WO2013111842A1 - Car active ingredient-generating device - Google Patents

Abstract

[Problem] To provide a car active ingredient-generating device: which has a configuration that can be made smaller so as to allow placement in an area of the car instrument panel that faces the interior of the car while also being capable of appropriately delivering air comprising the active ingredient, which has been generated by heating an active ingredient-generating member, into the interior of the car using the air stream of the car air conditioning device; and for which replacement of the active ingredient-generating member is also simple. [Solution] The car active ingredient-generating device (5) is configured so that: the device is disposed in an area of the instrument panel (1) that faces the interior of the car; a mat-shaped member (M) is detachably attached to an attachment part (28b) from an insertion port (7) on the interior side; by heating the mat-shaped member (M), which has been attached on the attachment part (28b) and faces the air flow channel (28a), using the radiator plate (17) of a PTC heater device(15) facing the mat-shaped member (M) on the side opposite to the air flow channel (28a) to generate the active ingredient, the active ingredient is vaporized into the air flowing in the air flow channel (28a); and air comprising the active ingredient is delivered from the air flow channel (28a) into the interior of the car via an expanded portion (7a) of the insertion port (7).

Description

Active ingredient generator for vehicles

The present invention is arranged in a part of an instrument panel of a vehicle such as an automobile facing a passenger compartment, and heats the effective component into the air by heating and air containing the active ingredient in the passenger compartment. The present invention relates to a device for sending out by using an air flow of the device.

In recent years, in order to keep the passenger compartment of automobiles and other vehicles comfortable, it has been demanded that various effective components such as aromatic components, aroma components, deodorant components, and insect repellent components are diffused in the air in the passenger compartment. However, placing a commercially available fragrance or deodorant container on the dashboard of the vehicle limits the visibility of the vehicle occupant, especially the driver, and creates a danger in driving the vehicle. In addition, the fragrance and deodorant components always fill the passenger compartment where the fragrance and deodorant components are relatively narrow and sealed from the fragrance and deodorant. It can be unnecessarily irritating and on the other hand uncomfortable for the vehicle occupant.

Accordingly, for example, Patent Documents 1 and 2 show a fragrance device for a vehicle that aims to supply a fragrance component into a vehicle compartment so as not to obstruct the field of view and uncomfortable for a vehicle occupant. As described above, a patent application has already been filed by the applicant of the present application.

The fragrance device for a vehicle shown in Patent Documents 1 and 2 is used for supplying the fragrance component to the air blown from the air outlet of the vehicle air conditioner and supplying it into the vehicle interior. Of the flow path, the end of the inlet pipe is connected to the downstream side of the air from the blower and the upstream side of the air from the evaporator, the air is taken into the vehicle fragrance device, and the air passing through the heater core and the air bypassing the heater core The end portion of the outlet pipe is connected to the downstream side of the air with respect to the portion where the air is mixed and the air containing the fragrance component is sent from the vehicle fragrance device into the air flow path of the vehicle air conditioner and the vehicle. It is said that it is possible to supply and stop the fragrance component into the room.

On the other hand, for the negative ion generator having a configuration in which a case body is fitted to a predetermined jack provided on an instrument panel of an automobile, for example, as shown in Patent Document 3, the applicant of the present application. A patent application has been made publicly known.

JP 2010-179786 A JP 2010-179787 A JP 2004-119233 A

However, the fragrance device for vehicles shown in Patent Documents 1 and 2 includes a storage space for storing fragrance, an air inflow opening, and an air fragrance holding container having an air outflow opening. A single actuator fixed to the main body, and a cam connected to the actuator to rotate the rotary shaft of the inlet path opening / closing door and the rotary shaft of the outlet path opening / closing door. The part is attached with the fragrance holding container, and an inlet path for flowing air to the air inflow opening, an outlet path for flowing out air containing fragrance components from the air outflow opening, and the air inflow opening And an outlet path opening / closing door for opening / closing the air outflow opening.

For this reason, the vehicle fragrance device disclosed in Patent Documents 1 and 2 is separate from the vehicle air conditioner, and is connected to the air flow path in the vehicle air conditioner via an inlet pipe and an outlet pipe. Since the overall external dimensions of the vehicular fragrance device are relatively large, there is a possibility of space saving of the vehicle in recent years, and there is a possibility that the mounting part to the vehicle becomes a problem. .

In addition, the fragrance device for vehicles shown in Patent Documents 1 and 2 generates a fragrance component from a fragrance and includes it in the air. Since the form to generate | occur | produce is taken, the opening / closing door which adjusts the presence or absence of the active ingredient from a fragrance | flavor is needed, and an apparatus enlarges.

Furthermore, although the fragrance device for vehicles shown in Patent Documents 1 and 2 can replace the fragrance holding container containing the fragrance, the attachment / detachment opening of the fragrance holding container is below the instrument panel. Therefore, the fragrance holding container cannot be replaced frequently, and is replaced about once a year, for example.

And in the said patent document 3, although it is shown using the existing recessed part space formed in the instrument panel of a motor vehicle as fitting parts, such as a fog lamp switch and an air-conditioner switch, it is accommodated in a recessed part space. Is a negative ion generator, and the configuration of a vehicle fragrance device that has a function of heating an active ingredient generating member by heat dissipation while being miniaturized so as to be housed in a recessed space formed in an instrument panel is disclosed. Absent.

