JP6578523B1 - Fragrance clock - Google Patents

Abstract

[Structure] A scent clock 100 includes an olfactory display 10 on which a cartridge containing a plurality of scent sources is mounted, an information processing device 4 for outputting a scent from the olfactory display 10 based on an ejection pattern, and the like. For example, the user can set the ejection pattern and the set time so that a plurality of scents are output for the purpose of use when waking up. When the set time is reached, for example, a citrus fragrance with low irritation is output at a low concentration, and the concentration gradually increases so as to become a strong fragrance of a refreshing system. [Effect] It is possible to output the scent while adjusting the type and concentration of the scent according to the user. For example, by outputting a plurality of scents as described above, an effect of awakening the brain while suppressing stress applied to the user can be expected. In this case, since the user can obtain the preparation time to wake up, the user can get up comfortably. [Selection] Figure 1

Description

  The present invention relates to a scent clock, and more particularly to a scent clock that outputs a scent at a predetermined time, for example.

  An example of background art is disclosed in Patent Document 1. In Patent Document 1, the fragrance evaporates from the surface of the evaporation promoting member while the timer is set. Also, when the timer expires, the release of the fragrance is stopped. Thereby, a fragrance | flavor can be discharge | released only for the fixed time at the time of use of a fragrance | flavor.

JP-A-7-59838 [A61L 9/02, A61L 9/12, B65D 83/00, B65D 85/00]

  However, even if the timer expires and the release of the fragrance is stopped, the evaporated fragrance remains in the air, so that the fragrance of the fragrance remains in the space even after the release of the fragrance is stopped. Therefore, when the timer is set so as to release two kinds of fragrances in a short time, it is assumed that the two kinds of fragrances are mixed in the same space, and the effect of the fragrance cannot be obtained appropriately. .

  Therefore, the main object of the present invention is to provide a novel scented clock.

  Another object of the present invention is to provide a scent clock that can output a scent while adjusting the type of scent according to the user.

  The present invention employs the following configuration in order to solve the above problems. The reference numerals in parentheses, supplementary explanations, and the like indicate the corresponding relationship with the embodiments described in order to help understanding of the present invention, and do not limit the present invention.

According to a first aspect of the present invention, a cartridge including an incense source is attached to each of a plurality of cartridge mounting locations, and a plurality of wind sources are provided individually corresponding to the plurality of cartridge mounting locations. from incense source in the cartridge corresponding to the source by that to inject fragrant component a fragrance timepiece using olfactory display that outputs Ri incense, comprising a first memory means for storing the injection pattern table, the injection pattern table Has at least one injection ID, and sets, corresponding to the injection ID, an aroma code indicating at least a scent component and an injection time indicating a time for injecting the scent component indicated by the aroma code, and at least a set time and an injection Second storage means for storing the injection task table in which the ID is set, the current time matches the set time of the injection task table When the determination means determines whether or not the current time coincides with the set time of the injection task table, the aroma indicated by the corresponding injection ID in the injection pattern table based on the injection ID of the injection task table It is a scent clock provided with control means for controlling the wind power source so that the scent component indicated by the code is jetted for the jetting time .

In the first invention, the olfactory display (10 ) of the scent clock (100: reference numeral exemplifying a corresponding part in the embodiment; hereinafter the same ) is provided individually corresponding to a plurality of cartridge mounting locations. a plurality of wind sources was, you outputs Ri incense by that to inject fragrant components from incense source in the cartridge corresponding to the wind source by the wind source. For example, olfactory display receives the instruction signal, and drives the appropriate wind source outputs a plurality scent by injecting the aroma components from the scent source in each cartridge. The first storage means (532) has at least one injection ID, and sets an aroma code indicating at least a scent component and an injection time indicating a time for injecting the scent component indicated by the aroma code corresponding to the injection ID. The second storage means (534) stores at least the injection task table in which the set time and the injection ID are set. When the determination means (400, S31) determines that the current time coincides with the set time of the injection task table, the control means (400, S39) corresponds in the injection pattern table based on the injection ID of the injection task table. The wind power source is controlled so that the scent component indicated by the aroma code indicated by the jet ID is jetted for the jet time .

According to the first invention, if one or more injection pattern tables are set in the first storage means, it is possible to easily set an injection task table suitable for the user simply by selecting the injection pattern table. it can.

A second invention is dependent on the first invention, and the injection pattern table has a plurality of injection times indicating a time for injecting the fragrance component indicated by each of the plurality of aroma codes and the plurality of aroma codes for one injection ID. When the determination unit determines that the current time coincides with the set time of the injection task table, the control unit indicates the corresponding injection ID in the injection pattern table based on the injection ID of the injection task table. It is a scent clock that controls a plurality of wind power sources so that a plurality of scent components indicated by a plurality of aroma codes are sequentially ejected for a correspondingly set ejection time.

According to a third aspect of the present invention, a cartridge including an incense source is attached to each of a plurality of cartridge mounting locations, and a plurality of wind sources provided individually corresponding to the plurality of cartridge mounting locations are provided. The olfactory display that outputs fragrance by ejecting the scent component from the scent source in the cartridge corresponding to the source further includes first storage means for storing the spray pattern table, and the spray pattern table includes at least one spray ID. In accordance with the injection ID, at least the aroma code indicating the scent component and the injection time indicating the time to inject the scent component indicated by the aroma code are set, and at least the set time and the injection ID are set Scent clock program executed by a scent clock computer comprising second storage means for storing a task table A determination means for determining whether or not the current time matches a set time of the injection task table, and when the determination means determines that the current time matches the set time of the injection task table, the injection task It is a scent clock program that functions as a control means for controlling the wind power source so that the scent component indicated by the aroma code indicated by the corresponding jet ID in the jet pattern table is jetted for the jet time based on the jet ID of the table. .

According to the present invention, it is possible to easily set an injection task table suitable for a user.

  The above object, other objects, features, and advantages of the present invention will become more apparent from the following detailed description of embodiments with reference to the drawings.

FIG. 1 is an illustrative view showing an outline of a scented clock according to one embodiment of the present invention. FIG. 2 is an illustrative view showing one example of a configuration of the scent clock shown in FIG. FIG. 3 is an external view showing an example of the external appearance of the olfactory display shown in FIGS. 1 and 2. 4 is an illustrative view schematically showing an example of an internal structure of the olfactory display shown in FIG. FIG. 5 is a cross-sectional view schematically showing an example of the internal structure of the olfactory display shown in FIG. 3 as viewed from the side, and shows a cross section taken along the line VV of FIG. FIG. 6 is a perspective view showing an example of the appearance of a display body included in the olfactory display shown in FIG. FIG. 7 is an illustrative view showing one example of a state where a cover of the display main body shown in FIG. 6 is opened. 8 is a cross-sectional view schematically showing an example of the internal structure as viewed from the front side of the display main body shown in FIG. FIG. 9 is a cross-sectional view schematically showing an example of the internal structure as seen from the side surface direction of the display main body shown in FIG. FIG. 10 is a cross-sectional view showing an example of a cross section when the wind power source included in the olfactory display shown in FIG. 3 is cut in a diagonal direction. FIG. 11 is a cross-sectional view showing an example of a cross section when the operation sound suppression unit included in the olfactory display shown in FIG. 3 is cut in a direction orthogonal to the thickness direction. 12 is a perspective view showing an example of the appearance of a scent source cartridge used in the olfactory display of FIG. FIG. 13 is an illustrative view showing one example of an appearance of the scent source cartridge of FIG. 12 viewed from the front side. FIG. 14 is a circuit diagram showing an example of a control circuit provided in the olfactory display shown in FIG. 15 is an illustrative view for explaining an example of a method for adjusting the concentration of the scent component ejected from the olfactory display shown in FIG. 3, and FIG. 15 (A) is a method for adjusting the concentration to normal (medium). FIG. 15B shows an example of a method for adjusting the density to a high state, and FIG. 15C shows an example of a method for adjusting the density to a low state. FIG. 16 is a block diagram showing an example of the electrical configuration of the information processing apparatus shown in FIG. FIG. 17 is an illustrative view showing one example of a configuration of an injection pattern table included in the aroma pattern database shown in FIG. 18 is an illustrative view showing an example of an image visually representing the ejection pattern shown in FIG. 17, and FIG. 18 (A) is an example of an image showing a state in which the density is adjusted to gradually decrease. FIG. 18B is an example of an image showing an example of a state in which the density is adjusted to gradually increase. FIG. 19 is an illustrative view showing one example of a configuration of an injection task table included in the aroma pattern database shown in FIG. 20 is an illustrative view showing one example of an ejection screen displayed on the display of the information processing apparatus shown in FIG. FIG. 21 is an illustrative view showing one example of a configuration of an injection history table included in the aroma pattern database shown in FIG. FIG. 22 is an illustrative view showing one example of a memory map of a memory of the information processing apparatus shown in FIG. FIG. 23 is a flowchart showing an example of a jetting task creation process of the processor of the information processing apparatus shown in FIG. FIG. 24 is a flowchart showing an example of a jetting task management process of the processor of the information processing apparatus shown in FIG. FIG. 25 is an illustrative view showing an outline of a scented clock according to a second embodiment of the present invention. FIG. 26 is an illustrative view showing one example of a configuration of the scent clock of the second embodiment shown in FIG. FIG. 27 is a circuit diagram showing an example of a control circuit provided in the olfactory display of the second embodiment shown in FIG. FIG. 28 is a block diagram showing an example of the electrical configuration of the information processing apparatus shown in FIG. FIG. 29 is a block diagram showing an example of the electrical configuration of the pre-sleep state detection apparatus shown in FIG. FIG. 30 is an illustrative view showing one example of a structure of an injection task table stored in the aroma pattern database of the second embodiment shown in FIG. FIG. 31 is an illustrative view showing one example of a part of a memory map of a memory of the information processing apparatus shown in FIG. FIG. 32 is a flowchart showing an example of the injection task creation process of the processor of the information processing apparatus of the second embodiment shown in FIG. FIG. 33 is a flowchart showing an example of a jetting task management process of the processor of the information processing apparatus of the second embodiment shown in FIG.

