JP2016124431A - Air conditioner for vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce ventilation resistance to inhibit deterioration of the air quantity when conditioned air is blown from a casing in different directions.SOLUTION: An air conditioner for a vehicle 1 includes a damper unit having an air circulation port B1, through which conditioned air generated in a casing 4 circulates, and having a frame member 43 holding a damper 42 for changing the opening of the air circulation port B1. A communication port 43e, through which the conditioned air generated in the casing 4 circulates, is formed in the frame member 43 so as to open in a direction different from that of the air circulation port B1.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a vehicle air conditioner mounted on, for example, an automobile.

  2. Description of the Related Art Conventionally, a vehicle air conditioner has a casing that houses a cooling heat exchanger and a heating heat exchanger. The casing includes an amount of air that passes through the cooling heat exchanger and a heating heat exchanger. There are provided a temperature adjustment damper that changes the amount of air passing therethrough to generate conditioned air, a blowing direction switching damper that switches the blowing direction of the generated conditioned air, and the like. A defroster opening and a vent opening are formed on the casing upper wall of the vehicle air conditioner of Patent Document 1, and a defroster damper that opens and closes the defroster opening and a vent damper that opens and closes the vent opening are held. A holding structure is provided. The holding structure has a frame shape, and a convex portion that protrudes toward the casing is formed on the peripheral edge thereof. On the other hand, a recess is formed in the peripheral edge of the mounting port at the top of the casing. The holding structure is attached to the casing by fitting the convex part of the holding structure into the concave part of the casing.

  In addition, since the defroster opening and the vent opening of the holding structure are opened upward, the conditioned air generated in the casing flows out from the casing through the defroster opening and the vent opening. Will do.

Japanese Patent No. 4092632

  By the way, in patent document 1, since the defroster opening part and vent opening part of a holding structure are opening upwards, the flow of the conditioned air which flows out from a defroster opening part, and the conditioned air which flows out from a vent opening part Both flows are upwards. However, in general, the defroster outlet formed in the instrument panel faces upward, while the vent outlet faces the rear side of the vehicle on the passenger side, so the defroster outlet and the vent outlet are in different directions. Is open. Therefore, in Patent Document 1, the direction of the flow of conditioned air blown out from the vent outlet must be changed greatly depending on the shape setting of the duct. As a result, the ventilation resistance of the duct is increased, and consequently the air volume is reduced.

  The present invention has been made in view of such a point, and an object of the present invention is to reduce a ventilation resistance and suppress a decrease in an air volume when conditioned air is blown out in a plurality of different directions. is there.

  In order to achieve the above object, in the present invention, the blowout direction of the conditioned air is set in advance in a plurality of directions by a damper unit provided in the casing.

The first invention is
A heat exchanger for adjusting the temperature of air-conditioning air;
A casing for housing the heat exchanger;
A vehicle air conditioner having a first air circulation port through which conditioned air generated in the casing flows, and a damper unit having a frame member that holds a damper that changes the opening degree of the first air circulation port. In the device
In the frame member, a second air circulation port through which conditioned air generated in the casing flows is formed to open in a direction different from the first air circulation port. .

  According to this configuration, the conditioned air generated in the casing flows through the first air circulation port and also flows through the second air circulation port. Since the first air circulation port and the second air circulation port are opened in different directions, the conditioned air is blown out from the casing in a plurality of different directions. This makes it possible to change the flow direction of the conditioned air by the damper unit without greatly changing the direction of the conditioned air by the duct, thereby reducing the ventilation resistance.

According to a second invention, in the first invention,
The first air circulation port is a vent opening for a front seat through which conditioned air supplied to a front seat occupant in the passenger compartment flows.
The second air circulation port is a rear-seat vent opening through which conditioned air supplied to a rear-seat occupant in the passenger compartment circulates.