Therefore, the present invention includes an effective component generated by heating an effective component generating member while being configured to be miniaturized so as to be disposed at a portion facing the vehicle interior of the vehicle instrument panel. It is an object of the present invention to provide an effective component generator for a vehicle in which air can be appropriately sent into the vehicle interior by using the air flow of the vehicle air conditioner and the effective component generating member can be easily replaced.

An active component generator for a vehicle according to the present invention is an active component generator for a vehicle for sending air containing an active component into an interior of a vehicle using an air flow of a vehicle air conditioner, The air conditioner is separate from the air conditioner, and is disposed at a position facing the room of the instrument panel. The first opening connected to the vehicle air conditioner, and the first opening opened to the room Two opening portions, an air flow path communicating the first opening portion and the second opening portion, a mounting portion for mounting an active ingredient generating member that generates an active ingredient by heating, A housing having a heat radiating means for heating the active ingredient generating member, wherein the active ingredient generating member is detachably attached to the mounting portion from an insertion opening opened in the chamber, and the active ingredient generating member is Generated by heating The active ingredient is characterized by evaporating into the air flowing through the air passage (claim 1). Here, the active ingredient refers to, for example, an aromatic component, an aroma component, a deodorant component, a pest repellent component, or the like. The active ingredient generating member refers to a mat-like member on which an active ingredient such as an aromatic component, an aroma component, a deodorant component, or a pest repellent component is supported. The first opening is for taking in air from the vehicle air conditioner, and the second opening is for sending air containing active ingredients into the vehicle interior. The first opening may be used for taking in air from the interior of the vehicle, and the first opening may be used for sending air containing an active ingredient into the vehicle air conditioner.

As a result, the effective component generated by heating the active component generating member with the heat radiating means is sent out of the housing from the second opening or the first opening through the air flow path. Therefore, it is possible to reduce the size of the instrument panel, so that the instrument panel can be placed in a position facing the vehicle interior. It will never be.
By stopping the air blower of the vehicle air conditioner, air is not taken into the air flow path of the vehicle effective component generator from the vehicle air conditioner via the first opening, so that the vehicle active component is generated. Air containing active ingredients is not sent out from the second opening of the apparatus. In addition, since the effective component is not generated from the effective component generating member by stopping the heat dissipation by the heat radiating means, the active component is not affected even if the air blower of the vehicle air conditioner is operating and air is flowing to the vehicle effective component generating device. Is not sent out into the vehicle interior.
Since the active ingredient generating member can be attached to and detached from the mounting portion through the insertion opening opened in the vehicle interior, the active ingredient generating member can be easily replaced. By extracting from the mounting portion, it is possible to stop the air containing the active component from being sent out into the vehicle interior.

In the vehicle active ingredient generator according to the present invention, the heat dissipating means is in contact with the active ingredient generator facing the air flow path on the side opposite to the air flow path ( Claim 2). Here, it is preferable that the heat dissipating means is in surface contact with the active ingredient generating member.

This prevents the heat radiating means from directly cooling the heat radiating means by exchanging heat with the air flowing through the air flow path when the heat radiating means faces the air flow path.

Furthermore, in the vehicle effective component generating apparatus according to the present invention, the heat dissipating means includes a heat radiating plate in contact with the effective component generating member and a PTC element in contact with the heat radiating plate from the side opposite to the active component generating member. It is a PTC heater device (Claim 3). Although the area of the PTC element is smaller than that of the heat sink, the active component generating member can be heated via the heat sink. Moreover, the active ingredient generation | occurrence | production member protrudes rather than the heat sink. Thereby, it is avoided that the site | part by the side of the insertion port of an active ingredient generation | occurrence | production member becomes high temperature, and since it becomes difficult for the passenger of a vehicle to pull out an active ingredient generation | occurrence | production member with a finger of a hand.

Furthermore, the PTC heater device has an electrode for supplying current to the PTC element, and the electrode is partly or entirely formed in a spring shape, and presses the PTC element against the heat radiating plate. (Claim 4). In the electrode according to the fourth aspect, a plate spring or a coil spring may be used, and the shape of the spring is not limited as long as the PTC element can be pressed against the heat radiating plate. The electrode is made of a material having lower heat conductivity than the heat radiating plate. For example, the heat radiating plate is made of aluminum and the electrode is made of stainless steel.
The electrode of the PTC heater device is formed in a leaf spring shape having a bent portion that protrudes toward the PTC element, and contacts the PTC element at the top of the bent portion to connect the PTC element to the heat radiating plate. It is good also as a characteristic to press on (claim 5). The electrode according to claim 5 is also made of a material having lower heat conductivity than that of the heat radiating plate. For example, the heat radiating plate is made of aluminum and the electrode is made of stainless steel.

Accordingly, the PTC heater device can make the contact between the heat dissipation plate and the PTC element more reliable and wide, and the electrode can relatively reduce the contact area with the PTC element. The generated heat is easily transmitted to the heat radiating plate, but can be prevented from being transmitted to the electrode as much as possible.

As described above, according to the first to fifth aspects of the invention, the vehicular active ingredient generator according to the present invention uses an active ingredient generating member heated by a heat dissipating means to Since the second opening or the first opening is sent out of the housing through the flow path, the number of necessary components can be relatively small, so that downsizing can be achieved. Since the instrument panel can be disposed in a portion facing the vehicle interior, it is possible to prevent the mounting portion on the vehicle from becoming a problem.