<First embodiment>
1 to 3, a scent clock 100 according to an embodiment of the present invention includes an information processing device 4 and an olfactory display 10. The scent clock 100 can output a predetermined scent from the olfactory display 10 at a preset time determined by a user or the like. And the user can smell a predetermined scent at the set time.

  The information processing apparatus 4 is a kind of notebook PC, for example, and is connected to the olfactory display 10. Further, the information processing apparatus 4 can acquire information such as the weather and season when the scent is output from the server via a network such as the Internet.

For example, the olfactory display 10 is attached to a tripod platform and installed around the user so that the injection port 16 for injecting the scent faces the direction of the user's face sleeping. The olfactory display 10 outputs a scent within a limited range in terms of time and space in accordance with instructions from the information processing device 4.

  Note that the olfactory display 10 of the present embodiment is used for enhancing the realism and realism of content by adding scent (olfaction information) to content including video and sound and outputting (presenting) it to the user. You can also. For example, the olfactory display 10 includes the information processing device 4, a television, a radio, a game machine, a karaoke device, a camera, a CD player, a DVD player, a mobile phone (including a so-called smartphone), a smart watch, a smart glass, a PC, and the like. The scent can be output in conjunction with various audiovisual displays.

  FIG. 4 is an illustrative view schematically showing an internal structure of the olfactory display 10 as viewed from the front side, and shows an internal state of the olfactory display 10 by omitting a jet plate 34 to be described later. FIG. 5 is a cross-sectional view of the olfactory display 10 taken along the line VV in FIG. 4 and schematically shows the internal structure of the olfactory display 10 viewed from the side.

  As shown in FIGS. 4 and 5, the olfactory display 10 includes a display main body 12 and a plurality of scent source cartridges (hereinafter sometimes simply referred to as “cartridges”) 14 detachably housed therein. . In this embodiment, the display main body 12 accommodates six cartridges 14 arranged in the circumferential direction. However, the number of cartridges 14 that can be simultaneously stored in the display main body 12 (the number of cartridge storage chambers 24 described later) is not particularly limited.

  Hereinafter, the configuration of the olfactory display 10 will be specifically described. As shown in FIGS. 6 to 9, the display main body 12 includes a housing 20 that forms an outer shell thereof, and a plurality of cartridge housing chambers (cartridges) formed by partitioning the internal space of the housing 20 with partition walls 22. Mounting location) 24. Each of the cartridge storage chambers 24 is provided with a wind power source 26 and an operation sound suppressing unit 28 that are closely arranged in the partition wall 22.

  The housing 20 includes a base portion 30, a side wall 32, and an injection plate 34, and is formed in a hollow hexagonal column shape using an appropriate material such as acrylic resin. As for the size of the housing 20, the length between the apexes facing each other when viewed from the front is 60 mm, for example, and the length in the axial direction (front-rear direction) is 60 mm, for example.

  Although illustration is omitted, inside the display main body 12 is provided a control board chamber for housing the control board. The control board has a structure in which electronic components such as a CPU and a memory are mounted on the board (see FIG. 14), and is connected to a wind source 26, an auxiliary wind source 76, and the like, which will be described later, via wiring (not shown). Then, the operation of the olfactory display 10 is controlled.

  The base portion 30 is formed in a regular hexagonal plate shape, and is disposed on the rear side of the housing 20 (the side opposite to the user). Side walls 32 are provided at the peripheral edge of the base portion 30. The side wall 32 is formed in a hexagonal cylindrical shape by a holder 32a continuous with each of the corners of the peripheral edge of the base portion 30 and a slide cover 32b provided between the holders 32a. A slide groove 36 is formed on the side surface of the holder 32a, and a projection (not shown) formed on the side surface of the slide cover 32b is fitted into the slide groove 36. As a result, the slide cover 32b can slide between the holders 32a. As will be described later, each of the openings between the holders 32 a functions as a cartridge exchange port 38 of the cartridge storage chamber 24, and the slide cover 32 b is used for opening and closing the cartridge exchange port 38. The slide cover 32b abuts against the rear end of the cartridge 14 in the insertion direction when the cartridge 14 is stored in the cartridge storage chamber 24, and has an effect of pushing the cartridge 14 in the insertion direction.

  An injection plate 34 is provided on the front end of the side wall 32, that is, on the front side of the housing 20. The injection plate 34 is formed in a regular hexagonal plate shape and covers the end opening of the side wall 32. A dome-shaped protrusion 40 is provided at the center of the injection plate 34, and a communication hole 42 extending in the thickness direction of the injection plate 34 is formed so as to penetrate the center of the protrusion 40. The communication hole 42 has a tapered diameter-reduced portion that is reduced in diameter toward the front side, and the front portion is formed in a straight tube shape. The tip opening of the protrusion 40 functions as the ejection port 16, and the communication hole 42 communicates the ejection port 16 with each cartridge storage chamber 24. In addition, the diameter of the injection port 16 is 0.8 mm, for example.

Further, a screw hole 44 for attaching a tripod head is formed at an appropriate position of the housing 20. In this embodiment, the screw hole standard is adapted to the camera platform. The camera head standard for cameras is standardized by the global standard (1/4 inch-20 UNC), so if the screw hole standard is adapted to it, the camera heads around the world will be smelled. This is convenient because it can be used as it is as a pan head for the display 10.

  Further, the internal space of the housing 20 is partitioned by radial partition walls 22 that connect the opposing holders 32a, and in the housing 20, six regular triangular prism-shaped cartridge housing chambers 24 arranged in the circumferential direction are formed. The That is, the inner side surface of the cartridge housing chamber 24 has two inclined surfaces 46 that converge toward the center side of the housing 20 (that is, inwardly incline with respect to the insertion direction of the cartridge 14 described later). . Further, the central shaft 48 that is a connecting portion of each partition wall 22 is formed in a hexagonal column shape, protrudes from the base portion 30, and its tip end portion extends into the communication hole 42. The distal end portion of the central shaft 48 has a tapered shape in which a groove-shaped notch is formed on the outer peripheral surface, and a fragrance (air containing fragrance components) discharged from a fragrance outlet 88 of the cartridge 14 described later is directed toward the injection port 16. It functions as a guide part to guide. As a result, the reverse flow of the fragrance and the penetration of the fragrance into the other cartridge 14 are prevented.

  Each cartridge housing chamber 24 is formed with an air delivery port 50 that communicates with the ejection port 16 via a communication hole 42 formed in the ejection plate 34. Each cartridge storage chamber 24 is formed with a cartridge exchange port 38 that can be opened and closed by a slide cover 32b.

  Further, each cartridge storage chamber 24 is provided with an air source 26 in close contact with the partition wall 22. The wind source 26 is disposed in the partition wall 22 (that is, radially disposed in the housing 20) and constitutes a part of the partition wall 22. A nozzle 52 (see FIG. 10) provided at the center of the wind source 26 communicates with the inside of the cartridge housing chamber 24 and functions as an air supply port 54 through which air flows into the cartridge 14 housed in the cartridge housing chamber 24. To do. The size of the wind source 26 is, for example, 20 mm long, 20 mm wide, and 2 mm thick.

  FIG. 10 shows a cross section when the wind source 26 is cut in a diagonal direction. The wind power source 26 includes a diaphragm 58 to which a piezoelectric element (piezo element) 56 is attached. By applying a high-frequency alternating voltage (sine wave voltage or rectangular wave voltage) or a pulse voltage to the piezoelectric element 56, the diaphragm 58 is provided. This is a piezoelectric type in which 58 is bent and vibrated at high speed in the plate thickness direction to generate an air flow.