  That is, in general, the conditioned air supplied to the front seat occupant blows out toward the rear of the vehicle, whereas the conditioned air supplied to the rear seat occupant flows through the rear seat duct disposed near the floor of the passenger compartment. Therefore, the conditioned air supplied to the front seat occupant and the conditioned air supplied to the rear seat occupant have different blowing directions. In this case, by applying the present invention and changing the direction of the conditioned air flow by the damper unit, it is possible to reduce the ventilation resistance for both the front seat and the rear seat.

According to a third invention, in the second invention,
A part of the first air circulation port is positioned outside the damper and is normally open.

  According to this structure, it becomes possible to always flow conditioned air from a part of the first air circulation port.

According to a fourth invention, in the third invention,
The first air circulation port is respectively disposed on both sides of the second air circulation port in the width direction.

  According to this structure, it becomes possible to always flow conditioned air from both sides in the width direction of the second air circulation port.

According to a fifth invention, in any one of the first to fourth inventions,
The frame member is inserted into an attachment port formed in the casing from the outside of the casing.

  According to this configuration, when the frame member is attached to the casing, the frame member may be inserted into the attachment port from the outside of the casing.

A sixth invention is the invention according to any one of the first to fifth aspects,
The casing is formed with an attachment port to be attached in a state where the frame member is inserted,
A seal member is provided from a peripheral edge of the mounting port in the casing to a peripheral edge of the first air circulation port in the frame member.

  According to this structure, the peripheral part of the attachment port in a casing and the peripheral part of the 1st air circulation port in a frame member are sealed by the sealing member. In addition, since this seal member extends from the peripheral edge of the mounting port in the casing to the peripheral edge of the first air circulation port in the frame member, air leakage from between the casing and the frame member is suppressed by the same seal member. Therefore, an increase in the number of parts is suppressed.

A seventh invention is the sixth invention, wherein
The seal member is provided between a peripheral portion of the first air circulation port in the frame member and an air conditioning duct connected to the first air circulation port and guiding conditioned air into the vehicle interior. It seals between a member and this air-conditioning duct.

  According to this structure, it becomes possible to seal between a frame member and an air-conditioning duct with a sealing member.

  According to the first invention, the first air circulation port and the second air circulation port through which conditioned air flows are formed in the frame member of the damper unit attached to the casing, and the second air circulation port is the first air circulation port. Therefore, when the conditioned air is blown out from the casing in a plurality of different directions, the airflow resistance can be reduced and the reduction in the air volume can be suppressed.

  According to the second aspect, since the ventilation resistance can be reduced when the conditioned air is supplied to each of the front seat occupant and the rear seat occupant, a sufficient air volume can be secured for both occupants.

  According to the third aspect of the invention, conditioned air can always flow from the first air circulation port.

  According to the fourth aspect of the invention, the conditioned air can always flow from both sides in the width direction of the second air circulation port.

  According to the fifth aspect, since the frame member can be inserted into the attachment port from the outside of the casing, the frame member can be easily attached to the casing.

  According to the sixth invention, since the seal member is provided from the peripheral edge portion of the mounting opening in the casing to the peripheral edge portion of the first air circulation port in the frame member, the frame member and the casing are suppressed while suppressing an increase in the number of parts. The sealing property between the two can be improved.

  According to the seventh aspect, the space between the frame member and the air conditioning duct can be sealed by the sealing member.

It is the perspective view which looked at the air-conditioner for vehicles concerning an embodiment from the vehicles back side. It is a left view of a vehicle air conditioner. It is a top view of a vehicle air conditioner. It is a disassembled perspective view of a vehicle air conditioner. FIG. 4 is a cross-sectional view taken along line AA in FIG. 3 when the vent damper unit is in an open state. FIG. 5 is a sectional view taken along line BB in FIG. 3 when the vent damper unit is in an open state. It is the rear view which looked at the vent damper unit in an open state from the vehicle rear side. It is the rear view which looked at the vent damper unit in a closed state from the vehicle rear side. It is a top view of a vent damper unit. It is a bottom view of a vent damper unit. It is the front view which looked at the vent damper unit in an open state from the vehicle front side. It is a left view of a vent damper unit. FIG. 4 is a cross-sectional view taken along line AA in FIG. 3 when the vent damper unit is in a closed state. FIG. 5 is a sectional view taken along line BB in FIG. 3 when the vent damper unit is in a closed state.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. It should be noted that the following description of the preferred embodiment is merely illustrative in nature, and is not intended to limit the present invention, its application, or its use.