Moreover, according to invention of Claim 1-5, by stopping the air blower of a vehicle air conditioner, it is the 1st opening part from the air conditioner for vehicles to the air flow path of the active component generator for vehicles. The air can be prevented from being taken in via the air, so that the air containing the active ingredient can be stopped from being sent out from the second opening of the vehicle active ingredient generator. By stopping the heat dissipation, no effective component is generated from the effective component generating member. Therefore, even if the air blower of the vehicle air conditioner is operating and air is flowing through the vehicle effective component generating device, the air containing the effective component is It is possible to stop being sent into the room. Therefore, according to the invention described in claims 1 to 5, even if the vehicle active ingredient generator is installed in the vehicle, it is possible to stop the supply of the active ingredient into the vehicle interior. It is also possible to prevent the passenger of the vehicle from becoming uncomfortable due to the scent of the active ingredient.

Further, according to the first to fifth aspects of the present invention, since the active ingredient generating member can be attached to and detached from the mounting portion from the insertion opening opened in the interior of the vehicle, the active ingredient generating member can be simply used. Therefore, it is possible for the passenger of the vehicle to replace the active ingredient generating member according to the situation and mood. Moreover, even if the operation of the air blower of the vehicle air conditioner is not stopped or the heat dissipating action of the heat dissipating means is not stopped, the air containing the active component is only taken out from the mounting portion and the air containing the active component is Therefore, even if the vehicle active ingredient generator is installed in the vehicle, it is possible to stop the supply of the active ingredient into the vehicle interior.

In particular, according to the second aspect of the present invention, since the heat dissipating means faces the air flow path, it is possible to prevent the heat dissipating means from being directly cooled by exchanging heat with the air flowing through the air flow path. Thus, it is possible to prevent the heat dissipation capability of the heat dissipation means from being lowered.

In particular, according to the invention described in claims 3 to 5, the PTC heater device can make contact between the heat sink and the PTC element more reliably and in a wide range, and the electrode has a contact area with the PTC element. Since it can be made relatively small, heat can be easily transmitted from the PTC element to the heat radiating plate, whereas heat can be prevented from being transmitted to the electrode as much as possible. As a result, it is possible to prevent heat from being transmitted from the PTC heater device to locations other than the active ingredient generating member, and switches and other devices housed in the housing are affected by the heat from the PTC heater device. Can be prevented. In particular, in the invention described in claim 4, it is possible to freely select a spring having a shape capable of pressing a PTC element such as a leaf spring or a coil spring against the heat radiating plate as an electrode.

FIG. 1 is a schematic view showing an example in which an active component generator for a vehicle according to the present invention is mounted on a portion of an instrument panel facing a vehicle interior side. FIG. 2 shows a case where the vehicle active ingredient generator is arranged in the vertical direction as an example of the arrangement of the vehicle active ingredient generator, and a mat-like member is inserted in the insertion port of the vehicle active ingredient generator. It is the schematic which showed the dimension relationship between the aspect in which the is inserted, the active ingredient generator for vehicles, and the opening part opened to the vehicle interior side of the instrument panel. FIG. 3 is a perspective view showing an outer shape of the above-described vehicle active ingredient generator. FIG. 3 (a) is a perspective view showing a state seen from the insertion port side of the mat-like member, and FIG. 3 (b). These are perspective views which show the state seen from the connection part side with a vehicle air conditioner. 4 is a cross-sectional view showing an internal configuration of the above-described vehicle active ingredient generator. FIG. 4 (a) is a cross-sectional view showing the vehicle active ingredient generator as viewed from above the vehicle. b) is a cross-sectional view showing a state in which the vehicle active ingredient generator is viewed from the left-right direction of the vehicle. FIG. 5 is a cross-sectional view showing a state of an electrode, a heat sink, a base, and wiring extending from the base of the above-described vehicle active ingredient generator. FIG. 6 is an explanatory view showing a configuration of electrodes constituting the above-described vehicle active ingredient generator. FIG. 7 shows an example of a PTC heater device that constitutes the above-described vehicle active ingredient generator. A heat sink is in contact with the mat member, the PTC element is in contact with the heat sink, and the bent portion of the electrode is further in contact with the PTC element. It is the schematic by which the structure which the top part contact | connected was shown. FIG. 8 is an explanatory view showing a procedure for mounting the active component generator for a vehicle on the instrument panel from the side opposite to the vehicle interior side, and FIG. Fig. 8 (b) shows a state before the vehicle active ingredient generator is mounted from the opposite side, and Fig. 8 (b) shows the instrument panel after the vehicle active ingredient generator is mounted from the side opposite to the vehicle interior side. Shows the state. FIG. 9 shows a configuration for connecting a duct to a portion of the air flow path of the vehicle air conditioner that is downstream of the blower and taking air from the vehicle air conditioner into the vehicle active component generator. It is explanatory drawing which showed an example. FIG. 10 is an explanatory diagram illustrating a plurality of examples as the configuration on the end side of the duct when the duct is connected to the vehicle air conditioner. FIG. 11 is an explanatory view showing several examples of the structure for turning on / off the PTC heater device by attaching and detaching the mat-like member instead of the switch mechanism for manually pressing the button.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

In FIG. 1, an example of a driver seat side front portion S of a vehicle, in particular, a passenger car (right-hand drive vehicle) is displayed. In the driver seat side front portion S of the vehicle interior, an instrument panel 1 and A handle 2 is shown.

