JP7129297B2 - vehicle air conditioner - Google Patents

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vehicle air conditioner that is arranged on the ceiling of a vehicle and used for air conditioning in the vehicle interior.

2. Description of the Related Art Conventionally, as a vehicle air conditioner, there is known one that is arranged on the ceiling of a vehicle and configured to supply blown air from the ceiling to the vehicle interior. The invention described in Patent Document 1 is known as a technique related to such a vehicle air conditioner.

The vehicle air conditioner of Patent Document 1 is arranged in the ceiling, and is configured to cool the air taken in by the operation of the fan with an evaporator and blow the air into the vehicle interior from the ceiling side.

JP-A-9-207550

Here, in recent years, it is desired to secure a large living space in a vehicle. In order to meet this demand, it is necessary to reduce the size in the vertical direction as much as possible in the vehicle air conditioner described in Patent Document 1. It is expected that the vertical dimension of the air outlet of the vehicle air conditioner will be reduced in order to meet the demand for securing a living space.

Further, in order to improve the comfort of passengers, it is desirable that the vehicle air conditioner can blow air to a desired location in the vehicle even if the vertical dimension of the air outlet is small.

For example, in the vehicle air conditioner described in Patent Document 1, a plurality of blowout louvers (guide members) are rotatably arranged inside the blowout port. It is configured to adjust the flow of blown air in any direction in the horizontal direction. Therefore, even if the vertical dimension of the air outlet is reduced, it is necessary to improve the operability of adjusting the wind direction of the blown air.

The present invention has been made in view of these points, and relates to a vehicle air conditioner that is arranged on the ceiling of a vehicle, and is capable of improving the operability of adjusting the wind direction while securing a living space of the vehicle. An object of the present invention is to provide an air conditioner for

In order to achieve the object, the vehicle air conditioner according to claim 1 comprises:
an air-conditioning case (10) arranged in the ceiling (R) of the compartment (I) and having a suction port (16) through which the air inside the compartment is sucked;
a blower (20) housed inside the air-conditioning case for blowing the air inside the air-conditioning case;
It is formed in a flat shape with a short vertical direction and extends in a predetermined first direction. and a blowout port (45) that blows out to the inside of the
The blow-out passage is
an upper wall portion (47) forming the upper side of the blowout passage and extending at an angle so as to be positioned downward toward the downstream side in the flow direction of the blown air passing through the blowout passage;
a lower wall portion (48) arranged at a distance below the upper wall portion and extending downward toward the downstream side in the flow direction of the blown air;
The lower end of the upper wall is horizontally aligned with the lower end of the lower wall,
The upper wall portion has a covered portion (47a) whose lower side of the upper wall portion is covered by the lower wall portion, and an exposed portion (47b) below the covered portion where the lower side of the upper wall portion is exposed. has
A guide member (50) is disposed inside the blow-out passage for adjusting the flow of air blown from the blow-out port in the second direction by rotating in the second direction intersecting the first direction,
The guide member has, at a position facing the exposed portion of the upper wall portion, an operation portion (52) used for a rotating operation in the second direction, and a support portion arranged at the exposed portion of the upper wall portion. (55) is rotatably supported in the second direction,
The support portion supports the guide member at a position biased toward the operation portion with respect to the entire guide member .

According to the vehicle air conditioner, the blower is operated inside the air conditioning case arranged on the ceiling of the passenger compartment, so that the air sucked from the suction port is blown out from the blower outlet to the inside of the passenger compartment. It is possible to improve the comfort inside the passenger compartment.

Further, according to the vehicle air conditioner, since the air outlet portion is formed in a flat shape that is short in the vertical direction, the size of the entire device in the vertical direction can be reduced, and the living space in the passenger compartment can be widened. can be secured.

In the vehicle air conditioner, the guide member is arranged rotatably in the second direction inside the blowout passage of the blowout port formed in a flat shape with a short vertical direction. For this reason, the vehicle air conditioner can adjust the flow of the blown air blown out from the blower outlet in the second direction even when the blower outlet is formed in a flat shape with a short vertical direction. A ventilation mode desired by the passenger can be realized in the second direction.

In the vehicle air conditioner, the operation portion of the guide member is arranged at a position facing the exposed portion of the upper wall portion. For this reason, according to the vehicle air conditioner, even if the air outlet portion is formed in a flat shape that is short in the vertical direction, the occupant in the passenger compartment can easily access the operation portion of the guide member from below. can be done.

Thereby, the vehicle air conditioner can improve the operability of the guide member in the second direction, and can accurately adjust the wind direction in the second direction inside the vehicle compartment.

Further, in the vehicle air conditioner, the operating portion of the guide member is arranged above the lower ends of the upper and lower wall portions and below the exposed portion of the upper wall portion by effectively utilizing the dead space. For this reason, according to the vehicle air conditioner, it is possible to contribute to miniaturization in the vertical direction also from the viewpoint of the operating portion of the guide member.

It should be noted that the reference numerals in parentheses of each means described in this column and claims indicate the correspondence with specific means described in the embodiments described later.

BRIEF DESCRIPTION OF THE DRAWINGS It is a top view of the vehicle air conditioner which concerns on one Embodiment. It is a schematic diagram which shows the vehicle mounting position of the vehicle air conditioner which concerns on one Embodiment. BRIEF DESCRIPTION OF THE DRAWINGS It is a front view of the vehicle air conditioner which concerns on one Embodiment. BRIEF DESCRIPTION OF THE DRAWINGS It is a side view of the vehicle air conditioner which concerns on one Embodiment. It is a bottom view of the vehicle air conditioner which concerns on one Embodiment. FIG. 3 is a cross-sectional plan view showing the flow of blown air inside the vehicle air conditioner. FIG. 2 is a cross-sectional view showing a VII-VII cross section in FIG. 1; It is an external appearance perspective view of the flap in a vehicle air conditioner. FIG. 2 is a sectional view showing the IX-IX section in FIG. 1; Fig. 2 is an enlarged cross-sectional view of an air outlet portion of the vehicle air conditioner; It is explanatory drawing which shows the rotation range of the guide member arrange|positioned at the right side part of a vehicle air conditioner. It is explanatory drawing which shows the rotation range of the guide member arrange|positioned at the left side part of a vehicle air conditioner.

Embodiments will be described below with reference to the drawings. In the following embodiments, parts that are the same or equivalent to each other are given the same reference numerals in the drawings.

