes the first entrance 13 a by opening and closing the first holding portion entrance 211 . Therefore, the first door 15 is a first entrance door that opens and closes the first entrance 13a.

The first door 15 communicates the upstream space 125 of both the bypass channel 124 and the second cartridge 14 with the inlet 121 of the housing 12 when the first inlet 13a is closed. The first door 15 does not allow the upstream space 125 of both the bypass channel 124 and the second cartridge 14 to communicate with the inlet 12 a of the housing 12 when the first inlet 13 a is opened.

The second door 16 is provided in the internal space 123 on the side of the first outlet 13b of the first cartridge 13 . The second door 16 opens and closes the first outlet 13 b by opening and closing the first holding section outlet 212 . Therefore, the second door 16 is a first exit door that opens and closes the first exit 13b.

A first door 15 opens a first entrance 13a and a second door 16 opens a first exit 13b. This allows air to pass through the inside of the first cartridge 13 . When the wind passes through the inside of the first cartridge 13, the first perfume volatilizes. On the other hand, the first door 15 closes the first entrance 13a and the second door 16 closes the first exit 13b. This prohibits air from passing through the inside of the first cartridge 13 . Therefore, volatilization of the first fragrance is suppressed.

The third door 17 is provided in the internal space 123 on the side of the second inlet 14 a of the second cartridge 14 . The third door 17 opens and closes the second entrance 14 a by opening and closing the second holding portion entrance 221 . Therefore, the third door 17 is a second entrance door that opens and closes the second entrance 14a.

The fourth door 18 is provided in the internal space 123 on the side of the second outlet 14b of the second cartridge 14 . The fourth door 18 opens and closes the second outlet 14 b by opening and closing the second holder outlet 222 . Therefore, the fourth door 18 is a second exit door that opens and closes the second exit 14b.

A third door 17 opens the second entrance 14a and a fourth door 18 opens the second exit 14b. This allows air to pass through the inside of the second cartridge 14 . When the wind passes through the inside of the second cartridge 14, the second perfume volatilizes. On the other hand, the third door 17 closes the second entrance 14a and the fourth door 18 closes the second exit 14b. This prohibits air from passing through the inside of the second cartridge 14 . Therefore, volatilization of the second perfume is suppressed.

The structures of the first door 15, the second door 16, the third door 17 and the fourth door 18 are common. Each door has a rotary shaft 23 , a door plate portion 24 and a seal portion 25 . The door plate portion 24 has a plate shape and rotates about the rotation shaft 23 . The rotating shaft 23 is provided on one end side of the door plate portion 24 .

The rotating shaft 23 of the first door 15 is arranged on the other side in the lateral direction D2 with respect to the first entrance 13a. The other side in the lateral direction D2 is the side away from the inlet 121 of the housing 12 . The rotating shaft 23 of the second door 16 is arranged on one side in the lateral direction D2 with respect to the first outlet 13b. One side in the lateral direction D2 is the side away from the outlet 122 of the housing 12 .

The rotation shaft 23 of the third door 17 is arranged on the other side in the lateral direction D2 with respect to the second entrance 14a. The rotation shaft 23 of the fourth door 18 is arranged on one side in the lateral direction D2 with respect to the second outlet 14b.

The seal portion 25 is a member for preventing leakage, and is provided on the door plate portion 24 so as to protrude from the door plate portion 24 . For example, when the first door 15 closes the first holding portion inlet 211, the first holding portion inlet 211 is airtightly closed by the seal portion 25 of the first door 15 coming into contact with the peripheral portion of the first holding portion inlet 211. escape.

The fragrance device 10 has a control board 30 . The housing 12 has an accommodating portion 31 for the control board 30 . The control board 30 is housed in the housing portion 31 . The control board 30 is a control unit that controls operations of the blower 11 , the first door 15 , the second door 16 , the third door 17 and the fourth door 18 . An operation unit (not shown) is operated by the passenger. The control board 30 controls the operation of the blower 11 and the doors 15 to 18 in accordance with the operation of the operating section.

The fragrance device 10 provides a fragrance according to the scene. The control board 30 controls each of the doors 15 to 15 so that the air flow in the internal space 123 of the housing 12 is in one of the first mode and the second mode, in order to provide the scent according to the scene. 18 actuation.

For example, the first mode is wind flow for providing the scent of the first fragrance suitable for when the passenger wants to relax. The second mode is wind flow for providing the scent of the second perfume suitable for when the passenger wants to concentrate.

A passenger operates the operation unit for relaxation. In response to this, the control board 30 operates the blower 11 and controls the open/closed states of the doors 15 to 18 so that the air flow in the internal space 123 is in the first mode. In the first mode, as shown in FIG. 2, the first door 15 and the second door 16 on the first cartridge 13 side are opened. The third door 17 and fourth door 18 on the second cartridge 14 side are closed.

As a result, in the first mode, as indicated by arrows in FIG. becomes the first state in which the current does not flow. When the wind passes through the inside of the first cartridge 13, the first fragrance volatilizes, and the volatilized first fragrance is included in the wind. The wind containing the first fragrance flows out from the outlet 122 of the housing 12 and reaches the passenger so that the passenger perceives the scent of the first fragrance.