  Hereinafter, the operation of the wind source 26 will be briefly described. In the wind power source 26, air suction and discharge are repeated from the vent hole 62 provided in the center of the pump chamber 60 in accordance with the vibration of about 26 kHz of the diaphragm 58 to which the disk-shaped piezoelectric element 56 is attached. The air taken into the pump chamber 60 from the suction flow path 64 at the time of suction passes through the nozzle 52 on the top plate 66 arranged coaxially with the vent hole 62 at the time of discharge, and expands in the tapered pipe line in the nozzle 52. Discharged. At this time, since a negative pressure portion is generated in the space between the vent hole 62 and the nozzle 52 due to the venturi effect, the air in the vent hole 62 is continuously sucked. Thereby, a continuous pumping operation from the vent hole 62 toward the nozzle 52 is obtained.

  Since the wind power source (piezoelectric wind power source) 26 driven by the piezoelectric element 56 is not a rotating mechanism such as a blower fan or a scroll blower, it can be reduced in size and height, and has low power consumption. . In addition, it has a feature that it can generate a high static pressure in a short time with virtually no vibration. As such a wind power source 26, for example, a micro blower (model number: MZBX001) manufactured by Murata Manufacturing Co., Ltd. can be used.

  Returning to FIG. 8 and FIG. 9, on the back side of the wind source 26 (upstream side of the air flow path), a flat plate shape for suppressing leakage of the operation sound of the wind source 26 (vibration sound of the diaphragm 58) to the outside. Is provided. The operation sound suppression unit 28 also constitutes a part of the partition wall 22. The operation sound suppression unit 28 is formed of an appropriate material such as acrylic resin, and forms a hollow portion on the back side of the diaphragm 58. An outside air port 70 (see FIG. 11) of the operation sound suppressing unit 28 communicates with the outside of the housing 20 through an outside air inlet 74 formed at the peripheral edge of the base 30. The size of the operation sound suppression unit 28 is, for example, 20 mm long, 20 mm wide, and 2 mm thick.

  FIG. 11 shows a cross section when the operation sound suppression unit 28 is cut in a direction orthogonal to the thickness direction. As shown in FIG. 11, the side wall 68 of the operation sound suppression unit 28 is formed with an outside air port 70 for inhaling outside air when the wind power source 26 is operated, and the inside of the operation sound suppression unit 28 is C-shaped. It is partitioned off by a partition wall 72 having a shape. As a result, the operating sound of the wind power source 26 reaches the outside air port 70 so as to go around the maze-like air passage, so that leakage of the operating sound from the outside air port 70 is suppressed.

  Returning to FIGS. 8 and 9, an auxiliary wind source 76 is provided in the base portion 30. The auxiliary wind source 76 is provided independently from each cartridge storage chamber 24, and is used for acceleration of fragrance, concentration adjustment of fragrance components, deodorization, and the like. The auxiliary wind source 76 is the same as the wind source 26, that is, a diaphragm having a piezoelectric element attached thereto. When a high frequency alternating voltage is applied to the piezoelectric element, the diaphragm is vibrated at high speed to generate an air flow. It is good to use what is generated. The operation sound suppression unit 28 is also provided on the back side of the auxiliary wind source 76 as appropriate.

  Further, an auxiliary passage 78 is formed in the central shaft 48 as a passage for the air (odorless air) discharged from the nozzle of the auxiliary wind source 76. The auxiliary passage 78 is a through hole that linearly connects the nozzle of the auxiliary wind source 76 and the communication hole 42, and extends linearly to the injection port 16 through the communication hole 42. When the auxiliary wind source 76 is activated, odorless air is discharged into the auxiliary passage 78 from the nozzle of the auxiliary wind source 76. Since the odorless air goes straight to the injection port 16 without following a complicated path, the odorless air is injected from the injection port 16 with almost no pressure drop.

  The cartridge 14 is detachably accommodated in the cartridge accommodation chamber 24 of the display main body 12. As shown in FIGS. 12 and 13, the cartridge 14 includes a container body 80 formed of a synthetic resin such as polyethylene or polypropylene. The container main body 80 is formed in a hollow regular triangular prism shape so as to have an outer surface shape that conforms to the inner surface shape of the cartridge housing chamber 24 without a gap. In the container main body 80, when the cartridge 14 is housed in the cartridge housing chamber 24, an air inlet 82 is formed at a position facing the air supply port 54 of the cartridge housing chamber 24 (see FIG. 5). In other words, the outer surface of the container body 80 has two inclined surfaces 84 that converge with respect to the insertion direction of the cartridge 14, and the intake port 82 is formed on one of the inclined surfaces 84.

Further, an aroma outlet 88 is formed in the container body 80 at a position facing the air delivery port 50 of the cartridge housing chamber 24 (see FIGS. 3 and 4). Since each of the fragrance outlets 88 communicates with the injection port 16 almost linearly through the communication hole 42, the fragrance delivered from the fragrance outlet 88 is injected from the injection port 16 without reducing its momentum. The diameter of the air inlet 82 and the diameter of the fragrance outlet 88 are, for example, 0.8 mm.

  Further, since the internal path of the display main body 12 that comes in contact with the fragrance delivered from the cartridge 14 is only the communication hole 42 of the ejection plate 34, the attachment of the scent component (residual scent) to the display main body 12 hardly occurs. In addition, since the diameter of the air inlet 82 and the fragrance outlet 88 is small, when the wind source 26 is not operated, leakage of fragrance from the cartridge 14 hardly occurs.

  A solid fragrance source 90 is accommodated inside the container body 80. The solid fragrance source 90 is manufactured, for example, by impregnating (impregnating) a liquid fragrance into a granular porous body and retaining the liquid fragrance on the outer surface and pores of the porous body. As the fragrance, natural fragrances, synthetic fragrances, and blended fragrances thereof can be used as appropriate. As the porous body, a granular body such as calcium silicate can be appropriately used. The particle size and shape of the porous body are not particularly limited. By using the solid fragrance source 90 as described above, the fragrance (fragrance component) can be gradually released from the fragrance source 90.

  When the cartridge 14 is housed in the cartridge housing chamber 24 of the display main body 12, the slide cover 32 b is opened, and the cartridge 14 is pushed from the cartridge replacement port 38 toward the central axis 48 into the cartridge housing chamber 24. Accommodate. Thereafter, by closing the slide cover 32b, the rear end side in the insertion direction of the cartridge 14 (container body 80) is suppressed by the slide cover 32b. Accordingly, the connection portion between the air supply port 54 of the display main body 12 and the air intake port 82 of the cartridge 14 is improved in close contact and is properly adhered.

  Further, since the cartridge housing chamber 24 and the cartridge 14 have inclined surfaces 46 and 84 that incline inward with respect to the insertion direction, the inlet portion (that is, the cartridge exchange port 38) of the cartridge housing chamber 24 is inserted in the cartridge 14 insertion direction. It becomes larger than the front part. For this reason, it is easy to insert the cartridge 14 into the cartridge housing chamber 24.

  In the olfactory display 10 having such a configuration, when an alternating voltage is applied to the piezoelectric element 56 of the wind power source 26 corresponding to the cartridge 14 containing the target scent source 90, the diaphragm 58 is flexed and vibrated at high speed, and the outside air Outside air is sucked from the suction port 74, and high-speed and high-pressure air is sent into the cartridge 14 from the nozzle 52 (air supply port 54) of the wind power source 26 through the suction port 82. The air in the cartridge 14 contains a gaseous scent component volatilized from the scent source 90, and the air (scent) containing the scent component is discharged from the scent outlet 88 into the communication hole 42.

  Specifically, the control board of the olfactory display 10 is attached to the cartridge 14 containing the target scent source 90 in response to an instruction signal sent from the information processing device 4 via the I / F 206 (see FIG. 14). An alternating voltage is applied to the piezoelectric element 56 of the corresponding wind source 26. Then, the diaphragm 58 is bent and vibrated at a high speed, and the outside air is sucked into the wind source 26 through the outside air inlet 74 and the operation sound suppression unit 28, and at the same time, from the nozzle 52 of the wind source 26 into the cartridge 14. High pressure air is sent. The air in the cartridge 14 contains a gaseous scent component volatilized from the scent source 90, and the air (scent) containing the scent component is discharged from the scent outlet 88 into the communication hole 42.

The instruction signal includes scent information (aroma code) indicating the scent component to be ejected. The aroma code is assigned with a unique number (code) for each scent (or scent type) such as banana, apple, vanilla, orange and the like. For example, the port (cartridge housing chamber 24) of the olfactory display 10 is indicated by the numbers 1-6. The aroma pattern database 404 (see FIG. 16) provided in the information processing apparatus 4 stores (saves) a device information table indicating an aroma code indicating which type of incense source 90 cartridge is installed in each port. The

  Therefore, the information processing apparatus 4 outputs an instruction signal to the olfactory display 10 based on the device information table. And this instruction | indication signal contains the information of the scent component to eject, ie, the wind power source 26 (piezoelectric element 56) provided in the cartridge 14 in which the said fragrance | flavor source 90 was put.