First, a schematic configuration of a vehicle air conditioner according to the present embodiment will be described with reference to the drawings. In the following description, when the front, rear, left, right, up, and down directions are used, the front, rear, left, right, up, and down directions as seen from the passenger seated on the seat are indicated. The same definition is used for arrows appropriately shown in each drawing, and the vehicle width direction corresponds to the left-right direction.

First, the outline of the vehicle air conditioner 1 according to the present embodiment will be described. As shown in FIGS. 1 and 2, the vehicle air conditioner 1 is arranged on the ceiling portion R of the vehicle compartment I in order to make the inside of the vehicle compartment I of the vehicle C a comfortable air-conditioned environment. The air blower 20, the evaporator 70, etc. are accommodated in 10 inside.

An air intake port 16 and an air outlet portion 45 are arranged in the air conditioning case 10 of the vehicle air conditioner 1 , and communicate with the inside of the vehicle compartment I, respectively. Therefore, the vehicle air conditioner 1 sucks the air in the vehicle interior I from the suction port 16 into the air conditioning case 10 by the operation of the blower 20, and converts it into the blowing air F whose temperature is adjusted by the evaporator 70. 45 to the passenger compartment I.

As shown in FIG. 2, a vehicle air conditioner 1 according to the present embodiment is mounted on a so-called minivan type vehicle C with three rows of seats. In a vehicle compartment I of the vehicle C, a first row seat Sa, a second row seat Sb and a third row seat Sc are arranged in this order from the front to the rear of the vehicle.

In the vehicle C, the first row seats Sa are configured as a driver's seat and a passenger's seat. The second-row seats Sb and the third-row seats Sc are, for example, bench-type seats on which a plurality of passengers can sit.

The third-row seat Sc is arranged closer to the center side in the vehicle width direction than the second-row seat Sb in relation to the arrangement space for the rear wheels of the vehicle C. As shown in FIG. Therefore, the seating position of the third row seat Sc is positioned between the seating positions of the second row seat Sb in the lateral direction of the vehicle.

As shown in FIG. 2, the vehicle air conditioner 1 is arranged behind the first-row seats Sa and in front of the second-row seats Sb in the ceiling portion R of the vehicle compartment I. positioned. The vehicular air conditioner 1 operates according to the operation of an operation panel arranged near the second row seat Sb and the third row seat Sc. It is configured to provide air conditioning.

The vehicle air conditioner 1 is mainly operated by an occupant P seated on the second row seat Sb or the third row seat Sc, and is used to improve the comfort of the occupant P on the rear side of the vehicle compartment I. . In other words, the occupants of the second row seat Sb and the third row seat Sc can perform the air conditioning operation of the vehicle air conditioner 1 without involving the occupant P in the driver's seat or the front passenger seat.

Next, a specific configuration of the vehicle air conditioner 1 according to the present embodiment will be described in detail with reference to FIGS. 1 to 5. FIG. FIG. 1 shows a top view of a vehicle air conditioner 1, and FIG. 3 shows a front view of the vehicle air conditioner 1. As shown in FIG. FIG. 4 shows a side view of the vehicle air conditioner 1, and FIG. 5 shows a bottom view of the vehicle air conditioner 1. As shown in FIG.

As described above, the vehicle air conditioner 1 includes the blower 20 and the evaporator 70 forming part of the vapor compression refrigeration cycle inside the air conditioning case 10 arranged on the ceiling portion R of the vehicle C. Constructed to contain.

As shown in FIGS. 1 and 3 to 5, the air conditioning case 10 includes an upper case 11 forming an upper shell of the vehicle air conditioner 1 and a lower shell of the vehicle air conditioner 1. It is composed of a lower case 13 that The upper case 11 and the lower case 13 are assembled with screws or the like.

A plurality of upper fixing portions 12 are symmetrically formed on the upper case 11 . The upper fixing portion 12 is used when fixing the air conditioning case 10 to an upper vehicle body member in the ceiling portion R of the vehicle C. As shown in FIG.

As shown in FIG. 1 and the like, a fan accommodating portion 15 is arranged in the central portion of the air conditioning case 10 in the vehicle width direction. The fan accommodating portion 15 constitutes a vehicle rear side portion of the air conditioning case 10, and accommodates the blower 20 therein. Further, as shown in FIG. 5, a suction port 16 is formed in the lower surface of the fan accommodating portion 15, and the interior of the air conditioning case 10 and the fan accommodating portion 15 and the interior of the vehicle compartment I are communicated.

The blower 20 is arranged inside the fan accommodating portion 15 so as to face the suction port 16 , sucks air in the vehicle interior I through the suction port 16 , and blows the air into the air conditioning case 10 as blown air F.

The blower 20 is arranged inside the fan accommodating portion 15 by being fixed to a vehicle body member (for example, a roof reinforcement) in the ceiling portion R. As shown in FIG. The blower 20 is an electric blower in which an electric motor 21 drives a centrifugal multi-blade fan (that is, a sirocco fan). A centrifugal multi-blade fan has a substantially cylindrical shape and has a large number of blades radially outward.

As shown in FIGS. 3 to 5, the electric motor 21 constitutes a lower portion of the blower 20 and has a drive shaft extending along the vertical direction of the vehicle. The centrifugal multi-blade fan is fixed to the drive shaft of the electric motor 21 .

Therefore, by operating the electric motor 21, the blower 20 can blow out the air sucked into the axial core portion of the centrifugal multi-blade fan through the suction port 16 radially outward. The rotational speed (blowing air volume) of the centrifugal multi-blade fan in blower 20 is controlled by a control voltage output from an air conditioning control device (not shown).

As shown in FIG. 1 and the like, an air blowing port 25 is formed on the vehicle front side of the fan accommodating portion 15 . The blower port 25 is a portion that is blown out from the fan accommodating portion 15 when the air sucked from the suction port 16 is blown as the blown air F by the operation of the blower 20 . The blower port 25 is a part for supplying the blowing air F flowing inside the air conditioning case 10 .

The vehicle air conditioner 1 has a first air passage 30 , a second air passage 35 , and a third air passage 40 in addition to the fan accommodating portion 15 . The first air passage 30 , the second air passage 35 , and the third air passage 40 function as flow paths for the air F blown through the air blow port 25 .

The first air passage 30 is formed inside the air conditioning case 10 of the vehicle air conditioner 1 so as to extend toward the front side of the vehicle from the air outlet 25 formed in the fan accommodating portion 15 . Therefore, the blown air F blown from the blow port 25 flows inside the first air passage 30 to the front side of the vehicle.