  FIG. 1 is a perspective view of a vehicular air conditioner 1 according to an embodiment of the present invention as viewed obliquely from the left rear. This vehicle air conditioner 1 is accommodated in an instrument panel (not shown) provided at the front end of the vehicle in a vehicle interior of, for example, an automobile. In the description of this embodiment, the front side of the vehicle is simply referred to as “front”, the rear side of the vehicle is simply referred to as “rear”, the left side of the vehicle is simply referred to as “left”, and the right side of the vehicle is simply referred to as “right”. To do. Moreover, although not shown, the front seat and the rear seat are provided in the passenger compartment.

  As shown in FIGS. 5 and 6, the vehicle air conditioner 1 includes a cooling heat exchanger 2 and a heating heat exchanger 3 for adjusting the temperature of the air-conditioning air, and these cooling heat exchanger 2 and heating. And a casing 4 for housing the heat exchanger 3 for use. The casing 4 is formed by molding a resin material, and is configured by combining a front member 4a, a lower member 4b, a left member 4c, and a right member 4d as shown in FIGS. The front member 4 a constitutes a portion on the front side of the central portion of the casing 4 in the front-rear direction. The lower member 4 b constitutes the bottom wall portion of the casing 4. The left side member 4 c and the right side member 4 d constitute the entire rear side with respect to the front side member 4 a of the casing 4.

  Although not shown, the vehicle air conditioner 1 also includes a blower unit. The blower unit is configured such that one of the air inside the vehicle compartment and the air outside the vehicle compartment can be selected and taken into the casing 4. The blower unit is disposed on the passenger seat side of the passenger compartment. In this embodiment, it is arranged on the right side in the instrument panel.

  The casing 4 is disposed in a substantially central portion in the left-right direction of the passenger compartment within the instrument panel. As shown in FIGS. 5 and 6, an air intake 10 is formed in the front portion of the right side wall portion of the casing 4, and the air intake 10 is connected to the blower unit. A defroster opening 12 is formed in the upper wall portion of the casing 4. The defroster opening 12 opens over both ends of the casing 4 in the left-right direction. Although not shown, a defroster duct is connected to the defroster opening 12. The defroster duct is connected to a defroster outlet provided in the instrument panel. The defroster outlet is for supplying conditioned air toward the inner surface of the front windshield of the vehicle, and is generally located at the front end of the upper surface of the instrument panel.

  Moreover, as shown in FIG. 1 etc., the vent blowing duct 13 is formed in the upper part of the rear wall part of the casing 4 so that it may protrude diagonally upward. As shown in FIG. 4, a damper unit attachment port 14 to which the vent damper unit 40 is attached is formed at the front end in the protruding direction of the vent outlet duct 13. The damper unit attachment port 14 is open across both ends of the casing 4 in the left-right direction. The structure of the vent damper unit 40 will be described later.

  As shown in FIG. 4, the damper unit mounting opening 14 is formed in a substantially rectangular shape that is long in the left-right direction. A flange 15 extending outward in the radial direction of the damper unit mounting port 14 is formed on the entire periphery of the periphery of the damper unit mounting port 14 in the casing 4. A surface of the flange 15 facing obliquely rearward is a first seal surface portion 15a. The first seal surface portion 15 a is formed over the entire periphery of the periphery of the damper unit attachment port 14. As shown in a partially enlarged view in FIG. 5, the inner portion of the damper unit attachment opening 14 in the first seal surface portion 15 a is lowered by one step, thereby forming a step portion 15 b in the first seal surface portion 15 a.