In addition, the occupant operates the operation unit for concentration. In response to this, the control board 30 operates the blower 11 and controls the open/closed states of the doors 15 to 18 so that the air flow in the internal space 123 is in the second mode. In the second mode, as shown in FIG. 3, the first door 15 and the second door 16 on the side of the first cartridge 13 are closed. The third door 17 and fourth door 18 on the second cartridge 14 side are opened.

As a result, in the second mode, as indicated by arrows in FIG. It becomes the second state in which no flow occurs inside. When the wind passes through the inside of the second cartridge 14, the second perfume is volatilized and the volatilized second perfume is included in the wind. The wind containing the second fragrance that flows out from the second cartridge 14 and the unscented wind that flows out from the bypass channel 124 join together. The merged wind flows out from the outlet 122 of the housing 12 and reaches the passenger, so that the passenger perceives the scent of the second perfume.

Next, the effect of the fragrance device 10 of this embodiment will be described by comparing the fragrance device 10 of this embodiment with the fragrance device of Comparative Example 1. FIG. The fragrance device of Comparative Example 1 shown in FIGS. 4 and 5 is different from the fragrance device 10 of the present embodiment in that the internal space 123 of the housing 12 does not have the bypass channel 124 . Other configurations are the same as those of the fragrance device 10 of the present embodiment.

As indicated by the arrows in FIG. 4, the air flow in the first mode is the same as in this embodiment. As indicated by the arrows in FIG. 5, the air flow in the second mode differs from that in this embodiment. That is, all of the air entering from the inlet 121 of the housing 12 passes through the second cartridge 14 and flows out from the outlet 122 .

In the fragrance device of Comparative Example 1, when the amount of air flowing in from the inlet 121 of the housing 12 is constant and the airflow in the internal space 123 is switched between the first mode and the second mode, the second cartridge 14 The air volume passing through is the same as the air volume passing through the first cartridge 13 .

Here, similarly to the fragrance device 10 of the present embodiment, the volatilization speed of the second fragrance used in the fragrance device of Comparative Example 1 is higher than the volatilization speed of the first fragrance. Therefore, the volatilization amount of the second fragrance in the second mode is larger than the volatilization amount of the first fragrance in the first mode. Therefore, the concentration of the second fragrance contained in the wind is higher than the concentration of the first fragrance in the first mode. Therefore, the intensity of the fragrance of the second fragrance delivered to the occupant in the second mode is stronger than the intensity of the fragrance of the first fragrance in the first mode.

On the other hand, in the fragrance device 10 of this embodiment, the amount of air flowing in from the inlet 121 of the housing 12 is constant, and the airflow in the internal space 123 is switched between the first mode and the second mode. In the first mode, all of the air entering through the inlet 121 passes through the first cartridge 13 and exits through the outlet 122 . In the second mode, the air flowing in from the inlet 121 is divided into the second cartridge 14 and the bypass channel 124 and flows through each.

Therefore, the air volume passing through the second cartridge 14 in the second mode is smaller than the air volume passing through the first cartridge 13 in the first mode. As described above, according to the fragrance device 10 of the present embodiment, instead of changing the amount of air blown from the blower 11, the amount of air passing through the second cartridge 14 is controlled by the mechanical structure of the first cartridge 13. can be less than the air volume passing through the

As a result, the amount of volatilization of the second perfume in the second mode is suppressed to a smaller amount than in the fragrance device of Comparative Example 1. The concentration of the second perfume contained in the air passing from the second cartridge 14 is lower than that of the fragrance device of Comparative Example 1. Further, the air containing the second fragrance that has passed through the second cartridge 14 and the unscented air that has passed through the bypass channel 124 are mixed, so that the concentration of the second fragrance contained in the air flowing out from the outlet 122 is even lower.

As a result, according to the fragrance device 10 of the present embodiment, compared to the fragrance device of Comparative Example 1, the strength of the scent of the second perfume delivered to the passenger in the second mode is reduced to that of the first mode. It can approximate the intensity of the scent of the first perfume that is sometimes delivered to the occupants.

For example, the amount of air blown by the blower 11 is set so that the strength of the scent of the first perfume in the first cartridge 13 is the target strength. At this time, the flow passage cross-sectional area of the bypass flow passage 124 is set so that the air volume passing through the second cartridge 14 is an air flow volume for making the strength of the scent of the second perfume the target intensity. This makes it possible to equalize the strength of the fragrance. The fragrance of the first fragrance that is hard to volatilize and the fragrance of the second fragrance that is easy to volatilize can be delivered to the occupant with the same fragrance strength. In this way, the strength of the scent sensed from the wind that has passed through each of the first and second cartridges 13 and 14 can be made the target strength.