A rib 31 is arranged on the front side of the vehicle inside the air conditioning case 10 . As shown in FIGS. 6 and 7, the upper end of the rib 31 is located at a predetermined distance from the inner surface of the air conditioning case 10 on the upper side of the vehicle and extends in the lateral direction of the vehicle.

Therefore, the blown air F that has flowed through the first air passage 30 passes above the ribs 31 inside the air conditioning case 10 . That is, the first air passage 30 according to the present embodiment can be defined as an air passage extending from the air outlet 25 of the fan accommodating portion 15 to the rib 31 toward the vehicle front side.

As shown in FIG. 1 and the like, the vehicle air conditioner 1 has an evaporator 70 inside the first air passage 30 in the air conditioning case 10 . The evaporator 70 is connected to a vapor compression refrigeration cycle via a refrigerant pipe connection 71, and has a tube 72 through which refrigerant flows and a plurality of plate fins 73 joined to the tube 72. there is

Although not shown, the vapor compression refrigeration cycle has a compressor, a condenser, and a decompression section (for example, an expansion valve, a capillary tube, etc.) in addition to the evaporator 70. It is configured by connecting with a refrigerant pipe. Therefore, in the refrigerating cycle, the refrigerant is compressed to a high temperature and high pressure state by the compressor, and the heat is released in the condenser.

Thus, the evaporator 70 can be cooled by absorbing heat from the blown air F through heat exchange between the blown air F flowing through the first air passage 30 and the refrigerant flowing through the tubes 72 . That is, the evaporator 70 functions as a cooling heat exchanger in the vehicle air conditioner 1 and corresponds to the heat exchanger in the present invention.

The tube 72 in the evaporator 70 connects the ends of a plurality of straight pipe portions extending linearly across the first air passage 30 in the vehicle width direction with a substantially U-shaped tube. configured as follows. Therefore, the tube 72 is arranged to meander in the first air passage 30 in the vehicle width direction. Since the end of the tube 72 is connected to the refrigerant pipe connection portion 71 , the refrigerant of the vapor compression refrigeration cycle flows into and out of the tube 72 through the refrigerant pipe connection portion 71 .

In the evaporator 70, a plurality of straight pipe portions of the tubes 72 are arranged in the vehicle front-rear direction, and a plurality of straight pipe portions are arranged in the vehicle vertical direction, which is smaller than the vehicle front-rear direction. That is, a predetermined space is formed between the straight tube portions of each tube 72 in the longitudinal direction of the vehicle and in the vertical direction of the vehicle. Therefore, when the blown air F flowing through the first air passage 30 passes through the evaporator 70 , it passes between the tubes 72 and exchanges heat with the refrigerant flowing inside the tubes 72 .

The plurality of plate fins 73 are formed in a plate shape from a material with good thermal conductivity, and are joined to the straight portion of the tube 72 at intervals in the vehicle width direction as shown in FIG. there is Therefore, the refrigerant flowing inside the tubes 72 can absorb heat from the blast air F flowing through the first air passage 30 via the plate fins 73 in addition to the tube walls of the tubes 72 .

As the refrigerant used in this refrigeration cycle, an HFC refrigerant (specifically, R134a) is adopted, and a vapor compression subcritical refrigeration cycle in which the pressure of the refrigerant on the high pressure side does not exceed the critical pressure of the refrigerant is adopted. Configure. Of course, an HFO-based refrigerant (for example, R1234yf) or the like may be employed as the refrigerant.

A second air passage 35 is formed on the front side of the vehicle inside the air conditioning case 10 . As shown in FIG. 1 and the like, the second air passage 35 is defined by the space between the wall surface of the air conditioning case 10 on the front side of the vehicle and the rib 31 . That is, the second air passages 35 extend in the vehicle width direction (that is, in the vehicle right direction and the vehicle left direction) from the end portions of the first air passage 30 extending forward in the vehicle width direction central portion.

A vehicle front side portion of the second air passage 35 is closed by a vehicle front side wall surface of the air conditioning case 10 . Therefore, in the vehicle air conditioner 1, when the blown air F that has passed through the first air passage 30 flows into the second air passage 35, it hits the wall surface of the second air passage 35 on the front side of the vehicle.

An air volume distribution rib 36 is arranged inside the second air passage 35 . The air volume distribution rib 36 is located in front of the central portion of the air blowing port 25 in the vehicle width direction. The horizontal cross section of the air volume distribution rib 36 has a substantially isosceles triangle shape. The air volume distribution ribs 36 are arranged so that the vertices of the isosceles triangle are positioned on the first air passage 30 side.

Therefore, the air volume distribution rib 36 has the function of dividing the flow of the blown air flowing out from the first air passage 30 into two by the apex and the side surface of the air volume distribution rib 36, and the function of dividing the divided flow of the blown air into the second air passage. It functions to change the direction of the flow to the right side of the vehicle through the second air passage 35 and the left side of the vehicle through the second air passage 35 .

Since the wall surface on the vehicle front side of the air conditioning case 10 extends in the vehicle width direction, the blown air F distributed by the air volume distribution ribs 36 is guided in the vehicle right direction and the vehicle left direction along this wall surface. That is, after flowing into the second air passage 35 , the blown air F is distributed by the air volume distribution ribs 36 and then flows along the second air passage 35 in the vehicle right direction and the vehicle left direction.

The wall surface of the air conditioning case 10 on the front side of the vehicle is composed of the wall surface of the upper case 11 on the front side of the vehicle and the wall surface of the lower case 13 on the front side of the vehicle, as shown in FIG. The wall surface of the upper case 11 on the front side of the vehicle and the wall surface of the lower case 13 on the front side of the vehicle are fitted together by a concave-convex fitting structure.

By adopting this structure, the wall surface of the air-conditioning case 10 on the front side of the vehicle secures the airtightness of the air-conditioning case 10 to the outside. The second air passage 35 can guide the blown air F that has flowed into the second air passage 35 to the third air passage 40 without leaking outside the air conditioning case 10 .

Third air passages 40 are formed on both sides in the vehicle width direction inside the air conditioning case 10 and extend toward the rear side of the vehicle. That is, each of the third air passages 40 is formed on the left and right sides of the vehicle with respect to the first air passages 30 and the evaporator 70 in the air conditioning case 10 . The vehicle front-rear direction corresponds to the first direction, and particularly the vehicle rear side corresponds to one side of the first direction.

As shown in FIG. 1, a distribution member 41 is arranged inside the third air passage 40 on the right side of the vehicle. The distribution member 41 distributes the blown air F that has flowed from the second air passage 35 into the third air passage 40 on the right side of the vehicle into two flows. That is, the third air passage 40 on the right side of the vehicle is divided by the distribution member 41 into a third air passage 40a located on the outside in the vehicle width direction and a third air passage 40b located on the inside in the vehicle width direction.