  In addition, the control board operates the auxiliary wind source 76 in response to the instruction signal sent from the information processing device 4. That is, an alternating voltage is also applied to the piezoelectric element 56 of the auxiliary wind source 76. Thereby, the odorless air discharged from the nozzle 52 of the auxiliary wind source 76 passes through the linear auxiliary passage 78 and goes straight to the injection port 16. The fragrance discharged from the fragrance outlet 88 into the communication hole 42 merges with the odorless air discharged from the auxiliary wind source 76 in the communication hole 42, and is accelerated in the fragrance injection direction by riding on the air flow. The jet is ejected vigorously from the jet port 16 with almost no delay with respect to the instruction signal from the processing device 4. When the application of the alternating voltage to the piezoelectric element 56 of the wind source 26 and the auxiliary wind source 76 is stopped, the fragrance injection from the injection port 16 is also instantaneously stopped.

  At this time, since the piezoelectric wind source 26 and the auxiliary wind source 76 are used, the start and stop of the fragrance injection are executed with good responsiveness (that is, accurate time control is possible), and pulsation is performed. It is also possible to output a constant fragrance that is not the target. Further, by providing the auxiliary wind source 76, the fragrance discharged from the cartridge 14 can be appropriately accelerated in the fragrance injection direction even when the pressure drop occurs in the communication hole 42 only by the wind source 26. The scent injection performance can be maintained or improved. In other words, the fragrance is vigorously ejected from the ejection port 16 with directivity, and the scent can be output in a spatially limited range (that is, only near the user's face).

  In addition, after stopping the wind source 26 (after outputting the scent), if the auxiliary wind source 76 is continuously operated to spray only odorless air and the injected scent component is diffused or diluted, the scent component Compared with free diffusion as it is, quicker deodorization becomes possible.

  In this embodiment, six cartridges 14 are provided, and fragrance is ejected from one ejection port 16 through the communication hole 42. For this reason, not only six kinds of scents can be output individually, but also the scents can be prepared and output by operating the wind source 26 of each cartridge 14 simultaneously or by time sharing. For example, if the incense source 90 accommodated in each cartridge 14 is A, B, C, D, E, F, “A + B, A + C,..., E + F,. E + F, A + B + C + D + E + F ”can be provided with various fragrances. Moreover, the ratio which mix | blends fragrance can also be changed suitably by adjusting the duty ratio of the input signal of each wind power source 26, etc. FIG.

  In this embodiment, the information processing device 4 also outputs a control signal for adjusting the concentration of the scent component in addition to the instruction signal. And the olfactory display 10 can adjust the density | concentration of a fragrance component according to a control signal. Specifically, the wind power source 26 and the auxiliary wind power source 76 are alternately operated, and the time for operating them (hereinafter referred to as “operation period”) and the time for stopping them (hereinafter referred to as “stop period”) are controlled. Then, the mixing ratio of the fragrance from the cartridge 14 and the odorless air from the auxiliary wind source 76 is adjusted.

Hereinafter, a method for adjusting (controlling) the concentration of the scent component will be described. In the present embodiment, as a method for controlling the concentration of the scent component, an injection method is employed in which the fragrance and the odorless air are alternately injected, and the period in which the fragrance and the odorless air are injected is changed. However, in other examples, the fragrance and odorless air are alternately injected, the injection method of changing the number of times the fragrance and odorless air are injected, and the fragrance and odorless air are alternately injected, An injection method that changes the amount (injection amount) of injecting the fragrance at a time may be employed.

  FIG. 14 is an illustrative view showing one example of a control circuit 200 for realizing the above-described injection method of the present embodiment. The control circuit 200 is formed on a control board. As shown in FIG. 14, the control circuit 200 includes a processor 202, and a memory 204 is connected to the processor 202. The memory 204 is a rewritable storage medium such as a flash memory or a RAM. The processor 202 is connected to an I / F 206, and is connected to the information processing apparatus 4 via the I / F 206 so as to be communicable. Further, a switch circuit 208 is connected to the processor 202. One end of seven piezoelectric elements 56 included in each of the six wind sources 26 and one auxiliary wind source 76 is connected to the switch circuit 208. Each of the other ends of these piezoelectric elements 56 is connected to an alternating voltage source 300 provided outside the control circuit 200 via a variable resistor R.

  For example, the switch circuit 208 includes seven switching elements (for example, FETs) and is provided between each piezoelectric element 56 and the ground. The processor 202 controls time for turning on / off each switching element, controls (changes) the resistance value of each variable resistor R, or controls both according to the control signal. That is, at least one of the operation period of the wind source 26 and the auxiliary wind source 76 and the magnitude of the amplitude of the piezoelectric element 56 included in the wind source 26 and the auxiliary wind source 76 are controlled.

  Note that the instruction signal from the information processing device 4 described above is input to the processor 202 of the olfactory display 10.

  In addition, a control signal for controlling (adjusting) the concentration of the scent component output from the information processing device 4 is input to the control circuit 200 illustrated in FIG. For example, when a control signal for linearly changing the concentration is input to the processor 202 (olfactory display 10), the concentration of the scent component ejected from the olfactory display 10 changes linearly accordingly. However, since it is difficult to recognize minute changes in concentration by human olfaction, the concentration may be adjusted stepwise. In this embodiment, the density can be arbitrarily adjusted (controlled) from 0% (low) to 100% (high). However, in the following description, for simplicity, a case will be described in which the density is adjusted in three stages (high, normal (medium), and low).

  In the case of the jetting method of the present embodiment, the wind power source 26 provided in the cartridge 14 in which the scent source 90 of the scent to be output is placed during the scent output period (hereinafter referred to as “scent output period”). The piezoelectric element 56 of each wind source (32, 74) is driven and stopped so that the operation period of the auxiliary wind source 76 and the operation period of the auxiliary wind source 76 are reversed. However, in this injection method, an alternating voltage having a constant peak value is applied to each piezoelectric element 56. Specifically, the alternating voltage from the alternating voltage source 300 is stepped down by each variable resistor R, and the reduced alternating voltage (for example, frequency 26 kHz, 19.5 Vp-p) is applied to each piezoelectric element 56.

  The scent output period is a period (time) specified in the instruction signal from the information processing device 4.

FIG. 15A shows the operation of the wind source 26 and the auxiliary wind source 76 when a control signal for setting the concentration of the scent component to normal (medium) is input from the information processing device 4 to the processor 202. An example of control (time series change of operation and stop) is shown. 15B controls the operation of the wind source 26 and the auxiliary wind source 76 when a control signal for setting the concentration of the scent component high is input from the information processing device 4 to the processor 202. An example is shown. Further, FIG. 15C controls the operation of the wind source 26 and the auxiliary wind source 76 when a control signal for setting the concentration of the scent component low is input from the information processing device 4 to the processor 202. An example is shown.

  However, the wind power source 26 shown in FIGS. 15A to 15C is the wind power provided in the cartridge 14 in which the scent source 90 instructed from the information processing apparatus 4, that is, the scent source 90 of the scent to be output is put. Source 26.

  As described above, in the injection method of the present embodiment, the operation period of the wind source 26 and the operation period of the auxiliary wind source 76 are reversed, and the wind source 26 and the auxiliary wind source 76 are operated alternately.

  In this embodiment, one operation period of the wind source 26 is determined according to the concentration of the scent component.

  For example, with the operation period when the concentration of the scent component is normal (medium) as a reference (for example, 1 second), the operation period when the concentration of the scent component is high is 1.5 times the reference (1.5 seconds) ) And the operating period when the concentration of the scent component is low is 0.5 times the reference (0.5 seconds). Here, for example, the period for controlling the operation of the wind source 26 is 2 seconds. Numerical values for the operation period and period according to the concentration are stored in the memory 204. When the processor 202 receives the control signal from the information processing device 4, the processor 202 determines the switching element provided in the switch circuit 208 according to these numerical values. Control on / off.

  Returning to FIG. 15A, when the concentration of the scent component is normal, one operation period of the wind source 26 is 1 second, and the cycle for controlling the operation is 2 seconds. One activation period of the source 76 is set to 1 second. That is, the one operation period of the wind source 26 and the one operation period of the auxiliary wind source 76 are set to the same length.

  In FIG. 15A, the operation period is described as H (high level) and the stop period is described as L (low level). However, the pulse given to the switching element such as an FET by the processor 202 is described. Means the level. That is, in this embodiment, the switching element is turned on when the pulse is at a high level, and the switching element is turned off when the pulse is at a low level.

  Further, as shown in FIG. 15B, when the concentration of the scent component is high, the single operation period of the wind source 26 is 1.5 seconds, and the cycle for controlling the operation is 2 seconds. The single operating period of the auxiliary wind source 76 is set to 0.5 seconds. That is, the one operation period of the wind source 26 is set to three times the one operation period of the auxiliary wind source 76. Accordingly, the concentration of the scent component is set higher than when it is normal.