In the fragrance device 10 of the present embodiment, as the second fragrance, the volatilization speed of the second fragrance is higher than the volatilization speed of the first fragrance. However, not limited to this case, the volatilization rate of the first fragrance and the volatilization rate of the second fragrance are the same as the second fragrance, and the threshold value of the fragrance of the second fragrance is higher than the threshold value of the first fragrance. A lower one may be used. That is, as the second fragrance, a fragrance that is easier to smell than the first fragrance may be used. Also in this case, the same effects as in the present embodiment can be obtained.

Moreover, the same kind of fragrance as the first fragrance may be used as the second fragrance. In this case, the intensity of fragrance in the second mode can be weakened compared to that in the first mode.

Further, in the fragrance device of Comparative Example 1, the intensity of the fragrance of the second fragrance delivered to the passenger in the second mode is brought close to the intensity of the fragrance of the first fragrance delivered to the passenger in the first mode. For this reason, it is conceivable that the amount of air blown from the blower 11 in the second mode is made smaller than the amount of air blown from the blower 11 in the first mode. However, in this case, the amount of air flowing out from the outlet 122 in the second mode is smaller than the amount of air flowing out from the outlet 122 in the first mode. Therefore, when the mode is switched from the first mode to the second mode, the air volume flowing out from the outlet 122 changes. This change in the amount of air makes the passenger feel uncomfortable.

On the other hand, in the fragrance device 10 of the present embodiment, as described above, when the first mode is switched to the second mode, the amount of air blown from the blower 11 is not changed, but the air flow from the inlet 121 is changed. The blown air is divided into the second cartridge 14 and the bypass channel 124 and flows through each. For this reason, compared to the fragrance device of Comparative Example 1 in the above case, the air volume of the air flowing out from the outlet 122 in the second mode and the air volume of the air flowing out from the outlet 122 in the first mode are different. can reduce the difference. Therefore, it is possible to reduce the uncomfortable feeling of the passenger caused by the change in the air volume.

(Second embodiment)
As shown in FIG. 6, in the fragrance device 10 of this embodiment, a third cartridge 33, a fifth door 34 and a sixth door 35 are added to the fragrance device 10 of the first embodiment. The first cartridge 13, the second cartridge 14, and the third cartridge 33 are arranged in order from one side to the other side in the lateral direction D2.

The third cartridge 33 contains a third perfume. The volatilization rate increases in the order of the third fragrance, the second fragrance, and the first fragrance. That is, the 3rd fragrance, the 2nd fragrance, and the 1st fragrance tend to volatilize in this order.

The fifth door 34 is provided on the third inlet 33a side of the third cartridge 33 . The fifth door 34 opens and closes the third entrance 33a. The sixth door 35 is provided on the third outlet 33b side of the third cartridge 33 . The sixth door 35 opens and closes the third exit 33b. The structure of the fifth and sixth doors 34 and 35 is the same as that of the first door 15 .

In the fragrance device 10 of this embodiment, the bypass channel 124 of the first embodiment is the first bypass channel 124 . In the fragrance device 10 of this embodiment, a second bypass channel 126 is formed in addition to the first bypass channel 124 in the internal space 123 of the housing 12 . The second bypass channel 126 is arranged between the second cartridge 14 and the third cartridge 33 .

The first to sixth doors 15, 16, 17, 18, 34, 35 switch the air flow among the first mode, second mode, and third mode.

As shown in FIG. 6, in the first mode, the first door 15 opens the first entrance 13a. The first door 15 closes the flow path from the inlet 121 to the first bypass flow path 124 and the second bypass flow path 126 . The second door 16 opens the first exit 13b. A third door 17 closes the second entrance 14a. A fourth door 18 closes the second exit 14b. A fifth door 34 closes the third entrance 33a. A sixth door 35 closes the third exit 33b.

As a result, in the first mode, all of the air that has flowed in from the inlet 121 of the housing 12 flows out from the outlet 122 after passing through the first cartridge 13, as indicated by arrows in FIG. Thus, in the first mode, the air flowing from the inlet 121 of the housing 12 to the outlet 122 flows through the inside of the first cartridge 13, the inside of the second cartridge 14, the inside of the third cartridge 33, and the first bypass channel. 124 and the second bypass flow path 126 are in the first state.

As shown in FIG. 7, in the second mode, the first door 15 closes the first entrance 13a. A second door 16 closes the first exit 13b. The third door 17 opens the second entrance 14a. The third door 17 closes the passage of air from the inlet 121 of the housing 12 to the second bypass passage 126 . The fourth door 18 opens the second outlet 14 b and also opens a flow path for air to flow from the first bypass flow path 124 to the outlet 122 of the housing 12 . A fifth door 34 closes the third entrance 33a. A sixth door 35 closes the third exit 33b.

As a result, as indicated by the arrows in FIG. 7, the air flowing in from the inlet 121 is divided into the second cartridge 14 and the first bypass channel 124 and passes through each. The wind that has passed through the second cartridge 14 and the wind that has passed through the first bypass channel 124 merge. The merged wind flows out from the outlet 122 . Thus, in the second mode, the air flowing from the inlet 121 to the outlet 122 of the housing 12 flows through the inside of the second cartridge 14 and the first bypass passage 124, and also flows through the inside of the first cartridge 13 and the third cartridge 33. and second bypass channel 126 .