  On the inner surface of the vent outlet duct 13, a plurality of engaging protrusions 13 a that protrude inward of the vent outlet duct 13 are formed. The engaging protrusions 13a are separated from each other on the left and right, and are formed in a claw shape that engages with a vent damper unit 40 described later.

  The vent blowing duct 13 is connected to a front seat vent duct (air conditioning duct) A (shown only in FIG. 2) via a vent damper unit 40. Although not shown, four passages are formed in the front end vent duct A so as to be lined up in the left-right direction. The front seat vent duct A includes four branch ducts (not shown), each of which has four passages extending from the base end. The four branch ducts include two center vent outlets (not shown) formed in the center in the left-right direction of the instrument panel, and left and right side vent outlets formed on the left and right sides of the instrument panel, respectively. Each is connected to an outlet (not shown). The center vent outlet and the side vent outlet are mainly for supplying conditioned air to the upper body of the front seat occupant.

  A flange A1 extending in the radial direction is formed at the base end of the front seat vent duct A. The outer shape of the flange A1 is set to be substantially the same as the outer shape of the first seal surface portion 15a of the flange 15 of the casing 4.

  As shown in FIGS. 1, 5, and 6, a heat duct 16 is integrally formed on the rear wall portion of the casing 4. The heat duct 16 is for supplying conditioned air near the feet of the passenger. The upper end portion (upstream end portion) of the heat duct 16 is adjacent to the lower portion of the vent outlet duct 13 in the rear wall portion of the casing 4. The heat duct 16 extends downward from the upstream end portion thereof, and the lower side is separated rearward from the rear wall portion of the casing 4. The cross-sectional shape of the heat duct 16 is a rectangular shape that is long in the left-right direction. In addition, a duct on the vehicle side is connected to the lower side of the heat duct 16 (not shown).

  Further, a rear seat vent duct 17 is integrally formed on the rear wall portion of the heat duct 16. The rear seat vent duct 17 is for supplying conditioned air to the upper body of the rear seat occupant. As shown in FIG. 6, the upper end portion (upstream end opening portion 17 a) of the rear seat vent duct 17 is open on the inner surface of the lower wall portion of the vent outlet duct 13 and has a shape that is long in the left-right direction.

  As shown in FIG. 1, the rear seat vent duct 17 extends downward along the rear wall portion of the heat duct 16. The lower end portion of the rear seat vent duct 17 is located above the lower end portion of the heat duct 16, and the lower end portion of the rear seat vent duct 17 is rearward along the floor of the passenger compartment (not shown). A duct extending to the seat side is connected.

  The rear seat vent duct 17 has a rectangular cross section that is long in the left-right direction. The lateral dimension of the rear seat vent duct 17 is set shorter than the lateral dimension of the heat duct 16, and the left side wall portion of the rear seat vent duct 17 is on the right side of the left side wall portion of the heat duct 16. The right side wall portion of the rear seat vent duct 17 is located on the left side of the right wall portion of the heat duct 16. Further, the dimension in the front-rear direction of the rear seat vent duct 17 is set to be shorter than the dimension in the front-rear direction of the heat duct 16. That is, the cross-sectional area of the rear seat vent duct 17 is smaller than the cross-sectional area of the heat duct 16. The front wall portion of the rear seat vent duct 17 is constituted by the rear wall portion of the heat duct 16, whereby the rear seat vent duct 17 and the heat duct 16 can be combined in a compact manner.

  As shown in FIGS. 5 and 6, an air passage R extending from the air intake 10 to the rear side is formed in the casing 4. The air passage R includes a cold air passage R1 in which the cooling heat exchanger 2 is disposed, a hot air passage R2 in which the heating heat exchanger 3 is disposed, and an air mix space R3. The cold air passage R <b> 1 extends from the air intake 10. The cooling heat exchanger 2 disposed in the cold air passage R1 is composed of, for example, a refrigerant evaporator of a heat pump device, and can cool the air-conditioning air flowing through the cold air passage R1 if the heat pump device is in an operating state. It is configured to be able to.