A distribution member 41 is also arranged inside the third air passage 40 on the left side of the vehicle. The distribution member 41 distributes the blown air F that has flowed from the second air passage 35 into the third air passage 40 on the left side of the vehicle into two flows. That is, the third air passage 40 on the left side of the vehicle is divided into a third air passage 40c located inside in the vehicle width direction and a third air passage 40d located outside in the vehicle width direction. In the following description, the third air passage 40 is treated as a general term for the third air passages 40a to 40d.

Since the third air passages 40 are connected to the second air passages 35 on both sides of the air conditioning case 10 in the vehicle width direction, the blown air F that has passed through the second air passages 35 is guided to the vehicle rear side. be able to. That is, the second air passage 35 can change the direction of the flow of the blowing air F that has passed through the first air passage 30 toward the front of the vehicle by 180° in the horizontal direction. It can lead to the rear side.

The third air passage 40 extends on both sides of the air-conditioning case 10 in the vehicle width direction to a blowout port portion 45 formed in a rear portion of the vehicle. A blowout port portion 45a is arranged in the vehicle rear portion of the third air passage 40a, and a blowout port portion 45b is arranged in the vehicle rear portion of the third air passage 40b. A blowout port portion 45c is arranged at the vehicle rear portion of the third air passage 40c, and a blowout port portion 45d is arranged at the vehicle rear portion of the third air passage 40d. The air outlet portion 45 is a general term for the air outlet portions 45a to 45d.

Each air outlet portion 45 is formed by opening the lower case 13 on the vehicle rear side of the air conditioning case 10 , and communicates the inside of the third air passage 40 in the air conditioning case 10 with the inside of the vehicle compartment I. Therefore, the blown air F that has flowed through the third air passage 40 is blown out from the inside of the air conditioning case 10 toward the rear side of the vehicle into the vehicle interior I through each outlet portion 45 . A specific configuration of the outlet portion 45 will be described later with reference to the drawings.

Next, the flow of the blown air F in the vehicle air conditioner 1 described above will be described in detail with reference to FIG. 6 . When the air conditioning operation of the vehicle air conditioner 1 is started, the operation of the electric motor 21 of the blower 20 is started together with the operation of the compressor in the refrigeration cycle.

As a result, the operation of the blower 20 is started, and the air inside the vehicle compartment I is sucked into the air conditioning case 10 through the suction port 16 of the fan accommodating portion 15 of the vehicle air conditioner 1 .

As shown in FIG. 6, the air sucked from the suction port 16 passes through the blower port 25 formed on the vehicle front side of the fan accommodating portion 15 as the first air F as the blower 20 operates. It blows out into the passage 30 .

The blown air F that has flowed into the first air passage 30 passes between the tubes 72 and the plate fins 73 of the evaporator 70 and flows through the first air passage 30 toward the vehicle front side. At this time, the blown air F is cooled by exchanging heat with the refrigerant in the evaporator 70 .

The blown air F that has passed through the evaporator 70 in the first air passage 30 passes over the rib 31 arranged on the vehicle front side of the air conditioning case 10 and flows into the second air passage 35 . As shown in FIG. 6, the blast air F that has flowed into the second air passage 35 is divided by the air volume distribution rib 36 into the blast air F that flows through the second air passage 35 toward the right side of the vehicle and the second air passage 35 toward the left side of the vehicle. and the flowing blast air F.

As shown in FIG. 6, the air volume distribution rib 36 is arranged to face the central portion of the air blow port 25 in the vehicle width direction. , the volume of the blown air F flowing through the second air passage 35 to the left side of the vehicle can be distributed evenly.

The blown air F distributed in the right direction of the vehicle in the second air passage 35 flows to the right side of the vehicle along the front wall surface of the second air passage 35, and the third air passage 40 is arranged on the right side of the air conditioning case 10 in the vehicle. flow inside. On the other hand, the blown air F distributed in the left direction of the vehicle in the second air passage 35 flows to the right side of the vehicle along the front wall surface of the second air passage 35, and flows to the right side of the vehicle in the air conditioning case 10. It flows into passage 40 .

When flowing into the third air passage 40 on the right side of the vehicle, the blast air F is divided by the distribution member 41 into two flows: the blast air F flowing through the third air passage 40a and the blast air F flowing through the third air passage 40b. be done.

The blown air F that has flowed toward the vehicle rear side through the third air passage 40a is blown out into the interior of the vehicle compartment I from the outlet portion 45a. Then, the blown air F that has flowed toward the vehicle rear side through the third air passage 40b is blown out into the interior of the vehicle compartment I from the outlet portion 45b.

As described above, in the vehicle C according to the present embodiment, the third row seat Sc is closer to the center side in the vehicle width direction than the second row seat Sb due to the relationship with the arrangement space for the rear wheels of the vehicle C. It is considered to be an arrangement. Therefore, the air F blown out from the air outlet portion 45a easily reaches the vehicle right side of the second row seat Sb, and the air blow F blown out from the air outlet portion 45b reaches the vehicle right side of the third row seat Sc. is easier to reach.

On the other hand, when the blast air F flows into the third air passage 40 on the left side of the vehicle, the distribution member 41 divides the blast air F into two flows: the blast air F flowing through the third air passage 40c and the blast air F flowing through the third air passage 40d. distributed to

The blown air F that has flowed toward the vehicle rear side through the third air passage 40c is blown out into the interior of the vehicle compartment I from the outlet portion 45c. Then, the blown air F that has flowed toward the vehicle rear side through the third air passage 40d is blown out into the interior of the vehicle compartment I from the outlet portion 45d.

Due to the arrangement of the second-row seats Sb and the third-row seats Sc, the blowing air F blown from the air outlet portion 45c easily reaches the vehicle left side of the third-row seats Sc, and is blown from the air outlet portion 45d. The air F easily reaches the vehicle left side of the second row seat Sb.

As a result, according to the vehicle air conditioner 1, the blowing air F whose temperature is adjusted by the heat exchange in the evaporator 70 can be supplied from each outlet portion 45, so that the comfort in the passenger compartment I can be improved. can be improved.

Next, a specific configuration of the outlet portion 45 in the vehicle air conditioner 1 will be described in detail with reference to FIG. 7 and the like. FIG. 7 shows a VII-VII cross section in FIG. 1, showing the internal configuration of the outlet portion 45d.