As shown in FIG. 8, in the third mode, the first door 15 closes the first entrance 13a. A second door 16 closes the first exit 13b. A third door 17 closes the second entrance 14a. A fourth door 18 closes the second exit 14b. The fifth door 34 opens the third entrance 33a. The sixth door 35 opens the third outlet 33 b and also opens a flow path for directing wind from the first bypass flow path 124 and the second bypass flow path 126 to the outlet 122 of the housing 12 .

As a result, as indicated by the arrows in FIG. 8, the air flowing in from the inlet 121 is divided into the third cartridge 33, the first bypass channel 124, and the second bypass channel 126, and passes through each of them. The wind that has passed through the third cartridge 33, the wind that has passed through the first bypass channel 124, and the wind that has passed through the second bypass channel 126 join together. The merged wind flows out from the outlet 122 . Thus, in the third mode, the air flowing from the inlet 121 of the housing 12 to the outlet 122 flows through the inside of the third cartridge 33, the first bypass channel 124 and the second bypass channel 126, and the first cartridge 13 and the inside of the second cartridge 14 .

According to this, the following effects are obtained in addition to the effects of the first embodiment. The amount of air passing through the third cartridge 33 in the third mode can be made smaller than the amount of air passing through the second cartridge 14 in the second mode. As a result, the strength of the scent of the third perfume delivered to the passenger in the third mode can be brought close to the strength of the scent in the first mode and the second mode. In this way, the strength of the scent of the third perfume sensed from the wind that has passed through the third cartridge 33 can be set to the desired strength. Note that the same effects as in the present embodiment can be obtained even when the fragrance is easy to smell in the order of the third fragrance, the second fragrance, and the first fragrance.

(Third Embodiment)
As shown in FIG. 9, the fragrance device 40 of the present embodiment differs from the fragrance device 10 of the first embodiment in the position of the entrance/exit of each cartridge and the air flow in the internal space of the housing. Specifically, the fragrance device 40 includes an air blower (not shown), a housing 41, a first cartridge 42, a second cartridge 43, a first door 45, a second door 46, a third door 48, a third It has 4 doors 49 , a fifth door 50 and a sixth door 51 .

Housing 41 has an inlet 411 and an outlet 412 . Inlet 411 and outlet 412 correspond to inlet 121 and outlet 122 of the first embodiment. An internal space 413 communicating with an inlet 411 and an outlet 412 is formed inside the housing 41 . The housing 41 holds the first cartridge 42 and the second cartridge 43 in the internal space 413 in such a manner that the air flowing from the inlet 411 to the outlet 412 can pass through the interiors of the first cartridge 42 and the second cartridge 43 . .

The inlet 411 is located on one side of the housing 41 in the lateral direction D2. The outlet 412 is located on the other side of the housing 41 in the lateral direction D2. The inlet 411 and the outlet 412 are positioned on the same upper side in the vertical direction D1. In the internal space 413 , a straight air flow path 414 is formed that connects the inlet 411 and the outlet 412 in a straight line.

A first holding portion 44 and a second holding portion 47 are formed below the linear flow path 414 in the internal space 413 . The first cartridge 42 is arranged in the internal space of the first holding portion 44 . The first holding portion 44 is arranged on one side of the housing 41 in the lateral direction D2. The first holding portion 44 has a first communication port 441 and a second communication port 442 on the upper side of the first holding portion 44 . The first communication port 441 and the second communication port 442 communicate between the linear flow path 414 and the internal space of the first holding portion 44 .

Unlike the first cartridge 13 of the first embodiment, the first cartridge 42 has one inlet/outlet 42a on the upper side of the first cartridge 42 . The inlet/outlet 42 a of the first cartridge 42 communicates with the first communication port 441 and the second communication port 442 . Other configurations of the first cartridge 42 are the same as those of the first cartridge 13 of the first embodiment. In this manner, the first holding portion 44 holds the first cartridge 42 in a state in which the air flowing from the inlet 411 to the outlet 412 can pass through the inside of the first cartridge 42 .

A second cartridge 43 is arranged in the internal space of the second holding portion 47 . The second holding portion 47 is arranged on the other side of the housing 41 in the lateral direction D2 relative to the first holding portion 44 . The second holding portion 47 has a third communication port 471 and a fourth communication port 472 on the upper side of the second holding portion 47 . The third communication port 471 and the fourth communication port 472 allow communication between the linear flow path 414 and the internal space of the second holding portion 47 .

Unlike the second cartridge 14 of the first embodiment, the second cartridge 43 has one inlet/outlet 43a on the upper side of the second cartridge 43 . The inlet/outlet 43 a of the second cartridge 43 communicates with the third communication port 471 and the fourth communication port 472 . Other configurations of the second cartridge 43 are the same as those of the second cartridge 14 of the first embodiment. In this manner, the second holding portion 47 holds the second cartridge 43 in such a manner that the air flowing from the inlet 411 to the outlet 412 can pass through the inside of the second cartridge 43 .