  A partition wall 19 extending in the vertical direction is provided between the cold air passage R1, the hot air passage R2, and the air mix space R3. A cold air passage R1 is provided in front of the partition wall 19. An opening 19 a is formed in the middle portion of the partition wall 19 in the vertical direction. The downstream end portion of the cold air passage R1 and the air mix space R3 communicate with each other through the opening 19a.

  The warm air passage R2 is formed in the casing 4 on the rear side of the partition wall 19 and in the lower region thereof. The upstream end of the hot air passage R2 communicates with the downstream end of the cold air passage R1. As the heating heat exchanger 3 disposed in the hot air passage R2, for example, a heater core through which cooling water of an engine mounted on a vehicle circulates, an electric heater that generates heat by supplying electric power, or the like can be used. The downstream end of the warm air passage R2 communicates with the air mix space R3.

  The air mix space R3 is formed in the casing 4 above the warm air passage R2. The cool air in the cool air passage R1 can directly flow into the air mix space R3 from the opening 19a of the partition wall 19, and the warm air from the warm air passage R2 can also flow in. In the air mix space R3, conditioned air having a desired temperature is generated by mixing cold air and hot air.

  A temperature adjustment damper 20 for adjusting the temperature of the conditioned air is disposed inside the casing 4. The temperature control damper 20 includes a support shaft 20a that extends in the left-right direction and is rotatably supported by the casing 4, and a closing plate portion 20b that extends in the radial direction of the support shaft 20a. The blocking plate 20b is for opening and closing the opening 19a of the partition wall 19 and the upstream end of the warm air passage R2. The temperature adjustment damper 20 is fully cold (see FIGS. 5 and 6) in which the opening 19a of the partition wall 19 is fully opened and the upstream end of the warm air passage R2 is fully closed by the rotation of the support shaft 20a. And a fully hot state (shown in FIGS. 13 and 14) in which the opening 19a of the partition wall 19 is fully closed and the upstream end of the warm air passage R2 is fully open. ing. By adjusting the rotation angle of the temperature adjustment damper 20, the opening degree of the opening part 19a of the partition wall 19 and the opening degree of the upstream end part of the warm air passage R2 are changed. As a result, the amount of cool air and the amount of warm air flowing into the air mix space R3 are changed, so that the temperature of the conditioned air generated in the air mix space R3 can be adjusted.

  The air mix space R3 communicates with the defroster opening 12, the vent outlet duct 13, the heat duct 16, and the rear seat vent duct 17. In the casing 4, a defroster damper 21 is disposed near the defroster opening 12. The defroster damper 21 includes a support shaft 21a that extends in the left-right direction and is rotatably supported by the casing 4, and two closing plate portions 21b and 21b that extend on both radial sides of the support shaft 21a. The defroster damper 21 is rotated around the support shaft 21a so that the defroster opening 12 is opened and closed by the closing plate portions 21b and 21b.

  A heat damper 22 is disposed inside the heat duct 16. The heat damper 22 includes a support shaft 22a that extends in the left-right direction and is rotatably supported by the casing 4, and two closing plate portions 22b and 22b that extend on both sides in the radial direction of the support shaft 22a. As the heat damper 22 rotates around the support shaft 22a, the heat duct 16 is opened and closed by the closing plate portions 22b and 22b.

  Next, the structure of the vent damper unit 40 will be described. The vent damper unit 40 constitutes a part of the vehicle air conditioner 1, and is separated from the casing 4 as shown in FIG. 4 and can be detachably attached to the casing 4.