The instrument panel 1 is provided with a through-hole-shaped mounting portion 3 to which various devices such as a switch mechanism can be mounted in the vicinity of the handle 2, and a fog lamp switch used as an option. The attachment part 3 such as a mechanism is in a state where its opening is hidden by a dummy cover when not in use. In response to this, the vehicle active ingredient generator 5 according to the present invention includes, as shown in FIG. 2, a dummy cover or the like that covers the opening of the mounting portion 3 that is not used (for example, a mounting portion for a fog lamp switch). It is to be removed and attached.

As shown in FIGS. 2 and 3, the vehicle active ingredient generator 5 includes a housing 6 having a substantially rectangular parallelepiped outer shape so as to be accommodated in the mounting portion 3 in the vertical direction. It is configured. Further, the vehicle active ingredient generator 5 includes an insertion port 7 into which the mat member M shown in FIG. 2 can be inserted, and a button 8a of a switch 8 for turning on / off a PTC heater device 15 described later. 6 is connected to the air conditioning unit 100 of the vehicle air conditioner described later and connected to the other end of the duct 24 described later, and the wiring 20 and 21 described below are connected. For this purpose, a wiring lead-out port portion 10 is provided on the engine room side surface 6 b of the housing 6. That is, the connection port 9 functions as an opening for taking in air from the air conditioning unit 100 in this embodiment.

The mat member M is, for example, an aroma mat in which an aroma component is supported on a plate, and has a thin plate shape of, for example, 22 mm wide × 35 mm deep × 3 mm thick as shown in FIG. That is, this vehicle active ingredient generator 5 can use a commercially available aroma mat as it is. The mat-like member M slightly protrudes from the insertion port 7 in a state where the mat-like member M is mounted on the vehicle active ingredient generator, so that a vehicle occupant can easily pull the mat-like member M with his / her fingers. It has become.

The insertion port 7 basically has a rectangular shape that is substantially the same as the cross-sectional shape of the mat-like member M, and in this embodiment, the air containing the aroma component generated from the mat-like member M is introduced into the vehicle interior. It has an extended portion 7a which becomes an opening for feeding out. The extended portion 7a is extended to the side opposite to the switch button 8a (the side surface side of the housing 6) with respect to the basic rectangular portion of the insertion port 7 described above. The connection port portion 9 is a cylindrical one having a through hole, and the tip portion thereof is a bulging portion 9 a that bulges outward in the radial direction so that it is difficult to be detached from the duct 24 when inserted into the end portion of the duct 24. Have.

In this embodiment, as an opening for sending air generated from the mat-like member M into the interior of the vehicle, a rectangular basic portion substantially the same as the cross-sectional shape of the mat-like member M of the insertion port 7 is used. An extended portion 7a continuous on the side surface side of the housing 6 is shown, and this extended portion 7a is expanded by a longitudinal method having a relatively smaller longitudinal dimension than the basic portion of the insertion port 7. Although described, it is not necessarily limited to this. Although not shown, the shape of the extended portion 7a is the same as the longitudinal dimension of the basic portion of the insertion port 7 toward the side surface of the housing 6 with respect to the basic portion of the insertion port 7. Alternatively, instead of forming the extended portion 7a connected to the insertion port 7, an opening that is independent from the insertion port 7 may be provided.

The housing 6 is formed of a synthetic resin material such as plastic. In this embodiment, as shown in FIGS. 4 and 5, a housing body 11 having an opening opposite to the vehicle interior side, and a housing body 11 is configured by a lid body 12 constituting the engine room side face 6b by closing the opening of the engine room 11 and an interior member 13 housed in the housing body 11 by assembling a PTC heater device 15 to be described later.

As shown in FIGS. 4 and 5, in the housing 6, an air flow path 28 a, one of which communicates with the insertion port 7 having the expansion portion 7 a and the other of which is connected to the connection port 9, and the mat-like member M. The space portion 28 also serving as the mounting portion 28b, and the space portion 28 are formed with the housing body 11 itself, the interior member 13, and the storage portion 29 partitioned by the PTC heater device 15 assembled to the interior member 13. ing.

The space portion 28 is based on the shape of the insertion port 7 and the extended portion 7a. When the mat member M is mounted, the mat member M approaches the interior member 13 side as shown in FIGS. The air flow path 28a is provided between the mat-like member M and the inner surface of the outer wall portion constituting the outer shape of the housing main body 11. That is, the interior member 13 side area of the space portion 28 functions as the mounting portion 28 b of the mat member M.

The PTC heater device 15 includes a PTC element 16 that generates heat by supplying current, a heat radiating plate 17 that transmits heat generated by the PTC element 16 to the mat member M, and an electrode 18 for supplying current to the PTC element 16. At least, the current supply to the PTC element 16 is turned ON / OFF by the operation of the switch 8.

In this embodiment, the PTC element 16 has a thin disk shape, and is housed in a circular through hole 13a formed in the interior member 13 as shown in FIGS. On the space portion 28 side, the surface of the PTC element 16 is connected to the surface of the interior member 13 without a step, whereas on the storage portion 29 side, the surface of the PTC element 16 is recessed closer to the space portion 28 side than the surface of the interior member 13. In the position.