  Furthermore, as shown in FIG. 15C, when the concentration of the scent component is low, the one operation period of the wind source 26 is 0.5 seconds, and the period for controlling the operation is 2 seconds. The single operating period of the auxiliary wind source 76 is set to 1.5 seconds. That is, the one operation period of the wind source 26 is set to a length of 1/3 of the one operation period of the auxiliary wind source 76. Therefore, the concentration of the scent component is made lower than when it is normal.

In the case of the injection method of the present embodiment shown in FIGS. 15 (A) to 15 (C) above, one operation period of the wind source 26 corresponding to the concentration is determined in advance. It is not necessary to be limited to. For example, in the case of the injection method according to another embodiment, a single operation period of the wind source 26 is set to a predetermined length, and the number (frequency) of operating the wind source 26 and the auxiliary wind source 76 is set. The density can also be adjusted. Therefore, in the injection method of another embodiment, information about a predetermined length of this operation period is stored in the memory 204.

  FIG. 16 is a block diagram showing an electrical configuration of the information processing apparatus 4. Referring to FIG. 16, information processing device 4 includes a processor 400 and the like. The processor 400 is connected to the olfactory display 10, the memory 402, the aroma pattern database (DB) 404, the communication LAN board 406, the output device 410, the input device 412, the GPS circuit 414, and the like.

  A communication device 408 is connected to the communication LAN board 406, and a GPS antenna 416 is connected to the GPS circuit 414.

  The processor 400 is also referred to as control means, and controls the operation of the information processing apparatus 4. The processor 400 also includes an RTC 400a that outputs date and time information. The memory 402 includes ROM, HDD, and RAM. In the ROM and the HDD, a control program for controlling the operation of the information processing apparatus 4 is stored in advance. The RAM is used as a work memory or a buffer memory of the processor 400.

  The aroma pattern DB 404 is also referred to as storage means, and associates the device information table described above, an injection pattern table (see FIG. 17) including an injection pattern when injecting a scent component, and a set time and an injection pattern for injecting the scent component And an injection history table (see FIG. 19) including an injection history of fragrance components. Since each table described above will be described later, a detailed description thereof will be omitted here.

  The communication LAN board 406 is configured by a DSP, for example, and provides transmission data provided from the processor 400 to the communication device 408, and the communication device 408 transmits the transmission data to another device (for example, a server) via the network. Further, the communication LAN board 406 receives data via the communication device 408 and gives the received data to the processor 400.

  The output device 410 includes a display and a speaker, and the input device 412 includes a microphone, a mouse, a keyboard, and the like. For example, the user uses the output device 410 and the input device 412 to input a set time to the scent clock 100 or to set the type of scent to be output.

  The GPS circuit 414 is activated when the current position is measured by the GPS function. When the GPS signal of the GPS satellite received by the GPS antenna 416 is input, the GPS circuit 414 executes a positioning process based on the GPS signal. As a result, latitude and longitude are calculated as GPS information (position information).

  Referring to FIG. 17, the injection pattern table includes an injection ID, a state, an injection type, an aroma code, an injection time, a concentration, a pattern, and an injection column corresponding to the pattern item of the injection pattern. An injection ID for identifying an injection pattern is stored in the injection ID column. One injection pattern is stored in the same row in association with this injection ID. That is, one row in the injection pattern table indicates one injection pattern identified by the injection ID.

In the status column, the purpose (use) of the injection pattern is stored. The purpose of use is sleep and wake-up, for example. For example, an injection pattern whose state is “sleep” indicates that the user is used at bedtime. The number of fragrance components ejected by one ejection pattern is shown in the ejection type column. For example, when “3” is stored in the injection type column, it means that three types of scent components are injected. In the aroma code column, an aroma code indicating a scent component to be ejected when the set time is reached is stored. The number of stored aroma codes corresponds to the value of the injection type stored in the injection type column. And when the some aroma code is memorize | stored, the order of the aroma code memorize | stored in the column of an aroma code shows the order which sprays a fragrance component as it is.

  Although illustration is omitted, when two or more aroma codes are enclosed in parentheses, it indicates that two or more scents are prepared and output. In this case, two or more scent components are ejected at a time.

  The ejection time indicates the scent output period for one kind of scent component (aroma code). For example, when “120” is stored in the injection time column, it indicates that the scent output period of one kind of scent component is 120 seconds. When “3” is stored in the injection type column, three types of scent components are jetted every 120 seconds, and the scent output period is 360 seconds (= 3 types × 120 seconds). .

  The density column stores the width of change in density (amount of change in density). The pattern column stores how to change the concentration of the scent component after the scent component is ejected. For example, if “weak” is stored in the pattern column and “80” is stored in the concentration column, a scent component with a concentration of 80% is injected when the set time is reached, and the final concentration is 0%. It shows that the concentration changes so that. When “strong” is stored in the pattern column and “100” is stored in the concentration column, the scent component starts to be injected at a concentration of 0% when the set time is reached, and the final concentration Indicates that the concentration changes so that becomes 100%. In addition, although illustration is omitted, when “constant” is stored in the pattern column, it indicates that the scent component is continuously ejected at the concentration of the value stored in the concentration column.

  In the column of jetting, for example, whether the scent component is jetted continuously or intermittently is stored. When “continuous” is stored in the injection column, the scent component is injected without interruption. On the other hand, when “intermittent” is stored in the injection column, the scent component is intermittently injected with a certain interval. Thus, when outputting a scent, the user can arbitrarily select whether to output continuously or intermittently.

  18 (A) and 18 (B) are illustrative views showing an example of an image visually representing each injection pattern shown in FIG.

  Referring to FIG. 18A, in the injection pattern of injection ID “000001”, there are three types of injection, the aroma code is “1, 2, 6”, the injection time is 120 seconds, and the concentration Is 80%, the pattern is “weak”, and the injection is “continuous”. In this case, the scent components indicated by the aroma code 1, the aroma code 2 and the aroma code 6 are continuously sprayed for 120 seconds each. Further, the concentration is 80% at the time when injection is started, and is controlled so as to become weak (0%) over 360 seconds. Therefore, when injection of the scent component is started, first, the scent component corresponding to the aroma code 1 is continuously sprayed at a concentration of 80%. When 120 seconds elapse after the scent component corresponding to the aroma code 1 is jetted, the concentration becomes about 54%. Subsequently, the scent component corresponding to the aroma code 2 is continuously sprayed at a concentration of about 54%, and after 120 seconds, the concentration becomes about 27%. Subsequently, the aroma component corresponding to the aroma code 6 is continuously ejected at a concentration of about 27%, and after 120 seconds, the concentration becomes 0%. When the concentration reaches 0%, the injection of the scent component ends.

For example, it is assumed that the above-described ejection pattern is used when the user sleeps. Therefore, the actual scent of the output scent is desirably lavender, cypress, cedarwood, coffee, and the like. In addition, by gradually lowering (weakening) the concentration of the scent component to be ejected, the user can be invited to a comfortable sleep.

  Next, referring to FIG. 18B, in the injection pattern of injection ID “000002”, there are four types of injection, the aroma code is “2, 3, 4, 5”, and the injection time is 120. Second, density is 100%, pattern is “strong”, and ejection is “intermittent”. In this case, the scent components indicated by the aroma code 2, the aroma code 3, the aroma code 4 and the aroma code 5 are intermittently ejected for 120 seconds each. Further, the concentration is 0% at the time when the injection is started, and is controlled to become strong (100%) over 480 seconds (= 4 types × 120 seconds). Therefore, when the injection of the scent component is started, the scent component corresponding to the aroma code 2 is first intermittently injected at a concentration of 0%, and after 120 seconds, the concentration becomes about 25%. Subsequently, the scent component corresponding to the aroma code 3 is intermittently ejected at a concentration of about 25%, and after 120 seconds, the concentration becomes about 50%. Subsequently, the aroma component corresponding to the aroma code 4 is intermittently ejected at a concentration of about 50%, and after 120 seconds, the concentration becomes about 75%. Subsequently, the scent component corresponding to the aroma code 5 is intermittently ejected at a concentration of about 75%, and after 120 seconds, the concentration becomes about 100%. And when a density | concentration reaches about 100%, injection of a fragrance component is complete | finished.

  For example, it is assumed that the above-described injection pattern is used when the user gets up. Therefore, it is desirable that the actual scent of the output scent is a citrus type such as grapefruit or lemon and a light-weight type such as peppermint or spearmint. Moreover, when injecting a scent component, a citrus scent with low irritation can be output at a low concentration, and the concentration can be gradually increased so as to gradually become a light scent or cool scent. Thereby, since the outputted scent is gently transmitted by the air flow, the effect of awakening the brain while suppressing the stress applied to the user can be expected. In this case, since the user can obtain the preparation time to wake up, the user can get up comfortably.