  As shown in FIG. 7 and the like, the vent damper unit 40 has a louver damper 42 composed of a plurality of louvers 41, 41,... And a frame member 43 that holds the louver damper 42. By using the louver damper 42, the vent damper unit 40 can be made thinner and more compact than when a cantilever type damper or a butterfly type damper is used.

  Since the frame member 43 is composed of a single resin part, the frame member 43 has a structure in which there is no seam around and the air hardly leaks. On the inner side of the frame member 43, a left air circulation port B1, a right air circulation port B2, a central left air circulation port B3, and a central right air circulation port B4 through which conditioned air generated in the casing 4 circulates in the left-right direction. It is formed to line up. Between the left air circulation port B1 and the central left air circulation port B3, between the central left air circulation port B3 and the central right air circulation port B4, and between the central right air circulation port B4 and the right air circulation port B2. The partition plates 47 extending in the vertical direction are provided. By providing the partition plate 47, the deformation of the frame member 43 can be suppressed, and the gap between the damper unit attachment port 14 of the casing 4 and the frame member 43 can be reduced.

  The widths of the left air circulation port B1 and the right air circulation port B2 are set to be the same. The widths of the center left air circulation port B3 and the center right air circulation port B4 are also set to be the same. The widths of the left air circulation port B1 and the right air circulation port B2 are set wider than the widths of the central left air circulation port B3 and the central right air circulation port B4.

  The left air circulation port B1, the right air circulation port B2, the central left air circulation port B3, and the central right air circulation port B4 of the frame member 43 are first air circulation ports and are conditioned air supplied to the front seat occupant of the passenger compartment. Is a vent opening for a front seat through which is distributed.

  The frame member 43 has a shape that is long in the left-right direction, and the outer shape of the frame member 43 is formed so as to substantially match the inner shape of the damper unit attachment port 14 of the casing 4. The frame member 43 is attached to the casing 4 while being inserted into the damper unit attachment port 14 of the casing 4.

  The frame member 43 is set so that the dimension in the front-rear direction becomes longer as it goes downward as a whole as shown in FIG. 12, and the frame member 43 is attached to the casing 4 as shown in FIGS. The entire member 43 is accommodated in the vent outlet duct 13. The frame member 43 includes a lower plate portion 43a and an upper plate portion 43b that extend substantially parallel to the left-right direction, and a left plate portion 43c and a right plate portion 43d that extend substantially parallel to the vertical direction. The dimension of the lower plate portion 43a in the air flow direction is set longer than the dimension of the upper plate portion 43b in the air flow direction. In addition, the entire frame member 43 is inclined so that the lower plate portion 43a is positioned on the rear side of the upper plate portion 43b in the attached state to the casing 4.

  The lower plate portion 43a of the frame member 43 is along the lower wall portion of the vent blowing duct 13, the upper plate portion 43b is along the upper wall portion of the vent blowing duct 13, and the left plate portion 43c is Along the left wall portion of the vent blowing duct 13, the right plate portion 43 d is along the right wall portion of the vent blowing duct 13.

  As shown in FIG. 10, lower engagement holes (engagement portions) 43 g are formed on the left and right sides of the lower plate portion 43 a of the frame member 43, respectively. A protrusion 13a (shown in FIG. 5) provided on the lower wall portion of the vent outlet duct 13 in the casing 4 is inserted into the lower engagement hole 43g. Further, as shown in FIG. 9, upper engagement holes (engagement portions) 43 h are respectively formed on the left and right sides of the upper plate portion 43 b of the frame member 43. A protrusion 13a provided on the upper wall portion of the vent outlet duct 13 in the casing 4 is inserted into the upper engagement hole 43h. With the protrusions 13a inserted into the lower and upper engagement holes 43g and 43h, the peripheral portions of the lower and upper engagement holes 43g and 43h engage with the protrusions 13a, respectively, so Withdrawal is suppressed. When the frame member 43 is attached, the protrusion 13a is inserted into the lower and upper engagement holes 43g and 43h due to elastic deformation of the peripheral portion of the protrusion 13a and the frame member 43.