Although FIG. 7 shows the internal configuration of the blow-out port portion 45d, the internal configurations of the blow-out port portions 45a to 45c have the same configuration. Therefore, in the following description, the configuration of the blower outlet portion 45 will be described using the blower outlet portion 45d as an example.

As shown in FIG. 7 , the blowout port portion 45 is a portion through which the blown air that has passed through the third air passage 40 is blown into the interior of the vehicle compartment I, and has a blowout passage 46 . The opening shape of the air outlet portion 45 is formed in a flat slit shape that is short in the vertical direction with respect to the lateral direction of the vehicle, which contributes to downsizing of the vehicle air conditioner 1 as a whole in the vertical direction.

A blowout passage 46 of each blowout port portion 45 extends from the rear end portion of the third air passage 40 toward the rear side of the vehicle and communicates with the interior of the vehicle compartment I. A passage cross section of the blowout passage 46 is formed in a flat slit shape that is short in the vertical direction with respect to the lateral direction of the vehicle.

Then, as shown in FIG. 7, the blow-out passage 46 extends with an inclination so as to be located downward toward the rear side of the vehicle. As described above, in the blowing passage 46, the blowing air F flows toward the rear side of the vehicle, so the blowing passage 46 is inclined downward toward the downstream side in the flow direction of the blowing air F.

The blowout passage 46 is formed in a tubular shape by wall portions including an upper wall portion 47 and a lower wall portion 48 . The upper wall portion 47 constitutes a wall portion corresponding to the upper side of the blowout passage 46, and extends at an angle so as to be located downward toward the rear side of the vehicle.

The lower wall portion 48 is arranged below the upper wall portion 47 at a constant interval, and constitutes the lower wall portion of the blow-out passage 46 . The lower wall portion 48 extends obliquely downward toward the vehicle rear side, and is parallel to the upper wall portion 47 . As shown in FIG. 7, the lower end of the upper wall portion 47 is positioned at the same height as the lower end of the lower wall portion 48 and arranged horizontally.

By configuring the blowout passage 46 as shown in FIG. 7, the upper wall portion 47 is formed with a covered portion 47a and an exposed portion 47b. The covering portion 47a is a portion of the upper wall portion 47 where the vehicle interior I on the lower side thereof is covered by the lower wall portion 48. As shown in FIG. The exposed portion 47b is located below the cover portion 47a of the upper wall portion 47, and is a portion where the lower side of the upper wall portion 47 is exposed to the vehicle compartment I. As shown in FIG.

Further, as shown in FIGS. 1, 6, etc., a guide member 50 is arranged inside the blow-out passage 46 . The guide member 50 is supported so as to be rotatable in the lateral direction of the vehicle, and functions to adjust the flow of the blown air F passing through the blowout passage 46 in the lateral direction of the vehicle. The configuration of the guide member 50 will be described later with reference to the drawings.

As shown in FIG. 7, a lower surface portion 49 is arranged at the lower end portion of the upper wall portion 47 (that is, the lower end portion of the exposed portion 47b). The lower surface portion 49 extends horizontally from the lower end portion of the upper wall portion 47 toward the rear side of the vehicle.

Here, since the opening shape of the blow-out passage 46 has a flat slit shape that is short in the vertical direction, the blown air F that has passed through the blow-out passage 46 is separated from the upper wall portion 47 and the lower surface portion 49 by the so-called Coanda effect. , the airflow direction is changed. Therefore, the blowing direction of the blowing air F that has passed through the blowing passage 46 changes in the substantially horizontal direction toward the rear side of the vehicle C and is guided along the surface of the lower surface portion 49 .

A flap 60 is arranged on the vehicle rear side of the lower surface portion 49 . The flap 60 is attached to the air conditioning case 10 on the vehicle rear side of the lower surface portion 49 so as to be rotatable in the vertical direction of the vehicle. fulfills the function of adjusting to

Next, the configuration of the flap 60 arranged on the vehicle rear side of the lower surface portion 49 will be described with reference to FIG. 8 . As shown in FIGS. 1, 5, and 6, in the vehicle air conditioner 1, a flap 60a is arranged on the vehicle rear side of the air outlet portion 45a, and a flap 60a is arranged on the vehicle rear side of the air outlet portion 45b. has a flap 60b. A flap 60c is arranged on the vehicle rear side of the air outlet portion 45c, and a flap 60d is arranged on the vehicle rear side of the air outlet portion 45d.

Here, the flaps 60a to 60d have the same basic configuration. Therefore, in FIG. 8 and the following description, the flap 60d will be described as an example, and the description of the flaps 60a to 60c will be omitted. The flap 60 is a general term for flaps 60a to 60d.

As shown in FIG. 8, the flap 60 has a flat plate portion 61, a reinforcing rib 62, and a rotation support portion 63, and the flat plate portion 61 and the like are integrally formed by resin molding. The flat plate portion 61 is a portion that occupies substantially the entire flap 60 when viewed from above, and is formed in a substantially rectangular flat plate shape.

The longitudinal direction of the flat plate portion 61 of the flap 60 is arranged in parallel with the longitudinal direction (horizontal direction of the vehicle) of the air outlet portion 45 located on the front side of the vehicle (that is, the upstream side in the blowing direction). The lower surface of the flat plate portion 61 of the flap 60 functions as a guide surface that guides the blown air F that has flowed along the surface of the lower surface portion 49 .

As shown in FIG. 8 and the like, reinforcing ribs 62 are arranged on the upper surface of the flat plate portion 61 . The reinforcing ribs 62 are arranged along the outer edge of the flat plate portion 61 . The reinforcing ribs 62 also include those that connect the reinforcing ribs 62 arranged along the front edge and the rear edge of the flat plate portion 61 . These reinforcing ribs 62 serve to reinforce the flat plate portion 61 of the flap 60, suppress deformation of the flat plate portion 61, and maintain a flat state.

The rotation support portion 63 is a portion for supporting the flap 60 so as to be vertically rotatable with respect to the air conditioning case 10 . The rotation support portions 63 are arranged on the front side of the vehicle on both the left and right sides of the flap 60 .

The rotation support portion 63 is formed in a flat plate shape, and the normal direction thereof extends along the left-right direction of the vehicle. A circular support hole penetrating in the left-right direction of the vehicle is formed in the rotation support portion 63 . A cylindrical shaft portion formed behind the lower surface portion 49 of the air conditioning case 10 is inserted through the support hole. As a result, the flap 60 is attached to the air conditioning case 10 on the vehicle rear side of the air outlet portion 45 so as to be rotatable in the vertical direction of the vehicle.