  In general, the psychological effect of a scent depends on what type of scent the user is sensitive to. Therefore, in a present Example, a scent can be output, adjusting the kind and density | concentration of a scent according to a user.

  In other embodiments, the concentration change may be not only linear but also curvilinear (exponential change). For example, the concentration of the scent component may change gradually at the initial stage when the scent is output, and the concentration may be rapidly changed after the final stage. Conversely, after the concentration of the scent component is changed abruptly at the initial stage, the concentration may change gradually.

  Referring to FIG. 19, the above-described injection task table includes columns of trigger, set time, injection ID, repetition, and valid / invalid corresponding to the task items of the injection task. Further, one row in the injection task table indicates one injection task. Further, in the present embodiment, a task in which a set time is associated with an injection ID or the like is set as an injection task. And the scent clock 100 performs the process which outputs fragrance based on the jetting task set effectively.

  In the trigger column, information indicating an event that triggers the output of the scent component is stored. For example, when “time designation” is stored as an event in the trigger column, it indicates that the scent component is ejected when the set time is reached. The set time for jetting the scent component is stored in the set time column.

Injection ID is memorize | stored in the column of injection ID. Information indicating whether or not to repeatedly use the injection task is stored in the repetition column. For example, when “OFF” is stored in the repetition column, it indicates that the corresponding injection task is not used repeatedly. On the other hand, when “ON” is stored in the repetition column, it indicates that the scent component is ejected every time the set time of the corresponding ejection task is reached.

  Information indicating whether or not the injection task is valid is stored in the valid / invalid column. For example, when “ON” is stored in the valid / invalid column, a process of outputting a scent is executed when the set time of the corresponding injection task is reached. On the other hand, when “off” is stored in the valid / invalid column, even if the set time of the corresponding injection task is reached, the process of outputting the scent is not executed.

  For example, referring to FIG. 20, when the set time (6:30) of the injection task shown in FIG. 19 is reached, the scent component is injected based on the injection pattern of injection ID “000002”. At this time, the date and time information when the scent component is jetted (for example, “September 28, 2014 (Sunday) 6:30”) and a set state ( For example, an ejection screen including “wake up”) is displayed. The injection screen also includes an image that visually represents the injection pattern of the injection ID “000002” shown in FIG. And the user can grasp | ascertain intuitively the change of the density | concentration of the scent output by confirming the ejection screen.

  Referring to FIG. 21, the above-described injection history table includes columns of injection date / time, season, time zone, weather, and injection ID. The date and time when the scent is output (for example, “201409272300 (September 27, 2014, 23:00)”) is stored in the injection date / time column. Further, one injection history is stored in the same row in association with this injection date / time. That is, one line in the injection history table indicates one injection history indicated by the injection date and time.

  The season column stores any one of spring, summer, autumn, and winter determined based on the injection date and time. In the present embodiment, the month indicated by the injection date is spring if it is March to May, summer if it is June to August, autumn if it is September to November, and winter if it is December, January and February. To be judged.

  The time zone column stores one of morning, noon, and night time zones determined based on the injection date and time. In this embodiment, if the time indicated by the injection date is 6-11 o'clock, it is judged morning, if it is 12-18 o'clock, it is noon, and if it is 19-24 o'clock, 0-5 o'clock, it is judged night.

  In the weather column, the weather when the scent is output is stored. In a present Example, the area | region where the fragrance was output based on the positional information etc. which were measured by the GPS function is specified, and the weather information of the specified area is acquired via a network. The weather column stores the weather (for example, “sunny”) based on the acquired weather information.

  In the column of the jet ID, the jet ID of the jet pattern used when jetting the scent component is stored.

  For example, when the scent is output based on the injection task shown in FIG. 19, the injection time is “201409272300”, the season is “autumn”, the time zone is “morning”, the weather is “cloudy”, and the injection ID is “000002”. The injection history is created, and the injection history is added to the injection history table.

  In addition, the judgment of a season may change with the country or area where a fragrance clock is utilized. For example, the southern hemisphere region is the opposite season to the northern hemisphere region. Therefore, in another embodiment, the reference for determining the season is changed based on the position information measured by the GPS function.

  The determination of the time zone may change depending on the season. For example, in another embodiment, if the season is summer, the time zone that is determined to be noon is set to be long, and the time zone that is determined to be night is set to be short. On the other hand, if the season is winter, the time zone determined to be noon is set to be short, and the time zone determined to be night is set to be long.

  Further, the position information may be registered in advance in the information processing apparatus 4. For example, the user can register position information in advance by designating a position where the scent clock 100 is used using map data.

  Here, the user can use the information processing apparatus 4 to set an injection pattern and create an injection task. That is, the user can output an arbitrary scent at an arbitrary set time. In another embodiment, the user may be able to re-edit the set injection pattern or the created injection task. In this case, the user can easily set an injection pattern and create an injection task.

  Further, the user can refer to the contents of the injection history table when creating a new injection task.

  The features of the present embodiment have been outlined above. Hereinafter, the present embodiment will be described in detail using the memory map of the memory 402 of the information processing apparatus 4 shown in FIG. 22 and the flowcharts shown in FIGS.

  FIG. 22 is an illustrative view showing one example of a memory map of the memory 402 of the information processing apparatus 4. As shown in FIG. 22, the memory 402 includes a program storage area 502 and a data storage area 504. In the program storage area 502, an injection pattern is set as a program for operating the information processing apparatus 4, and an aroma is output according to the injection task creation program 510 for creating an injection task and the created injection task An injection task management program 512 and the like are stored. Although illustration is omitted, the program for operating the information processing apparatus 4 includes a program for controlling the basic operation of the information processing apparatus 4 and the like.

  In the data storage area 504, a time buffer 530, a jet pattern buffer 532, a jet task buffer 534, an environment information buffer 536, and the like are provided.

  In the time buffer 530, time information output from the RTC 400a is temporarily stored. In the injection pattern buffer 532, each pattern item (for example, injection type, aroma code, etc.) of the injection pattern being set is temporarily stored. In the injection task buffer 534, each task item (for example, a set time) of the injection task being created is temporarily stored. The environment information buffer 536 temporarily stores the injection date, season, time zone, weather, and the like when the scent is output.

  Although not shown, the data storage area 504 stores data for displaying the ejection screen, a buffer for temporarily storing the results of various calculations, and other data necessary for the operation of the information processing apparatus 4. Counters and flags are also provided.

  The processor 400 of the information processing device 4 includes a plurality of injection task creation processes shown in FIG. 23 and an injection task management process shown in FIG. 24 under the control of a Linux (registered trademark) -based OS and other OSs. Process the task.

  FIG. 23 is a flowchart of the injection task creation process. For example, when an operation for executing a function for creating an injection task is performed, an injection task creation process is executed. When the injection task creation process is executed, the processor 400 determines in step S1 whether a pattern item has been input. For example, each pattern item of state, injection type, aroma code, injection time, concentration, pattern, and injection is input using the input device 412 of the information processing device 4, and it is determined whether an operation for confirming the input has been performed. The Note that the pattern item being input is stored in the ejection pattern buffer 532.

  If “NO” in the step S1, the processor 400 repeats the process in the step S1, for example, if an operation for confirming the input pattern item is not performed. On the other hand, if “YES” in the step S1, for example, when an operation for confirming the input pattern item is performed, the processor 400 creates an injection pattern based on the pattern item in a step S3. For example, as pattern items, the state is “wake up”, the injection type is “3”, the aroma code is “2, 3, 4, 5”, the injection time is “120 seconds”, the density is “80”, and the pattern is “weak”. ”And“ continuous ”are input, as shown in FIG. 17, the injection pattern of the injection ID“ 000002 ”is set. Here, the injection ID of the newly added injection pattern is determined based on the injection ID of the latest injection pattern stored in the injection pattern table. For example, when the injection ID of the latest injection pattern is “000001”, the injection ID of the newly added injection pattern is obtained by adding (incremented) “1” to the injection ID of the latest injection pattern. It becomes injection ID. When no injection pattern is registered, “000001” indicating the first injection pattern is set as the injection ID.

  The set injection pattern is added to the injection pattern table. The processor 400 that executes the process of step S3 functions as a setting unit.

  Subsequently, in step S5, the processor 400 determines whether or not a set time has been set. That is, it is determined whether the set time for outputting the scent is set. If “NO” in step S5, the processor 400 repeats the process of step S5, for example, if an operation for determining the set time is not performed. On the other hand, if “YES” in the step S5, for example, if an operation for determining the input set time is performed, the processor 400 creates an injection task by associating the injection pattern with the set time in a step S7. The created injection task is stored in the injection task buffer 534.

  Subsequently, in step S9, the processor 400 determines whether or not repetition has been enabled. That is, it is determined whether or not the created injection task is set to be repeated. If “NO” in the step S9, that is, if the setting of repeating the injection task is not made, the processor 400 sets the repetition task item in the injection task to “off”, and proceeds to the process of step S13.