  As shown in FIG. 7 and the like, a flange 48 extending outward in the radial direction of the air circulation ports B1 to B4 is formed at the peripheral edge portion of the air circulation ports B1 to B4 in the frame member 43. The flange 48 and the partition plate 47 are located on the same plane. The flange 48 extends in the same direction as the flange 15 of the casing 4 and is disposed and positioned in the step portion 15b of the flange 15 as shown in FIG. A surface of the flange 48 facing obliquely rearward is a second seal surface portion 48a. With the vent damper unit 40 attached to the casing 4, the second seal surface portion 48a is continuous along the inner periphery of the first seal surface 15a. The second seal surface portion 48a and the first seal surface portion 15a of the flange 15 of the casing 4 are formed so as to be located on substantially the same surface.

  And the sealing member S is provided ranging from the peripheral part of the damper unit attachment port 14 in the casing 4 to the peripheral part of the air circulation ports B1 to B4 in the frame member 43. As shown in FIG. 2, the seal member S is interposed between the casing 4 and the upstream end of the front seat vent duct A, and is made of an elastic material made of, for example, urethane foam or rubber.

  That is, the seal member S has a substantially rectangular frame shape that conforms to the shapes of the first seal surface portion 15a and the second seal surface 48a, and the seal surface 15a extends from the first seal surface portion 15a to the second seal surface 48a. , 48a is attached using an adhesive such as a double-sided tape. Thereby, since the gap between the peripheral portion of the damper unit mounting port 14 in the casing 4 and the peripheral portion of the air circulation ports B1 to B4 in the frame member 43 is closed by the seal member S, the inner surface of the vent outlet duct 13 and the frame Air leakage from between the outer surface of the member 43 is suppressed. Further, since the seal member S is attached to both the first seal surface portion 15a and the second seal surface 48a, the gap between the peripheral portion of the damper unit mounting port 14 and the front seat vent duct A is sealed. In addition, the space between the peripheral edge of the air circulation ports B1 to B4 and the front seat vent duct A is also sealed.

  The flange A1 of the vent duct A for the front seat presses the seal member S over the entire circumference thereof to the first seal surface portion 15a and the second seal surface 48a, that is, the peripheral portions of the air circulation ports B1 to B4. As a result, the seal member S is compressed and deformed, and comes into close contact with the entire periphery of the first seal surface portion 15a and the second seal surface 48a, and also on the entire periphery of the flange A1 of the front seat vent duct A. Since it comes into close contact, the space between the frame member 43 and the front seat vent duct A is reliably sealed. The seal member S is also attached to the partition plate 47 of the frame member 43.

  As shown in FIGS. 6 and 10, the lower plate portion 43a of the frame member 43 has a communication port 43e communicating with the upstream end opening portion 17a of the rear seat vent duct 17 so as to penetrate the lower plate portion 43a. Is formed. The communication port 43e is located at the center in the left-right direction of the lower plate portion 43a. The shape of the communication port 43e substantially matches the shape of the upstream end opening 17a of the rear seat vent duct 17. The upstream end opening 17a of the rear seat vent duct 17 communicates with the inside of the frame member 43 through the communication port 43e. The communication port 43e is a second air circulation port and is a rear seat vent opening through which conditioned air supplied to the rear seat occupant of the vehicle compartment circulates.

  Inside the frame member 43, an air guide plate portion 44 is provided below the frame member 43. The air guide plate portion 44 is for partitioning and forming a rear seat upstream vent passage 49 for allowing the conditioned air in the vent blowing duct 13 to flow into the rear seat vent duct 17 in the frame member 43. . The air guide plate portion 44 extends downward from a portion lower than the central portion in the vertical direction of the frame member 43. The wind guide plate portion 44 is curved as a whole so as to be located on the rear side (upstream side in the air flow direction) as it goes upward. Further, the air guide plate portion 44 extends from the left plate portion 43c of the frame member 43 to the right plate portion 43d, and is continuous with the inner surfaces of the left plate portion 43c and the right plate portion 43d. Thereby, the left plate portion 43c and the right plate portion 43d are connected by the air guide plate portion 44, and deformation of the frame member 43 is suppressed.