The heat radiating plate 17 is a thin, straight plate formed of a material having excellent heat conductivity and conductivity, for example, aluminum, and is disposed on the space 28 side of the interior member 13 so that the PTC element Further, when the mat-like member M is mounted, the side surface of the mat-like member M comes into contact with no gap. The heat radiating plate 17 also functions as an electrode on the other side for supplying a current to the PTC element 16, and is electrically connected to the wiring 19 extending from the power source side of the vehicle as shown in FIG. It is connected.

That is, the PTC element 16 is in contact with the heat radiating plate 17 in contact with the mat-like member M from the side opposite to the mat-like member M. The PTC element 16 has a smaller area than the heat radiating plate 17, The mat member M can be heated via the heat radiating plate 17. The mat member M protrudes further toward the insertion port 7 than the heat radiating plate 17. Accordingly, it is possible to avoid a situation in which a portion of the mat-like member M on the insertion port 7 side becomes hot and it becomes difficult for a vehicle occupant to pick up the mat-like member M from the insertion port 7 with a finger of a hand. it can.

And in order to hold | maintain the heat sink 17 and the mat-like member M which contact | connected this heat sink 17, as FIG. 5 shows, the interior member 13 has the outer wall side of the housing main body 11 from the surface at the heat sink 17 side. Ribs 13b and 13b are formed, and two types of ribs 11a and 11b are formed on the outer wall of the housing body 11 so as to extend from the inner surface to the heat radiating plate 17 side.

The ribs 13b and 13b of the interior member 13 are for preventing the interior member 13 from rattling in the vertical direction of the vehicle in this embodiment by interposing the interior member 13 therebetween. Further, the rib 11a of the housing body 11 extends to the surface of the heat radiating plate 17, and the heat radiating plate 17 is pressed between the inner member 13 and the inner member 13 so that the heat radiating plate 17 is a vehicle in this embodiment. , And the pressing force from the PTC element 16 to the heat radiating plate 17 is supported. The rib 11b of the housing body 11 is slightly shorter than the rib 11a, and the length of the rib 11a is configured to be shorter than the dimension obtained by adding the length of the rib 11b and the thickness of the mat member M. When the mat-like member M is inserted through the insertion port 7 in a press-fit manner, the leading end of the rib 11b extends to a position where the side surface of the mat-like member M can be pushed. The mat member M inserted from the side is pressed to the heat radiating plate 17 side, and in this embodiment, the mat member M is prevented from rattling in the left-right direction of the vehicle, and the mat member M and the heat radiating plate 17 are in contact with each other. Has been increased.

In this way, the mat-like member M is prevented from rattling by pressing a portion that is relatively narrow with respect to the side surface of the mat-like member M on the air flow path 28a side at the tip of the rib 11b. Since the mat member M is not pressed over a relatively large area with respect to the side surface on the air flow path 28a side, many areas of the side surface on the air flow path 28a side are opened, and air is passed from the side surface of the mat member M. The active ingredient is easily evaporated toward the flow path 28a.

The electrode 18 is made of a material having conductivity and relatively low thermal conductivity, for example, stainless steel, and extends from the base 22 housed in the housing portion 29 as shown in FIG. The wiring 20 is electrically connected. The base 22 is electrically connected to the switch 8 as shown in FIG. 4B and is also electrically connected to the wiring 21 extending from the power source side of the vehicle. Further, the electrode 18 is in partial contact with the PTC element 16 as will be described later.

Although the switch 8 is not shown so that the button 8a of the switch 8 can be seen even in a dark environment such as at night or in a tunnel, a light source such as an LED is housed inside the switch 8 and the switch 8 A transparent material or the like may be used on the surface exposed from the housing 6 of the button 8a so that the button 8a of the switch 8 can be illuminated by the light from the light source.

According to such a configuration of the PTC heater device 15, the switch 8 is turned on by pressing the button 8 a of the switch 8 with a finger or the like of the passenger's hand, and is disposed between the electrode 18 and the heat radiating plate 17. Since a current is supplied to the PTC element 16 from the power source of the vehicle, the PTC element 16 generates heat, and the heat of the PTC element 16 is transmitted to the heat radiating plate 17 and radiated from the heat radiating plate 17 to the mat member M. The mat member M is heated, and the aroma component is evaporated from the mat member M into the air flowing through the air flow path 28a of the space 28. Then, when the button 8a of the switch 8 is pressed again with the finger of the passenger's hand, the switch 8 is turned off, and the vehicle power supply to the PTC element 16 disposed between the electrode 18 and the heat radiating plate 17 is turned off. Current supply is interrupted and heat generation of the PTC element 16 is stopped, so that the mat member M is also not heated by the heat radiating plate 17, so that the aroma component flows from the mat member M through the air flow path 28 a of the space portion 28. Evaporation into the air can be stopped.

In the PTC heater device 15, the electrode 18 has such a form that the heat from the PTC element 16 is hardly transmitted to the electrode 18 as much as possible. The form of this electrode 18 is demonstrated using FIG.6 and FIG.7.