Next, in the vehicle air conditioner 1 according to the present embodiment, adjustment of the flow of the blowing air F blown out from the blowout port portion 45 will be described with reference to FIG. 7 . As shown in FIG. 7, the blowing air F blown out from the outlet 45 changes its flow direction along the lower end of the upper wall 47 and the lower surface 49 by the so-called Coanda effect. As a result, the blown air F flows generally horizontally toward the vehicle rear side along the surface of the lower surface portion 49 and reaches the flap 60 .

When the flap 60 is in a horizontal state along the surface of the lower surface portion 49 , the lower surface of the flat plate portion 61 of the flap 60 is positioned on the same plane as the surface of the lower surface portion 49 . In this case, as shown by the dashed line in FIG. 7, the blown air F flowing along the lower surface portion 49 toward the rear side of the vehicle flows horizontally along the lower surface of the flat plate portion 61 of the flap 60, and then flows into the passenger compartment I. is blown toward the rear side of the vehicle air conditioner 1 .

That is, the vehicle air conditioner 1 in this case guides the blowing direction of the blowing air F blown out from the air outlet portion 45 horizontally to the rear side of the vehicle C, so that the air blowing direction is the most rearward in the vehicle interior I. Air F can be supplied. For example, when adjusted in this manner, the vehicle air conditioner 1 can supply the blown air F blown out from the blowout port portion 45 to the occupant P in the third row seat Sc located at the rearmost position.

Next, a case in which the tilt angle of the flap 60 is changed by rotating the flap 60 will be described. As described above, the flap 60 is rotatably supported with respect to the air-conditioning case 10 about the columnar shaft. It can be rotated in the vertical direction around the shaft. Thereby, the occupant P can arbitrarily adjust the inclination angle of the lower surface of the flap 60 with respect to the lower surface portion 49 .

As indicated by the dashed line in FIG. 7 , when the flap 60 is rotated with the rear side thereof being pulled down, the blown air F blown from the outlet portion 45 is directed along the lower surface portion 49 of the vehicle. It flows rearward and reaches the lower surface of the flap 60 .

At this time, since the rear side of the flap 60 is pulled down, the blown air F flows toward the rear side and the lower side of the vehicle air conditioner 1 along the lower surface of the flat plate portion 61 of the flap 60 .

In other words, the vehicle air conditioner 1 in this case supplies the blown air F blown out from the outlet portion 45 further forward than when the flap 60 is in a horizontal state along the surface of the lower surface portion 49. be able to. For example, when adjusted in this way, the vehicle air conditioner 1 directs the blown air F blown out from the air outlet portion 45 to the occupant P in the second row seat Sb arranged in front of the third row seat Sc. can supply.

As described above, the vehicle air conditioner 1 according to the present embodiment is configured such that the blowing direction of the blowing air F blown out from the outlet portion 45 is adjusted in accordance with the tilt angle adjusted by the vertical rotation operation of the flap 60. can be arbitrarily adjusted in the vertical direction. As a result, according to the vehicle air conditioner 1 , the supply destination of the blown air F blown from the blowout port portion 45 can be adjusted in the vehicle longitudinal direction inside the vehicle compartment I.

Next, the configuration of the guide member 50 arranged in the blowout passage 46 of each blowout port portion 45 will be described with reference to the drawings. FIG. 9 shows the IX-IX section in FIG. 1, showing the configuration of the guide member 50d inside the outlet portion 45d. 10 is an enlarged view of the periphery of the guide member 50 in FIG. 9. FIG.

9 shows the configuration of the guide member 50d inside the outlet portion 45d as in FIG. The configurations of the member 50b and the guide member 50c are also similar.

Therefore, in the following description, the configuration of the guide member 50 in the outlet portion 45 will be described by taking the guide member 50d inside the outlet portion 45d as an example. The guide member 50 is a general term for the guide members 50a to 50d.

As shown in FIGS. 1, 5, 6, etc., the vehicle air conditioner 1 according to the present embodiment includes guide members 50a to 50d inside the blowout passage 46 at the blowout openings 45a to 45d. have. Each guide member 50 is formed in the shape of a flat plate extending along the inside of the blowout passage 46 and is attached so as to be rotatable around a support portion 55 arranged on the upper wall portion 47 .

As described above, the blow-out passage 46 in each blow-out port portion 45 is configured to have a flat opening whose dimension in the vertical direction of the vehicle is shorter than its dimension in the width direction of the vehicle. Each guide member 50 has a longitudinal dimension of a predetermined length L and a lateral dimension of a flat plate that is slightly shorter than the dimension of the outlet passage 46 in the vertical direction of the vehicle.

As shown in FIGS. 9 and 10 , each guide member 50 is rotatably supported by a support portion 55 arranged on the upper wall portion 47 of the blowout passage 46 . The rotation axis of the support portion 55 is perpendicular to the upper wall portion 47 . Therefore, each guide member 50 is attached to the inside of the blowout passage 46 in the blowout port portion 45 so as to be rotatable in the left-right direction of the vehicle about the support portion 55 . The vehicle width direction (vehicle left-right direction) perpendicularly intersects the vehicle front-rear direction, which corresponds to the first direction, and corresponds to the second direction.

Each guide member 50 includes an air guiding portion 51 for guiding the flow of the blown air F passing through the blowout passage 46, and an air guide portion 51 that is operated when rotating the guide member 50 in the vehicle width direction inside the blowout passage 46. and a knob operation unit 52 that

The air guide portion 51 of the guide member 50 is located upstream of the support portion 55 with respect to the blowing direction of the blowing air F in the blowout passage 46 . As shown in FIGS. 9 and 10 , most of the air guide portion 51 is positioned between the upper wall portion 47 and the lower wall portion 48 . In other words, the air guide portion 51 is positioned below the covering portion 47 a of the upper wall portion 47 inside the blowout passage 46 .

The air guide portion 51 has a function of guiding the flow of air passing through the blowout passage 46, and the air blown out from the blowout port portion 45 is directed according to the position in the vehicle width direction inside the blowout passage 46. Adjust the blowing direction of F to the width direction of the vehicle.

The knob operation portion 52 is a portion that is pinched by the passenger P when rotating the guide member 50 in the vehicle width direction. As shown in FIGS. 9 and 10 , the knob operating portion 52 is located downstream of the air guide portion 51 and the support portion 55 with respect to the blowing direction of the blown air F in the blowout passage 46 . The knob operation section 52 corresponds to an operation section.