A bypass channel 415 is formed below the straight channel 414 in the internal space 413 . The bypass channel 415 corresponds to the bypass channel 124 of the first embodiment. The bypass channel 415 is arranged around the second holding portion 47 . A portion of the bypass channel 415 is arranged between the first holding portion 44 and the second holding portion 47 , that is, between the first cartridge 42 and the second cartridge 43 .

An inlet 416 of the bypass channel 415 communicates with a portion of the straight channel 414 between the first holding portion 44 and the second holding portion 47 . An outlet 417 of the bypass channel 415 communicates with a portion of the linear channel 414 closer to the outlet 412 of the housing 41 than the second holding portion 47 .

The first door 45, the second door 46, the third door 48, the fourth door 49, the fifth door 50 and the sixth door 51 allow the airflow in the internal space 413 of the housing 41 to It is a switching unit for switching to the second mode of air flow. The first door 45 opens and closes the first communication port 441 . The second door 46 opens and closes the second communication port 442 . The third door 48 opens and closes the third communication port 471 . The fourth door 49 opens and closes the fourth communication port 472 . The fifth door 50 opens and closes the entrance 416 of the bypass channel 415 . The sixth door 51 opens and closes the outlet 417 of the bypass channel 415 . The third door 48, fourth door 49, fifth door 50 and sixth door 51 are configured to be interlocked.

As shown in FIG. 9, the first door 45 and the second door 46 open the first communication port 441 and the second communication port 442 in the first mode. The third door 48 and the fourth door 49 close the third communication port 471 and the fourth communication port 472, respectively. Fifth door 50 and sixth door 51 close inlet 416 and outlet 417 of bypass channel 415 .

As a result, as indicated by arrows in FIG. 9, all of the air that has flowed in from the inlet 411 of the housing 41 passes through the inside of the first cartridge 42 in a U-shape, and then flows out from the outlet 412 of the housing 41 . In this way, in the first mode, the first state is achieved in which the air flowing from the inlet 411 to the outlet 412 of the housing 41 flows through the inside of the first cartridge 42 and does not flow through the inside of the second cartridge 43 and the bypass flow path 415. .

As shown in FIG. 10, the first door 45 and the second door 46 close the first communication port 441 and the second communication port 442 in the second mode. Third door 48 and fourth door 49 open third communication port 471 and fourth communication port 472 . Fifth door 50 and sixth door 51 open inlet 416 and outlet 417 of bypass channel 415 .

As a result, as indicated by the arrows in FIG. 10, the air flowing in from the inlet 411 of the housing 41 is divided into the second cartridge 43 and the bypass channel 415 and passes through them. The wind that has passed through the second cartridge 43 in a U-shape and the wind that has passed through the bypass channel 415 merge. The merged wind flows out from the outlet 412 of the housing 41 . Thus, in the second mode, the air flowing from the inlet 411 of the housing 41 to the outlet 412 flows through the inside of the second cartridge 43 and the bypass channel 415, and the second state does not flow through the inside of the first cartridge 42. Become.

As described above, also in this embodiment, the air flow in the internal space 413 of the housing 41 is switched between the first mode air flow and the second mode air flow, as in the first embodiment. Therefore, the same effects as those of the first embodiment can be obtained in this embodiment as well.

In this embodiment, entrances 42a and 43a are formed in upper portions of the first and second cartridges 42 and 43, respectively. However, separate inlets and outlets may be formed on the same side of the first and second cartridges 42 , 43 .

(Fourth embodiment)
As shown in FIG. 11, in the fragrance device 10 of this embodiment, the structure of the second cartridge 14 is different from that of the fragrance device 10 of the first embodiment. Other configurations of the fragrance device 10 are the same as those of the first embodiment.

The second cartridge 14 has a first porous body 143 and a second porous body 144 in addition to the second container 141 and the second impregnating material 142 . The first porous body 143 is provided inside the second container 141 closer to the second inlet 14 a than the second impregnating material 142 . The second porous body 144 is provided inside the second container 141 closer to the second outlet 14b than the second impregnating material 142 is. The first porous body 143 and the second porous body 144 are porous bodies having a plurality of holes through which air can pass. The first porous body 143 and the second porous body 144 are members different from the second impregnating material 142 and have higher airflow resistance than the second impregnating material 142 . As the first porous body 143 and the second porous body 144, nonwoven fabric, mesh, or the like is used.

Thus, porous bodies 143 and 144 are provided at the second inlet 14a and the second outlet 14b of the second cartridge 14, respectively. On the other hand, the porous bodies 143 and 144 are not provided at the first inlet 13a and the air outlet 1bb of the first cartridge 13 . For this reason, the second cartridge 14 has a structure in which pressure loss is higher than that of the first cartridge 13 when air passes through the inside thereof.