As shown in FIG. 6, the electrode 18 is composed of a plate portion 18a and a wiring connection portion 18b, and the wiring connection portion 18b is erected from the side surface of the plate portion 18a. Then, as shown in FIG. 6A, the plate portion 18a has two parallel cutouts extending along the longitudinal direction of the plate portion 18a and the plate portion 18a so that the cutouts communicate with each other. By making a through hole 30 consisting of one notch extending along the short side direction, the three sides are released from the other part of the plate part 18a, and the released part is bent to the PTC element 16 side. The leaf spring portion 31 having the top portion 31a protruding toward the PTC element 16 is provided.

By using the electrode 18 having such a plate spring portion 31, the electrode 18 presses the PTC element 16 toward the heat radiating plate 17 at the top portion 31a of the plate spring portion 31, as shown in FIG. 16 and the heat radiating plate 17 can be satisfactorily contacted, and since the electrode 18 is in contact with the PTC element 16 only at the top 31a of the leaf spring portion 31, current is supplied to the PTC element 16. While the PTC element 16 can generate heat, heat is hardly transmitted from the PTC element 16 to the electrode 18.

As shown in FIG. 4B, the storage portion 29 stores the switch 8, the temperature sensor 23, and the like, while the electrode 18 faces the storage portion 29. In order to prevent the switch 8 and the temperature sensor 23 from being affected even if heat is transmitted to the electrode 18, the partition walls 25 and 26 provide a storage portion 29b facing the electrode 18 on the vehicle rear side portion, The switch 8 and the temperature sensor 23 are partitioned into storage portions 29a and 29c.

Next, an example of the configuration and procedure for mounting the vehicle active ingredient generator 5 to the mounting portion 3 of the instrument panel 1 will be described with reference to FIG.

In this embodiment, the vehicle active ingredient generator 5 has a vehicle lateral dimension that is smaller than an inner dimension of the mounting portion 3 in the vehicle lateral direction, and a driver seat side front portion S side of the mounting portion 3. The opening 3a is substantially the same as the inner dimension in the vehicle left-right direction. That is, the inner dimension of the opening 3a of the attachment portion 3 in the vehicle left-right direction is greater than the inner dimension of the attachment portion 3 in the vehicle left-right direction by projecting the flanges 1a, 1b in the directions close to each other. Is also getting smaller. In the vehicle active ingredient generator 5, the housing 6 is provided with projections 5a and 5b that come into contact with the inner surfaces of the flanges 1a and 1b.

Further, the vehicle active ingredient generator 5 has projections 5c and 5d having a triangular cross section on the housing 6 on the front side of the vehicle with respect to the projections 5a and 5b. The projections 5c and 5d are attached to the housing 6. The cross section formed in the part 3 is engageable with the triangular protrusions 3b and 3c. That is, the protrusions 5c and 5d of the vehicle active ingredient generator 5 are right-angled triangles with the vehicle rear side surface being an inclined surface and the vehicle front side surface being an upright surface. 3c is a right triangle in which the rear surface of the vehicle is an upright surface and the front surface of the vehicle is an inclined surface, and the amount of protrusion of the protrusions 5c and 5d of the vehicle active component generator 5 and the mounting portion 3 The protruding amounts of the protruding portions 3b and 3c are the same. The protrusions 5a, 5b, 5c, and 5d of the vehicle active ingredient generator 5 and the protrusions 3b and 3c in the attachment portion 3 are deformed so that the shape thereof is contracted in the vehicle left-right direction or tilted in the vehicle front-rear direction. It has a certain degree of elasticity so that it is possible.

As a result, as shown in FIG. 8 (a), the vehicle active ingredient generator 5 is first inserted into the mounting portion 3 provided on the instrument panel 1 from the front side of the vehicle. 5, the protrusions 5a and 5b get over the protrusions 3b and 3c in the attachment part 3. Next, as shown in FIG. 8B, the protrusions 5a and 5b are flanges of the opening 3a of the attachment part 3. The bumps 1a and 1b abut, and the protrusions 5c and 5d of the vehicle active ingredient generator 5 also get over the protrusions 3b and 3c, and the rising surfaces of the protrusions 5c and 5d and the protrusions 3b and 3c Abut. However, the vehicle active ingredient generator 5 is restricted from moving rearward of the vehicle by the engagement of the flanges 1a, 1b and the projections 5a, 5b, and the engagement between the projections 3b, 3c and the projections 5c, 5d. Since the movement to the front side of the vehicle is restricted by this, it can be mounted in the mounting portion 3 without rattling.

Furthermore, a configuration for flowing air through the air flow path 28a of the vehicle active component generator 5 using the air flow of the air conditioning unit 100 of the vehicle air conditioner will be described with reference to FIG.

The air conditioning unit 100 shown in FIG. 9 is an example of an air conditioning unit to be used, and is a vertically integrated type with a central center, and basically includes an air conditioning unit body 100a and an intake portion 100b. It is configured.

The air conditioning unit main body 100a is sent to the air flow path 102 formed in the casing 101 by the blower 105 for sending the air introduced from the inlet 103 of the intake portion 100b to the downstream side, and the blower 105. The cooling heat exchanger 106 such as an evaporator for cooling the air, the air filter 104 disposed upstream of the cooling heat exchanger 106, and the air cooled by the cooling heat exchanger 106 are recycled. A hot water heater 108 for heating, an electric heater 109 and an air mix door 110 for adjusting the mixing ratio of the air heated by these heaters 108 and 109 in the air mix chamber 102a are accommodated.