  On the other hand, if “YES” is determined in the step S9, for example, when the injection task is set to be repeated, the processor 400 sets the repetition of the created injection task to be on in a step S11. That is, the repeated task item in the injection task is turned “ON”.

  Subsequently, in step S13, the processor 400 sets the created injection task to be valid. That is, the task item for valid / invalid of the injection task is set to “valid”. This is because the possibility that the created injection task is not used is extremely low, and in this embodiment, the effective / ineffective task item of the injection task is automatically set to “valid”. However, in another embodiment, “valid” or “invalid” may be set for this task item after confirming whether or not to validate.

When the process of step S13 ends, the injection task stored in the injection task buffer 534 is registered in the injection task table, and the processor 400 ends the injection task creation process.

  FIG. 24 is a flowchart of the injection task management process. For example, when the information processing apparatus 4 is turned on, the ejection task management process is executed.

  When the injection task management process is executed, the processor 400 determines whether or not the current time matches the set time in step S31. That is, the current time stored in the time buffer 530 is read, and it is determined whether or not a matching time is stored in the set time column of the injection task table. If “NO” in the step S31, that is, if the set time that coincides with the current time is not stored, the processor 400 repeats the process of the step S31.

  If “YES” in step S31, that is, if there is an injection task including a set time that matches the current time, the processor 400 acquires an injection task including the set time that matches the current time in step S33. For example, if the current time is 6:30, the injection task shown in FIG. 19 is acquired. Subsequently, in step S35, the processor 400 determines whether or not the acquired injection task is valid. That is, in the acquired injection task, it is determined whether validity is stored in the valid / invalid task item. If “NO” in the step S35, that is, if the acquired injection task is not valid, the processor 400 returns to the process of the step S31.

  On the other hand, if “YES” in the step S35, that is, if the acquired injection task is valid, the processor 400 acquires an injection pattern based on the acquired injection task in a step S37. For example, when the injection task shown in FIG. 19 is acquired, the injection pattern with the injection ID “000002” is acquired from the injection pattern table.

  Subsequently, in step S39, the processor 400 outputs an instruction signal and a control signal based on the injection pattern. For example, the instruction signal and the control signal are output to the olfactory display 10 so that the scent is output as indicated by the injection pattern of the injection ID “000002” illustrated in FIG. Further, when these signals are output, an ejection screen as shown in FIG. 20 is displayed on the display of the information processing apparatus 4.

  Subsequently, in step S41, the processor 400 determines whether or not repetition is set. That is, it is determined whether or not the repeated task item is “ON” in the acquired injection task. If “YES” in the step S41, that is, if the repeated task item is “ON”, the processor 400 proceeds to a process in step S45. On the other hand, if “NO” in the step S41, that is, if the repetitive task item is “off”, the processor 400 switches the acquired injection task to invalid in a step S43. That is, the repeated task item is set to “off” so that the acquired injection task is not repeated.

Subsequently, in step S45, the processor 400 acquires environment information. That is, the injection date and time is acquired from the time information stored in the time buffer 530, and the season and time zone are acquired from the injection date and time. Further, based on the position information, the weather information of the current position that is disclosed on the network is acquired. The acquired information is stored in the environment information buffer 536 as environment information. Subsequently, in step S47, the processor 400 creates an injection history. That is, an injection history is created based on the environment information stored in the environment information buffer 536 and the acquired injection ID of the injection task. Subsequently, in step S49, the processor 400 adds the created injection history to the injection history table. For example, when a fragrance is output based on the injection task shown in FIG. 19, an injection history as shown in FIG. 21 is added.

  Then, when the process of step S49 ends, the processor 400 returns to the process of step S31.

<Second embodiment>
In the second embodiment, a state before falling asleep (hereinafter referred to as a “pre-sleeping state”) in which the user is going to sleep is detected, and a scent is output when the pre-sleeping state is detected. The information processing apparatus 4 of the second embodiment employs a tablet terminal instead of a notebook PC. In addition, since the external appearance, structure, etc. of the olfactory display 10 are substantially the same as in the first embodiment, detailed description thereof is omitted.

  With reference to FIGS. 25 and 26, in the scent clock 100 of the second embodiment, the information processing device 4 and the olfactory display 10 are not connected by wire and perform wireless communication. Moreover, the pillow used by the user incorporates a pre-sleeping state detection device 6 including a pressure sensor 604 (see FIG. 29) and the like. The information processing device 4 also performs wireless communication with the pre-sleep state detection device 6.

  FIG. 27 is an illustrative view showing one example of a control circuit 200 of the olfactory display 10 of the second embodiment. Referring to FIG. 27, in the control circuit 200 of the second embodiment, a wireless communication module 210 is connected to the processor 202 instead of the I / F 206. The wireless communication module 210 is a module for performing communication using a short-range wireless communication technique such as Bluetooth (registered trademark), and receives an instruction signal and a control signal transmitted from the information processing apparatus 4. To the processor 202.

  The control circuit 200 of the second embodiment is connected to the processor 400 substantially the same as the first embodiment except that the wireless communication module 210 is connected to the processor 202.

  FIG. 28 is a block diagram showing an electrical configuration of the information processing apparatus 4 according to the second embodiment. With reference to FIG. 28, a wireless communication module 420 is connected to the processor 400 of the information processing apparatus 4 of the second embodiment instead of the communication LAN board 406. The wireless communication module 420 has substantially the same function as the wireless communication module 210 connected to the processor 202 of the control circuit 200 described above, and transmits an instruction signal and a control signal. Also, since the olfactory display 10 is not directly connected to the information processing apparatus 4 of the second embodiment, the olfactory display 10 is not shown in FIG.

  The information processing apparatus 4 of the second embodiment is substantially the same as the first embodiment except that the wireless communication module 420 is connected to the processor 400.

  FIG. 29 is a block diagram illustrating an example of an electrical configuration of the pre-sleep state detecting device 6. Referring to FIG. 29, the state detection device 6 before falling asleep functions as a detection unit, and includes a processor 600 and the like. The processor 600 is connected to a memory 602, a pressure sensor 604, a wireless communication module 606, and the like.

  The processor 600 controls the operation of the pre-sleep state detector 6. The memory 602 includes a ROM and a RAM. In the ROM, a control program for controlling the operation of the pre-sleep state detector 6 is stored in advance. The RAM is used as a working memory or a buffer memory of the processor 600.

The pressure sensor 604 is, for example, a resistance wire type pressure sensor, and is built in the pillow so as to detect pressure when the head is placed on the pillow. In another embodiment, a sheet sensor that can detect the surface pressure may be employed as the pressure sensor. The wireless communication module 420 has substantially the same function as the wireless communication module 210 and the wireless communication module 420 described above, and transmits a pressure signal described later to the information processing device 4.

  When the pressure sensor 604 detects the pressure, the processor 600 of the pre-sleep state detecting device 6 determines that the user is in the pre-sleep state by placing his head on the pillow. At this time, the processor 600 transmits a pressure signal to the information processing apparatus 4 via the wireless communication module 606. Thus, in the second embodiment, the pressure sensor 604 is used to detect the user's pre-sleep state.

  FIG. 30 is an illustrative view showing one example of a configuration of an injection task table of the second embodiment. In the injection task of the second embodiment, “pressure sensor” can be set as a trigger task item. For example, when “pressure sensor” is stored as an event in the trigger column, the pre-sleep state is detected using the pressure sensor 604 of the pre-sleep state detection device 6, and the information processing device 4 outputs a pressure signal. Indicates that the scent component is jetted when received. When “pressure sensor” is stored in the trigger column, the set time is not stored in the set time column.

  Thus, in 2nd Example, a scent can be output at a suitable timing by detecting a user's state before sleep.

  In other embodiments, instead of the pressure sensor, various sensors such as an electroencephalograph, a heart rate monitor, and a camera, or a sleep onset estimating device may be used to detect sleep onset. For example, when an electroencephalograph is used in another embodiment, a scent is output from the olfactory display 10 when an electroencephalogram before sleep is measured by the electroencephalograph.

  In the second embodiment, the information processing apparatus 4 may be a so-called smartphone. In this case, history information such as season, time zone, and weather may be acquired using an application installed in the smartphone.

  In another embodiment, a pressure sensor 604 equipped with a small wireless communication module that supports ZigBee (registered trademark) wireless communication may be employed instead of the pre-sleep state detecting device 6.

  In other embodiments, the ZigBee method or the like may be employed for short-range wireless communication performed by the information processing device 4, the pre-sleep state detection device 6, and the olfactory display 10.

  The above has outlined the features of the second embodiment. This will be described in detail below using the memory map shown in FIG. 31 and the flowcharts shown in FIGS. 32 and 33.

  Referring to FIG. 31, in the data storage area 504 of the second embodiment, a wireless communication buffer in which a pressure signal received by wireless communication is temporarily stored with respect to the buffer and data of the first embodiment. 538 is further provided.