As a result, compared to the first embodiment in which the pressure loss of the second cartridge 14 is the same as the pressure loss of the first cartridge 13, the air volume of the air passing through the inside of the second cartridge 14 in the second mode is reduced. becomes less. The volatilization amount of the second perfume is reduced. In addition to this, the amount of wind passing through the bypass flow path 124 increases. As a result, the concentration of the second fragrance in the air flowing out of the outlet 122 of the housing 12 is reduced. Therefore, compared to the first embodiment, it is possible to make it difficult for the second perfume to smell from the wind flowing out from the outlet 122 in the second mode.

In this embodiment, it is necessary to make it difficult to smell the second perfume in order to make the strength of the second perfume smelled from the wind flowing out from the outlet 122 in the second mode to the target strength. effective when In this embodiment, the second inlet 14a and the second outlet 14b of the second cartridge 14 are provided with porous bodies 143 and 144, respectively. However, only one of the second inlet 14a and the second outlet 14b of the second cartridge 14 may be provided with the porous body.

Further, in the fragrance device of Comparative Example 1 shown in FIG. A structure may be considered. In this case, the number of revolutions of the fan in the second mode is the same as the number of revolutions of the fan in the first mode. In this case, when the first mode is switched to the second mode, the air volume flowing out from the outlet 122 in the second mode is smaller than the air volume flowing out from the outlet 122 in the first mode. Become. This change in the amount of air makes the passenger feel uncomfortable.

On the other hand, in the fragrance device 10 of the present embodiment, when the mode is switched from the first mode to the second mode, the air flowing in from the inlet 121 is divided into the second cartridge 14 and the bypass channel 124, and flowing. For this reason, compared to the fragrance device of Comparative Example 1 in the above case, the air volume of the air flowing out from the outlet 122 in the second mode and the air volume of the air flowing out from the outlet 122 in the first mode are different. can reduce the difference. Therefore, it is possible to reduce the uncomfortable feeling of the passenger caused by the change in the air volume.

(Fifth embodiment)
As shown in FIG. 12, in the fragrance device 10 of this embodiment, the structure of the second cartridge 14 is different from that of the fragrance device 10 of the first embodiment. Other configurations of the fragrance device 10 are the same as those of the first embodiment.

In this embodiment, the opening area of the second inlet 14 a of the second cartridge 14 is smaller than the opening area of the first inlet 13 a of the first cartridge 13 . The opening area of the second outlet 14 b of the second cartridge 14 is smaller than the opening area of the first outlet 13 b of the first cartridge 13 . The opening area of the second inlet 14a and the opening area of the second outlet 14b are the same, but may be different.

Thus, the second inlet 14a and second outlet 14b of the second cartridge 14 have smaller opening areas than the first inlet 13a and air outlet 1bb of the first cartridge 13 . For this reason, the second cartridge 14 has a structure in which pressure loss is higher than that of the first cartridge 13 when air passes through the inside thereof. Therefore, the same effects as those of the fourth embodiment can be obtained by this embodiment as well.

(Sixth embodiment)
As shown in FIG. 13 , the fragrance device 10 of the present embodiment is characterized in that the second cartridge 14 is smaller than the first cartridge 13 and that the bypass channel 124 is separated from the outer wall of the first cartridge 13 and the outer wall of the second cartridge 14 . It differs from the fragrance device 10 of the first embodiment in that it is formed by Other configurations of the fragrance device 10 are the same as those of the first embodiment.

The first cartridge 13 and the second cartridge 14 are arranged side by side in the lateral direction D2 as one direction. The shape of the first cartridge 13 is the same as that of the first embodiment. The shape of the second cartridge 14 is the same as in the first embodiment. The width of the second cartridge 14 in the lateral direction D2 is smaller than the width of the first cartridge 13 in the lateral direction D2. The opening areas of the second inlet 14a and the second outlet 14b are the same as the opening areas of the first inlet 13a and the first outlet 13b, or smaller than the opening areas of the first inlet 13a and the first outlet 13b.

The bypass channel 124 is a space sandwiched between the outer wall of the first cartridge 13 and the outer wall of the second cartridge 14 in the lateral direction D2. Each of the first cartridge 13 and the second cartridge 14 is held by the housing 12 except for the wall forming the bypass channel 124 .

Here, the fragrance device 10 of this embodiment and the fragrance device of Comparative Example 2 are compared. Although the fragrance device of Comparative Example 2 is not shown, the size of the inside of the housing 12 is the same as that of the fragrance device 10 of the present embodiment, and the size of the first cartridge 13 is the same as that of the fragrance device 10 of the present embodiment. , and the size of the second cartridge 14 is the same as that of the first cartridge 13 . Other configurations are the same as those of the fragrance device 10 of the present embodiment.

According to the fragrance device 10 of the present embodiment, compared to the fragrance device of Comparative Example 2, the width of the second cartridge 14 in the lateral direction D2 is smaller than the width of the first cartridge 13 in the lateral direction D2. , the width of the bypass channel 124 in the lateral direction D2 is increased. Therefore, compared to the fragrance device of Comparative Example 2, the amount of wind passing through the bypass flow path 124 in the second mode is increased. As a result, the concentration of the second perfume in the air flowing out from the outlet 122 of the housing 12 can be made smaller. It is possible to make it difficult for the second perfume to smell from the wind flowing out from the outlet 122 in the second mode.