Further, in the air conditioning unit main body 100a, the defrost blowing opening 114, the vent blowing opening 115, and the foot blowing opening 116 are provided in the casing 101 on the downstream side of the air from the air mix chamber 102a of the air flow path 102. A blow mode switching door 111 that is appropriately opened and adjusts the flow rate of air toward the defrost blow opening 114 and the vent blow opening 115, and a vehicle on the downstream side of the air from the blow mode switching door 111 and the vehicle. On the upper side, from the blowing mode switching door 112 that adjusts the ratio of the flow rate of air sent from the defrost blowing opening 114 and the flow rate of air sent from the vent blowing opening 115, and the foot blowing opening 116 A blowing mode switching door 113 for adjusting the flow rate of the air to be sent is installed respectively. Has become a thing was.

In the air conditioning unit 100 having such a configuration, a through hole 118 is provided at a position that becomes the air flow path 102 between the blower 105, the air filter 104, and the air mix door 110 with respect to the casing 101 of the air conditioning unit main body 100a. One end of the duct 24 is connected to the through hole 118, and the other end is connected to the connection port portion 9 of the vehicle active ingredient generator 5.

Thus, by operating the blower 105 of the air conditioning unit 100, the air taken into the air flow path 102 of the air conditioning unit 100 by the blower 105 passes through the duct 24 and the connection port 9 from the through hole 118 provided in the casing 101. After the aroma components generated from the mat member M are sent to the air flow path 28a of the vehicle active ingredient generator 5 and flow through the air flow path 102, the air containing the aroma components is transferred to the vehicle. It is sent out into the room from the expanded portion 7a of the insertion port 7 of the active ingredient generator 5 for use.

Here, as a structure for connecting one end of the duct 24 to the through hole 118 of the casing 101 of the air conditioning unit 100, for example, as shown in FIG. A locking portion 24a extending outward in the diagonal direction toward the active ingredient generating device 5 side, and an outer side in the diagonal direction from the vehicle active component generating device 5 side toward the distal end side of the duct 24 relative to the locking portion 24a of the duct 24 And a pressing portion 24b extending in the direction. Thereby, since the opening peripheral part of the through-hole 118 of the casing 101 is clamped with the latching | locking part 24a and the holding | suppressing part 24b, it can prevent that the front-end | tip of the duct 24 pulls out from the through-hole 118 of the casing 101 easily. .

Further, as a structure in which one end of the duct 24 is connected to the through hole 118 of the casing 101 of the air conditioning unit 100, for example, as shown in FIG. A cylindrical portion 33 that protrudes outward is mounted, and the tip of the duct 24 is used as a small diameter portion 24c having an outer diameter that is substantially the same as the inner diameter of the cylindrical portion 33, and the small diameter portion 24c of the duct 24 is inserted into the cylindrical portion 33. It has become. Thereby, the duct 24 can be connected to the through hole 118 of the casing 101 with a simple structure.

By the way, although it has been described that when the PTC heater device 15 is turned on / off in the vehicle active ingredient generator 5, it is performed by the operation of the passenger pressing the button 8a of the switch 8, it is not necessarily limited to this. For example, the PTC heater device 15 may be turned on / off by the operation of inserting the mat member M from the insertion port 7 and taking it out from the insertion port 7.

A plurality of examples of the structure for turning on / off the PTC heater device 15 by the operation of inserting and removing the mat-like member M from the insertion port 7 will be described with reference to FIGS. 11 (a) to 11 (d).

In the embodiment shown in FIG. 11 (a), a switch 8 is housed in the housing 6 of the vehicle active ingredient generator 5. The switch 8 is connected to the pressed portion 34 and the switch 8 and is connected to the vehicle. And a lever 35 that swings in the front-rear direction. The lever 35 is biased in a direction away from the pressed portion 34.

As a result, the mat member M is inserted into the housing 6 from the insertion port 7 and the lever 35 is pushed in the direction of the white arrow (the front side of the vehicle) in FIG. The switch 8 is turned ON by pressing 34, and as a result, heating of the mat-like member M by the PTC heater device 15 is started. On the other hand, by pulling out the mat-like member M from the insertion port 7, the lever 35 is separated from the pressed portion, so that the switch 8 is turned off and the heating of the mat-like member M by the PTC heater device 15 is stopped. Is done.

Also in the embodiment shown in FIG. 11B, the switch 8 is housed in the housing 6 of the vehicle active ingredient generator 5, and the switch 8 has a switch button 36 for switching ON / OFF. . The switch button 36 is set to turn on the switch 8 by being pushed to the front side of the vehicle, and to return to the OFF state when not pushed to the front side of the vehicle.

As a result, the mat-like member M is inserted into the housing 6 from the insertion port 7, and the switch 8 is turned on by pushing the switch button 36 in the direction of the white arrow in FIG. 11B (front side of the vehicle). Thus, heating of the mat-like member M by the PTC heater device 15 is started. On the other hand, by pulling out the mat-like member M from the insertion port 7, the pressing of the switching button 36 toward the front side of the vehicle is released, so that the switch 8 is turned OFF, and consequently the mat-like member by the PTC heater device 15. Heating to M is stopped.