That is, the knob operating portion 52 is positioned below the exposed portion 47b in the upper wall portion 47 of the outlet portion 45 and is arranged at a position facing the exposed portion 47b. Therefore, the knob operating portion 52 faces the inside of the vehicle compartment I without being blocked by the lower wall portion 48 .

Therefore, an occupant P inside the vehicle C can easily pick up the knob operation portion 52 from below the vehicle air conditioner 1 and can rotate the guide member 50 in the left and right direction of the vehicle. As a result, according to the vehicle air conditioner 1, the blowing direction of the blowing air F blown from the blower outlet portion 45 can be easily adjusted to any direction in the vehicle width direction.

9 and 10, the knob operating portion 52 of the guide member 50 is formed above the lower ends of the upper wall portion 47 and the lower wall portion 48 and below the exposed portion 47b of the upper wall portion 47. It is arranged by making effective use of the dead space. Since the guide member 50 does not greatly protrude downward from the air conditioning case 10, the vehicle air conditioner 1 can be downsized in the vertical direction of the vehicle and the living space in the passenger compartment I can be increased. can contribute to ensuring

The support portion 55 is arranged in the exposed portion 47b of the upper wall portion 47 of the blowout passage 46, and supports the guide member 50 so as to be rotatable in the vehicle width direction. The support portion 55 is attached to the guide member 50 at a position biased toward the knob operating portion 52 with respect to the entire length L of the guide member 50 .

Therefore, when the guide member 50 is rotated in the width direction of the vehicle about the support portion 55, the amount of movement of the air guiding portion 51 side becomes larger than the amount of movement of the knob operating portion 52 side. That is, according to the vehicle air conditioner 1 , the air guide portion 51 can be largely rotated by a small amount of rotation operation on the knob operation portion 52 , and the blowing direction of the blown air F blown out from the outlet portion 45 can be changed. can be efficiently adjusted in the vehicle width direction.

Next, in the vehicle air conditioner 1 according to the present embodiment, adjustment of the flow of the blown air F inside the blowout passage 46 of the blowout port portion 45 will be described with reference to FIGS. 11 and 12. FIG. As described above, in the vehicle air conditioner 1, the blown air F that has flowed through the second air passage 35 flows into the third air passages 40 on the vehicle left side and the vehicle right side, and flows through the distribution members 41 to the outlets. It is distributed for each part 45 .

The blown air F distributed by the distribution member 41 arranged on the right side of the vehicle flows into the blower outlet portion 45a and the blower outlet portion 45b arranged on the right side of the vehicle of the vehicle air conditioner 1 . Here, the distribution member 41 on the right side of the vehicle is arranged so as to evenly distribute the blown air that has flowed to the right side of the vehicle through the second air passage 35 and guide it to the blowout port 45a and the blowout port 45b.

Then, the blown air F distributed by the distribution member 41 arranged on the left side of the vehicle flows into the blower outlet portion 45c and the blower outlet portion 45d of the vehicle air conditioner 1 arranged on the left side of the vehicle. Here, the distribution member 41 on the left side of the vehicle is arranged so as to evenly distribute the blown air that has flowed to the left side of the vehicle through the second air passage 35 and guide it to the blowout port 45c and the blowout port 45d.

As shown in FIGS. 11 and 12, each distribution member 41 has a front side edge (that is, an upstream side edge in the blowing direction of the blown air F) with a predetermined front side distance Df and an inner side distance Di. are arranged as follows. The front distance Df is the distance between the front end of the distribution member 41 and the inner wall surface of the air conditioning case 10 on the front side of the vehicle, and the inner distance Di is the distance between the front end of the distribution member 41 and the inside in the vehicle width direction. means interval.

The front space Df in the distribution member 41 on the right side of the vehicle corresponds to the volume of the blown air F flowing into the blowout port 45a, and the inner space Di corresponds to the volume of the blown air F flowing into the blowout port 45b. . The front spacing Df and the inner spacing Di of the distribution member 41 on the right side of the vehicle are determined so that the volume of the blown air F at the blowout port 45a and the volume of the blown air F at the blowout port 45b are equal.

On the other hand, the inner space Di in the distribution member 41 on the left side of the vehicle corresponds to the volume of the blown air F flowing into the blowout port 45c, and the front space Df corresponds to the volume of the blown air F flowing into the blowout port 45d. ing. The front spacing Df and the inner spacing Di of the distribution member 41 on the left side of the vehicle are determined so that the volume of the blown air F at the outlet 45c and the volume of the blown air F at the outlet 45d are equal.

That is, the vehicle air conditioner 1 is configured such that the blowing air F is blown out at a mutually equal volume from the outlets 45a to 45d arranged side by side in the width direction of the vehicle. A guide member 50 is attached to the inside of the blowout passage 46 of each of the blowout openings 45a to 45d so as to be rotatable in the width direction of the vehicle.

When the guide member 50 is rotated in the vehicle width direction, the position and attitude of the air guide portion 51 inside the blowout passage 46 change in the vehicle width direction. Therefore, the blowing direction of the blowing air F blown from the blow-out port portion 45 is changed to any direction in the width direction of the vehicle by rotating the guide member 50 around the support portion 55 .

As shown in FIGS. 11 and 12, guide members 50a, 50b, 50c, and 50d are provided at the outlet portion 45a, the outlet portion 45b, the outlet portion 45c, and the outlet portion 45d. They are arranged so as to be independently rotatable in the width direction of the vehicle.

Therefore, according to the vehicle air conditioner 1, the blowing direction of the blowing air F blown from the plurality of air outlets 45 (that is, the air outlets 45a to 45d) arranged side by side in the vehicle width direction can be individually adjusted in any direction in the vehicle width direction by rotating each guide member 50 in the vehicle width direction.

In the vehicle air conditioner 1, each flap 60 is arranged on the vehicle rear side of each air outlet portion 45 so as to be rotatable in the vehicle vertical direction. Therefore, the blowing direction of the blowing air F blown from the blow-out port portion 45 can be adjusted to any direction in the vertical direction of the vehicle.

That is, according to the vehicle air conditioner 1, the blowing direction of the blowing air F blown from the four outlet portions 45 arranged side by side in the vehicle width direction can be set to any direction in the vehicle width direction and the vehicle vertical direction. can be adjusted to

As a result, the vehicle air conditioner 1 can supply the blown air F blown from each blowout port 45 to an arbitrary position on the rear side of the vehicle relative to the vehicle air conditioner 1 in the vehicle interior I, or It can be supplied out of position. By realizing various supply modes for the blown air F, the vehicle air conditioner 1 can respond to the requests of each passenger P in the passenger compartment I, and can improve the comfort of each passenger P. .