In this embodiment, as in the fourth embodiment, the second fragrance is used to make the intensity of the second fragrance emitted from the wind flowing out of the outlet 122 in the second mode the target intensity. It is effective when it is necessary to make it difficult to

(Seventh embodiment)
As shown in FIG. 14, in the fragrance device 10 of the present embodiment, the degree of opening of the third door 17 and the fourth door 18 in the second mode is the same as that of the first door 15 in the first mode. It is smaller than the respective opening degrees with the second door 16 . Other configurations of the fragrance device 10 are the same as those of the first embodiment.

For example, the degree of opening of the third door 17 and the degree of opening of the fourth door 18 in the second mode are the same. The opening degree of the first door 15 and the opening degree of the second door 16 in the first mode are the same. Alternatively, the degree of opening of the third door 17 and the degree of opening of the fourth door 18 in the second mode are different. The degree of opening of the first door 15 and the degree of opening of the second door 16 in the first mode are different. In this case, the degree of opening of the third door 17 and the degree of opening of the fourth door 18 in the second mode are the degree of opening of the first door 15 and the degree of opening of the second door 16 in the first mode, respectively. is smaller than the opening of either

According to this, the degree of opening of each of the third door 17 and the fourth door 18 in the second mode is the same as the degree of opening of each of the first door 15 and the second door 16 in the first mode. Compared to the same case, the amount of wind passing through the second cartridge 14 in the second mode is small. Therefore, the volatilization amount of the second fragrance is suppressed. As a result, the concentration of the second fragrance in the air flowing out from the outlet 122 of the housing 12 can be made smaller. It is possible to make it difficult for the second perfume to smell from the wind flowing out from the outlet 122 in the second mode.

In this embodiment, as in the fourth embodiment, the second fragrance is used to make the intensity of the second fragrance emitted from the wind flowing out of the outlet 122 in the second mode the target intensity. It is effective when it is necessary to make it difficult to

By the way, in the fragrance device of Comparative Example 1 shown in FIG. A case where the opening degree of each of the first door 15 and the second door 16 is made smaller is conceivable. Also in this case, the number of revolutions of the fan in the second mode is the same as the number of revolutions of the fan in the first mode.

However, in the fragrance device of Comparative Example 1, when the degree of opening of the door is made smaller in the second mode than in the first mode, the sound caused by the wind flow becomes louder than in the first mode. On the other hand, in the fragrance device 10 of the present embodiment, the wind flowing in from the inlet 121 flows through the bypass channel 124 in the second mode. Therefore, even if the degree of opening of the door is small in the second mode, it is possible to suppress the increase in noise caused by the wind flow.

In addition, in the fragrance device of Comparative Example 1 in the above case, the air volume flowing out from the outlet 122 in the second mode is smaller than the air volume flowing out from the outlet 122 in the first mode. Therefore, when the mode is switched from the first mode to the second mode, the air volume flowing out from the outlet 122 changes. This change in the amount of air makes the passenger feel uncomfortable.

On the other hand, in the fragrance device 10 of the present embodiment, when the mode is switched from the first mode to the second mode, the air flowing in from the inlet 121 is divided into the second cartridge 14 and the bypass channel 124, and flowing. For this reason, compared to the fragrance device of Comparative Example 1 in the above case, the air volume of the air flowing out from the outlet 122 in the second mode and the air volume of the air flowing out from the outlet 122 in the first mode are different. can reduce the difference. Therefore, it is possible to reduce the uncomfortable feeling of the passenger caused by the change in the air volume.

(Other embodiments)
(1) In the fragrance device of the fourth embodiment shown in FIG. 11, the second cartridge 14 is provided with a porous body separate from the second impregnating material. Further, in the fragrance device of the fifth embodiment shown in FIG. 12, the second inlet 14a and the second outlet 14b of the second cartridge 14 have smaller opening areas than the first inlet 13a and the air outlet 1bb of the first cartridge 13. . As a result, the second cartridge 14 has a structure with a higher pressure loss than the first cartridge 13 when air passes through the inside thereof.

However, by other means, the second cartridge 14 may be structured to have a higher pressure loss than the first cartridge 13 when wind passes through it. As another means, for example, when each of the first impregnating material 132 and the second impregnating material 142 is composed of a plurality of grains, the size of each grain of the second impregnating material 142 is the same as that of the first impregnating material. It may be made smaller than the size of each grain of the material 132 . As a result, compared to the first impregnating material 132, the gaps between the grains of the second impregnating material 142 become smaller, and the ventilation resistance inside the second cartridge 14 becomes greater.

As another example, only the second cartridge 14 of the first cartridge 13 and the second cartridge 14 may be partitioned into a labyrinth-like internal space of the second container 141 by a partition. By forming a labyrinthine flow path inside the second cartridge 14 , the air does not flow straight through the second cartridge 14 , but the air flows while bending multiple times. According to this, the flow path through which the wind flows becomes longer. The channel inside the second cartridge 14 is narrowed by the labyrinth-like partitioning. As a result, the pressure loss when air passes through the inside of the second cartridge 14 is higher than that of the first cartridge 13 .