In the embodiment shown in FIG. 11 (c), the structure of the PTC heater device 15 is devised to function as a switch. That is, a bending member 37 that is bent on the same side as the leaf spring portion 31 of the electrode 18 is accommodated on the insertion port 7 side of the electrode 18 having the PTC element 16 and the leaf spring portion 31 in the housing 6. The bending member 37 is housed in the housing 6 separately from the electrode 18 and separated from the electrode 18. The heat radiating plate 17 is swingable about the top portion 37a of the bending member 37, while the position of the fulcrum supporting the heat radiating plate 17 is shifted to the front side of the vehicle from the center of the heat radiating plate 17 in the vehicle front-rear direction. In the state where the mat member M is not in contact with the heat radiating plate 17, the heat radiating plate 17 is separated from the PTC element 16.

Thus, the mat-like member M is inserted into the housing 6 from the insertion port 7 and the mat-like member M pushes the heat radiating plate 17, so that the heat radiating plate 17 uses the top portion 37a of the bending member 37 as a fulcrum. ) Swings in the direction of the white arrow, so that the heat radiating plate 17 contacts the PTC element 16, so that a current is supplied to the PTC element 16 and the PTC heater device 15 is turned on. Heating to M is started. On the other hand, by pulling out the mat-like member M from the insertion port 7, the state where the heat radiating plate 17 is pressed by the mat-like member M is released, so that the heat radiating plate 17 moves away from the PTC element 16 (FIG. 11). (C) (in the direction opposite to the white arrow), the current is not supplied to the PTC element 16, the PTC heater device 15 is turned off, and the mat member M is heated by the PTC heater device 15. Stopped.

In the embodiment shown in FIG. 11 (d), a switch 8, which is a pressing operation type two-stage switch, is housed in the housing 6 of the vehicle active ingredient generator 5. This push-operation type two-stage switch sequentially turns the switch on and off by a push operation in one direction. However, since the configuration itself is known, the description thereof is omitted.

As a result, the mat-like member M is inserted into the housing 6 from the insertion port 7 and pressed against the switch 8 which is a two-stage switch, so that the switch 8 is turned on, and consequently the PTC heater device 15 Heating to the mat member M is started. Then, the mat member M is again inserted into the housing 6 from the insertion port 7 and pressed against the switch 8 which is a two-stage switch, so that the switch 8 is turned OFF, and as a result, the PTC heater. Heating of the mat member M by the device 15 is stopped.

Heretofore, the embodiment in which the vehicle active ingredient generator 5 is arranged in the vertical direction as shown in FIG. 2 has been described, but the mat-like member M housed in the vehicle active ingredient generator 5 is Since the vehicle active ingredient generator 5 is in contact with the heat radiating plate 17 so that there is no backlash regardless of the posture, the vehicle active ingredient generator 5 may be placed on its side depending on the installation environment. It is also possible to arrange them diagonally.

DESCRIPTION OF SYMBOLS 1 Instrument panel 3 Mounting part 5 Vehicle active component generator 6 Housing 7 Insertion port 7a Expansion part 8 Switch 8a Button 9 Connection port 15 PTC heater device 16 PTC element 17 Heat sink 18 Electrode 19 Wiring 20 Wiring 21 Wiring 22 Base 24 duct 28 space portion 28a air flow path 29 storage portion 31 leaf spring portion 31a top portion 33 cylindrical portion 34 pressed portion 35 lever 36 operation button 37 bending member 37a top portion 100 air conditioning unit of vehicle air conditioner 101 casing 102 air flow path 104 Air filter 105 Blower 106 Evaporator S Front portion of driver's seat inside vehicle interior M Matte member

Claims (5)

1. An active component generator for a vehicle for sending air containing an active component into the vehicle interior using the airflow of the vehicle air conditioner,
   The vehicle air conditioner is separate from the vehicle air conditioner and is disposed at a position facing the room of the instrument panel.
   A first opening connected to the vehicle air conditioner; a second opening opened in the room; an air flow path communicating the first opening and the second opening; And a housing having a mounting portion for mounting an active ingredient generating member that generates an active ingredient by heating, and a heat radiation means for heating the active ingredient generating member,
   The active ingredient generating member is detachably attached to the mounting portion from the insertion opening that opens in the room, and the active ingredient generated by heating the active ingredient generating member is transpired into the air flowing through the air flow path. An active ingredient generator for a vehicle, characterized in that
2. 2. The vehicle effective component generator according to claim 1, wherein the heat dissipating means is in contact with the active component generating member facing the air flow path on the side opposite to the air flow path.
3. 2. The PTC heater device according to claim 1, wherein the heat radiating means is a PTC heater device having a heat radiating plate in contact with the effective component generating member and a PTC element in contact with the heat radiating plate from the side opposite to the active component generating member. The vehicle active ingredient generator according to claim 2.
4. The PTC heater device has an electrode for supplying a current to the PTC element, and the electrode is partly or entirely formed in a spring shape and presses the PTC element against the heat radiating plate. The active ingredient generator for vehicles according to claim 3 characterized by things.
5. The electrode of the PTC heater device is formed in a leaf spring shape having a bent portion protruding toward the PTC element, and contacts the PTC element at the top of the bent portion and presses the PTC element against the heat radiating plate. The active ingredient generator for vehicles according to claim 4 characterized by things.

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