  FIG. 32 is a flowchart of the injection task creation process of the second embodiment. In addition, about the process (step) substantially equivalent to the process (step) performed by the injection task creation process of 1st Example, the same step number as 1st Example is attached | subjected and detailed description is abbreviate | omitted.

In step S1, the processor 400 determines whether or not a pattern item has been input. If “NO” in the step S1, that is, if no pattern item is input, the processor 400 repeats the process of the step S1. On the other hand, if “YES” in the step S1, that is, if a pattern item is input, the processor 400 sets an injection pattern based on the pattern item in a step S3. Subsequently, it is determined whether or not a set time is set in step S5. If “YES” in the step S5, that is, if the set time is set, the processor 400 creates an injection task by associating the injection pattern with the set time in a step S7. Then, when the process of step S7 ends, the processor 400 proceeds to the process of step S9.

  On the other hand, if “NO” in the step S5, that is, if the set time is not set, the processor 400 determines whether or not “pressure sensor” is set as a trigger in a step S61. That is, it is determined whether the scent is set to be output when the pre-sleep state is detected by the pre-sleep state detection device 6. If “NO” in step S61, that is, if the scent is not set to be output when the pre-sleep state is detected by the pre-sleep state detection device 6, the processor 400 returns to the process of step S5. On the other hand, if “YES” in the step S61, the processor 400 sets the trigger “in a scent when the pre-sleep state detection device 6 detects the pre-sleep state when the scent is output” in step S63. Create an injection task to be "pressure sensor". For example, an injection task whose trigger is “pressure sensor” as shown in FIG. 30 is created. The created injection task is stored in the injection task buffer 534. Then, when the process of step S63 ends, the processor 400 proceeds to the process of step S9.

  Since the processing after step S9 is substantially the same as that of the first embodiment, detailed description of the processing after step S9 is omitted.

  FIG. 33 is a flowchart of the injection task management process of the second embodiment. In addition, about the process (step) substantially equivalent to the process (step) performed by the injection task creation process of 1st Example, the same step number as 1st Example is attached | subjected and detailed description is abbreviate | omitted.

  In step S31, the processor 400 determines whether or not the current time matches the set time. If “YES” in the step S31, that is, if the current time matches the set time, the processor 400 acquires an injection task including the set time that matches the current time in a step S33. Then, when the process of step S33 ends, the processor 400 proceeds to the process of step S35.

  On the other hand, if “NO” in the step S31, that is, if the current time and the set time do not coincide with each other, the processor 400 determines whether or not the pressure signal is received in a step S81. That is, it is determined whether the pre-sleep state of the user has been detected by the pre-sleep state detection device 6. If “NO” in the step S81, that is, if the pre-sleep state is not detected and the pressure signal is not received, the processor 400 returns to the process of the step S41.

  If “YES” in the step S81, that is, if the pressure signal is received by detecting the state before falling asleep, the step S400 in the step S83 determines whether or not there is an injection task whose trigger is “pressure sensor”. Determine whether. That is, it is determined whether or not the injection task for which “pressure sensor” is set in the trigger task item is stored in the injection task table. If “NO” in the step S83, that is, if there is no injection task in which “pressure sensor” is set in the trigger task item, the processor 400 returns to the process of the step S31.

If “YES” in the step S83, that is, if there is an injection task in which “pressure sensor” is set in the trigger task item, the processor 400 selects an injection task in which the trigger task item is “pressure sensor” in a step S85. get. For example, an injection task in which “pressure sensor” is set in the task item of the trigger is read from the injection task table. Then, when the process of step S85 ends, the processor 400 proceeds to the process of step S35. Further, since the processing after step S35 is substantially the same as that of the first embodiment, detailed description of the processing after step S35 is omitted.

  In other embodiments, the contents of the injection task table may be integrated into the injection pattern table.

  Further, in the state pattern item, “work (study)” set when the user performs work (study), “rest” taken between studying, and the like may be stored. Further, when the state is set to “work”, the actual scent of the output scent is desirably lemongrass or bergamot that can be expected to increase the concentration. On the other hand, when the state is set to “break”, it is desirable that the actual scent of the output scent is a relaxing scent such as cypress or rosemary.

  In other embodiments, the aroma pattern DB 404 may be stored in a server. In this case, the information processing apparatus 4 acquires the data of the aroma pattern DB 404 from the server via the network.

  In another embodiment, the scent clock 100 may output a different scent every predetermined time (for example, one hour). As a result, in a single physical space such as a bedroom or entrance, a space with various images can be formed by changing the scent. For example, the entrance can be set to an “on mode” space with “fresh scent” in the morning time zone, and the entrance can be set to an “off mode” space with “scent of comfort” in the evening time zone.

  In addition, when a scent is used to obtain a masking effect in a toilet or the like, a single scent may cause adaptation (or fatigue) of human olfactory cells, and the scent may not be understood. However, if the scent clock 100 is used, different scents can be output every predetermined time in consideration of the olfactory adaptation as described above.

  Moreover, in another Example, the olfactory display 10 may be controlled so that the output of the scent ends at the set time.

  Further, the information processing device 4 and the olfactory display 10 may be configured as one device. In the second embodiment, when a sensor other than the pressure sensor 604 is connected to the pre-sleep state detecting device 6, if possible, the information processing device 4, the olfactory display 10, the pre-sleep state detecting device 6, and May be configured as one device.

Further, the plurality of programs described in the present embodiment are stored in the HDD of the data distribution server and distributed to the scent clock 100 (information processing apparatus 4) having the same configuration as that of the present embodiment via the network. Good. In addition, storage programs such as CDs, DVDs, and BDs (Blu-ray (registered trademark) Disc) are sold or distributed with these programs stored in storage media such as USB memory and memory card. May be. When the plurality of programs downloaded through the server and storage medium described above are applied to a system having the same configuration as that of this embodiment, the same effect as that of this embodiment can be obtained.

  The specific numerical values given in this specification are merely examples, and can be appropriately changed according to a change in product specifications.

DESCRIPTION OF SYMBOLS 4 ... Information processing apparatus 6 ... State-of-sleep detection apparatus 10 ... Olfactory display 14 ... Scent source cartridge 24 ... Cartridge storage chamber 26 ... Wind source 56 ... Piezoelectric element 76 ... Auxiliary wind source 100 ... Scent clock 200 ... Control circuit 400 ... Processor 402 ... Memory 404 ... Aroma pattern database 604 ... Pressure sensor

Claims (3)

A cartridge including an incense source is attached to each of a plurality of cartridge mounting locations, and a plurality of wind power sources provided individually corresponding to the plurality of cartridge mounting locations are provided, and the wind power source corresponds to the wind source. a fragrance timepiece using olfactory display that outputs Ri aroma from incense source in the cartridge by the fact jetting fragrance ingredient,
First storage means for storing an injection pattern table is provided, the injection pattern table having at least one injection ID, and corresponding to the injection ID, the aroma code indicating at least the scent component and the aroma code indicate Set an injection time indicating the time to inject the scent component, and
Second storage means for storing an injection task table in which at least a set time and an injection ID are set;
Determining means for determining whether the current time matches the set time of the injection task table; and
When the determination means determines that the current time coincides with the set time of the injection task table, the scent indicated by the aroma code indicated by the corresponding injection ID in the injection pattern table based on the injection ID of the injection task table A scent clock comprising control means for controlling the wind power source so that components are injected for the injection time . The injection pattern table sets a plurality of injection times indicating a time for injecting a scent component indicated by each of the plurality of aroma codes and the plurality of aroma codes for one injection ID,
When the determination unit determines that the current time coincides with the set time of the injection task table, the control unit indicates the injection ID corresponding to the injection pattern table based on the injection ID of the injection task table. 2. The scent clock according to claim 1 , wherein the plurality of wind power sources are controlled so that the plurality of scent components indicated by the plurality of aroma codes are sequentially ejected for the ejection time set correspondingly . A cartridge including an incense source is attached to each of a plurality of cartridge mounting locations, and a plurality of wind power sources provided individually corresponding to the plurality of cartridge mounting locations are provided, and the wind power source corresponds to the wind source. Using an olfactory display that outputs a scent by jetting a scent component from a scent source in a cartridge, and further comprising a first storage means for storing a jet pattern table, the jet pattern table having at least one jet ID Corresponding to the injection ID, at least an aroma code indicating the scent component and an injection time indicating a time for injecting the scent component indicated by the aroma code are set, and at least a set time and an injection ID are set. Executed by a scent clock computer comprising second storage means for storing an injection task table A scent watch program that, the computer,
Determining means for determining whether the current time matches the set time of the injection task table; and
When the determination means determines that the current time coincides with the set time of the injection task table, the scent indicated by the aroma code indicated by the corresponding injection ID in the injection pattern table based on the injection ID of the injection task table A scent clock program for causing a component to function as control means for controlling the wind power source so as to inject the component for the injection time .

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