(2) The fragrance device 10 of the fourth to seventh embodiments has a mechanical structure that makes it difficult to smell the second perfume when in the second mode compared to the fragrance device 10 of the first embodiment. are doing. However, in the fragrance device 10 of the first embodiment, the amount of air flowing from the blower 11 into the inlet 121 of the housing 12 in the second mode is less than the amount of air flowing from the blower 11 into the inlet 121 of the housing 12 in the first mode. It may be less than the air volume of the wind that blows. That is, the number of revolutions of fan 11 in the second mode may be made smaller than the number of revolutions of fan 11 in the first mode. This also reduces the volatilization amount of the second fragrance. Therefore, the concentration of the second perfume in the air flowing out from the outlet 122 of the housing 12 can be made smaller. Therefore, it is possible to make it difficult for the second perfume to smell from the wind flowing out from the outlet 122 in the second mode.

(3) In the fragrance device 10 of the first embodiment, the inlet 121 is provided in the housing 12 on one side in the lateral direction D2. The outlet 122 of the housing 12 is provided on the other side of the housing 12 in the lateral direction D2. However, the inlet 121 to the housing 12 may be provided at an upper portion of the housing 12 . The outlet 122 of the housing 12 may be provided in the lower portion of the housing 12 . In this case, the wind passing through the inlet 121 flows in the vertical direction D1. The wind passing through the outlet 122 flows in the vertical direction D1. The wind passing through each of the first cartridge 13, the second cartridge 14, and the bypass channel 124 flows in the vertical direction D1. Thus, the wind passing through each of inlet 121, outlet 122, first cartridge 13, second cartridge 14, and bypass channel 124 may be in the same direction.

(4) The fragrance devices 10 and 40 of each of the embodiments described above are mounted on a vehicle with the first direction D1 as the vertical direction and the second direction D2 as the horizontal direction. However, the fragrance devices 10, 40 of the embodiments described above may be mounted on the vehicle in other orientations.

(5) The present invention is not limited to the above-described embodiments, but can be modified as appropriate within the scope of the claims, including various modifications and modifications within the equivalent range. Moreover, the above-described embodiments are not unrelated to each other, and can be appropriately combined unless the combination is clearly impossible. Further, in each of the above-described embodiments, it goes without saying that the elements constituting the embodiment are not necessarily essential, unless it is explicitly stated that they are essential, or they are clearly considered essential in principle. stomach. In addition, in each of the above-described embodiments, when numerical values such as the number, numerical value, amount, range, etc. of the constituent elements of the embodiment are mentioned, when it is explicitly stated that they are particularly essential, and when they are clearly limited to a specific number in principle It is not limited to that specific number, except when In addition, in each of the above-described embodiments, when referring to the material, shape, positional relationship, etc. of the constituent elements, unless otherwise specified or in principle limited to a specific material, shape, positional relationship, etc. , its material, shape, positional relationship, and the like.

REFERENCE SIGNS LIST 10 fragrance device 12 housing 124 bypass channel 13 first cartridge 14 second cartridge 15 first door 16 second door 17 third door 18 fourth door

Claims (4)

A fragrance device for blowing air containing perfume,
a first cartridge (13, 42) containing a liquid first perfume therein;
a second cartridge (14, 43) containing a liquid second flavor therein;
It has an inlet (121, 411) through which wind flows in and an outlet (122, 412) through which wind flows out, and an internal space (123, 413) communicating with the inlet and the outlet is formed therein, and the inlet from the inlet to the outlet, the first cartridge and the second cartridge are held in the internal space in a state in which the air can pass through the respective interiors of the first cartridge and the second cartridge, and from the inlet to the a housing (12, 41) forming a bypass flow path (124, 415) in the internal space through which the wind directed to the outlet flows bypassing the first cartridge and the second cartridge;
A first state provided in the internal space, in which the air flowing from the inlet to the outlet flows through the inside of the first cartridge and does not flow through the inside of the second cartridge and the bypass channel, and a state from the inlet to the outlet. Switching units (15, 16, 17, 18, 45, 46, 48, 49 , 50, 51). 2. The fragrance device according to claim 1, wherein said second cartridge has a structure with a higher pressure loss compared to said first cartridge when wind passes through it. The first cartridge has a first inlet (13a) through which wind enters,
said second cartridge has a second inlet (14a) through which air enters;
The switching unit includes a first entrance door (15) that opens and closes the first entrance and a second entrance door (17) that opens and closes the second entrance,
2. The fragrance device according to claim 1, wherein the degree of opening of said second entrance door when in said second state is smaller than the degree of opening of said first entrance door when in said first state. The first cartridge and the second cartridge are arranged side by side in one direction (D2),
the bypass channel is a space sandwiched between the outer wall of the first cartridge and the outer wall of the second cartridge in the one direction;
2. The fragrance device of claim 1, wherein the width of the second cartridge in the one direction is less than the width of the first cartridge in the one direction.

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