As described above, the vehicle air conditioner 1 according to the present embodiment is arranged on the ceiling portion R of the vehicle C, and is configured by housing the blower 20 and the evaporator 70 inside the air conditioning case 10 . The vehicle air conditioner 1 adjusts the temperature of the blown air F flowing inside the air conditioning case 10 with the operation of the blower 20 by the evaporator 70, and supplies it to the inside of the vehicle compartment I of the vehicle C. occupant P's comfort can be improved.

Further, according to the vehicle air conditioner 1, since each air outlet portion 45 is formed in a flat slit shape that is short in the vertical direction with respect to the lateral direction of the vehicle, the size of the entire device in the vertical direction can be reduced. It is possible to secure a large living space in the passenger compartment I.

As shown in FIGS. 9 to 12 and the like, in the vehicle air conditioner 1, a guide member 50 is provided inside an air outlet passage 46 of an air outlet portion 45 formed in a flat slit shape that is short in the vertical direction of the vehicle. It is arranged so as to be rotatable in the width direction.

For this reason, even in the case of the air outlet portion 45 formed in a flat slit shape that is short in the vertical direction, the air conditioner 1 for a vehicle can direct the flow of the blown air F blown out from the air outlet portion 45 in the width direction of the vehicle. can be adjusted in any direction, and the ventilation mode desired by the occupant P can be realized in the vehicle width direction.

As shown in FIG. 10, the knob operating portion 52 of the guide member 50 is arranged at a position facing the exposed portion 47b of the upper wall portion 47. As shown in FIG. For this reason, according to the vehicle air conditioner 1, even if the air outlet portion 45 is formed in a flat slit shape with a short vertical direction, the occupant P in the passenger compartment I can operate the knob of the guide member 50 from below. The portion 52 is easily accessible.

As a result, the vehicle air conditioner 1 can improve the operability of the guide member 50 in the vehicle width direction, and can accurately adjust the wind direction in the vehicle interior I in the vehicle width direction.

As shown in FIG. 10 , the guide member 50 is rotatably supported in the vehicle width direction by a support portion 55 arranged in the exposed portion 47 b of the upper wall portion 47 . Further, the support portion 55 supports the guide member 50 at a position biased toward the knob operating portion 52 with respect to the guide member 50 as a whole. Therefore, when the guide member 50 rotates in the width direction of the vehicle, the amount of movement of the air guide portion 51 side becomes larger than the amount of movement of the knob operation portion 52 side.

Therefore, according to the vehicle air conditioner 1, with respect to the rotation operation of the guide member 50 in the vehicle width direction, a small operation on the knob operation portion 52 changes the blowing direction of the blowing air F blown out from the blowout port portion 45 to It can be changed greatly in the width direction of the vehicle.

(Other embodiments)
Although the present invention has been described above based on the embodiments, the present invention is not limited to the above-described embodiments. That is, various modifications and improvements are possible without departing from the gist of the present invention. For example, the configurations of the embodiments described above may be combined as appropriate, and the embodiments described above may be modified in various ways.

(1) In the above-described embodiment, the vehicle air conditioner 1 is configured to supply the blown air F cooled by the evaporator 70 into the vehicle interior I from the outlet portion 45, but is limited to this aspect. not something. For example, as a configuration for adjusting the temperature of the blown air F, the blown air may be heated using a heat exchanger such as a condenser or a heater core of a refrigeration cycle device. Also, as a configuration for adjusting the temperature of the blown air F, a Peltier element, an electric heater, or the like may be employed.

Furthermore, the vehicle air conditioner 1 does not necessarily need to adjust the temperature of the blown air F, and may be configured as a configuration (that is, a circulator) in which the air drawn into the air conditioning case 10 is directly blown out from the outlet portion 45. is also possible.

(2) In the above-described embodiment, the blowing air F is blown out along the third air passage 40 toward the rear side of the vehicle. Although the direction is adjusted in an arbitrary direction in the vehicle width direction (vehicle left-right direction), it is not limited to this aspect.

Various directions can be adopted as the first direction and the second direction, unlike the aspect in which the vehicle front-rear direction is the first direction and the vehicle width direction is the second direction as in the above-described embodiment. For example, the vehicle air conditioner 1 may be arranged on the ceiling portion R of the vehicle C so that the vehicle width direction is the first direction and the vehicle longitudinal direction is the second direction.

(3) In the above-described embodiment, the air passages for the blown air F in the air-conditioning case 10 are configured to have the first air passage 30, the second air passage 35, and the third air passage 40, but this aspect is not limited to It is sufficient that the configuration of the blow-out port portion 45 is the above-described configuration, and the configuration of the air passage on the upstream side thereof can be changed as appropriate.

Reference Signs List 1 vehicle air conditioner 10 air conditioning case 20 blower 45 blowout port 46 blowout passage 47 upper wall portion 47a cover portion 47b exposed portion 50 guide member 52 knob operation portion

Claims (1)

an air conditioning case (10) disposed in the ceiling (R) of the compartment (I) and having a suction port (16) through which the air inside the compartment is sucked;
a blower (20) housed inside the air-conditioning case for blowing the air inside the air-conditioning case;
It is formed in a flat shape with a short vertical direction and extends in a predetermined first direction. and a blowout port (45) for blowing out into the interior of the compartment,
The blow-out passage is
an upper wall portion (47) forming an upper side of the blowout passage and extending at an angle so as to be located downward toward the downstream side in the flow direction of the blown air passing through the blowout passage;
a lower wall portion (48) arranged at a distance below the upper wall portion and extending downward toward the downstream side in the flow direction of the blown air;
The lower end of the upper wall portion is formed so as to be horizontally aligned with the lower end of the lower wall portion,
The upper wall portion includes a covered portion (47a) whose lower side of the upper wall portion is covered by the lower wall portion, and an exposed portion (47b) below the covered portion where the lower side of the upper wall portion is exposed. and
A guide member (50) that rotates in a second direction that intersects with the first direction to adjust the flow of air blown from the blow-out port in the second direction is provided inside the blow-out passage. is placed and
The guide member has an operation portion (52) used for a pivoting operation in the second direction at a position facing the exposed portion of the upper wall portion, and is arranged at the exposed portion of the upper wall portion. is rotatably supported in the second direction by the supporting portion (55),
The vehicle air conditioner , wherein the support portion supports the guide member at a position biased toward the operation portion with respect to the entire guide member .

Images