  As shown in FIG. 7 and the like, an intermediate portion in the left-right direction at the lower edge portion of the air guide plate portion 44 extends to the lower plate portion 43a of the frame member 43 and is continuous with the lower plate portion 43a. On the other hand, the left side portion and the right side portion of the lower edge portion of the air guide plate portion 44 are separated upward from the lower plate portion 43a of the frame member 43 and extend to the front side as shown in FIG. As shown in FIG. 7, a left air passage T1 having a long cross-sectional shape in the left-right direction is formed between the left side portion of the lower edge portion of the air guide plate portion 44 and the lower plate portion 43a of the frame member 43. ing. Since the downstream side of the left air passage T1 communicates with the left air circulation port B1, a part of the lower side of the left air circulation port B1 is constituted by an opening on the downstream side of the left air passage T1. Further, a right air passage T2 similar to the left air passage T1 is formed between the right side portion of the lower edge portion of the air guide plate portion 44 and the lower plate portion 43a of the frame member 43. Since the downstream side of the right air passage T2 communicates with the right air circulation port B2, a part of the lower side of the right air circulation port B2 is constituted by an opening on the downstream side of the right air passage T2. The left air passage T1 and the right air passage T2 are located on both sides of the communication port 43e in the left-right direction (width direction).

  The left air passage T1 and the right air passage T2 are positioned below the louver 41 located at the lower end of the louver damper 42, that is, outside the louver damper 42. For this reason, the left air passage T1 and the right air passage T2 are always open regardless of whether the louver damper 42 is opened or closed. Thereby, conditioned air always flows from the lower side of the frame member 43 into the left air passage T1 and the right air passage T2.

  As shown in FIGS. 5 and 6, the space upstream of the air guide plate 44 in the air flow direction inside the frame member 43 becomes the rear seat upstream vent passage 49, and the rear seat upstream vent. The downstream end of the passage 49 communicates with the communication port 43 e of the lower plate portion 43 a of the frame member 43. The rear vent upstream side vent passage 49 is formed from the left side to the right side of the frame member 43 by the wind guide plate portion 44 extending from the left plate portion 43 c to the right plate portion 43 d of the frame member 43. The air flow in the rear-seat upstream vent passage 49 is directed toward the communication port 43e. Since the communication port 43e is arranged at the central portion in the left-right direction of the frame member 43, air flows to the right and flows into the communication port 43e in the region on the left side of the central portion in the left-right direction of the rear vent upstream vent passage 49. On the other hand, in the region on the right side of the central portion in the left-right direction, air flows to the left, flows into the communication port 43e, and flows downward. Further, in the region of the central portion in the left-right direction of the rear vent upstream side vent passage 49, the air is guided downward by the air guide plate 44 and flows into the communication port 43e while flowing from the front side to the rear side. At this time, since the air guide plate portion 44 is formed in a curved shape, the air flowing through the region in the central portion in the left-right direction of the rear-seat upstream vent passage 49 flows smoothly while gradually changing the direction.

  The louver damper 42 is for changing the opening degree of the air circulation ports B1 to B4. As shown in FIGS. 7 and 8, each louver 41 constituting the louver damper 42 is made of a resin plate formed so as to extend in a direction (left-right direction) intersecting with the air flow direction, and is in the longitudinal direction. It is supported by the frame member 43 so as to rotate around an axis extending in the direction. The louvers 41, 41,... Are made of the same member, and are arranged so as to be lined up and down inside the frame member 43. The plurality of louvers 41, 41,... Are connected to each other by a connecting member (not shown) so that they can be interlocked. By rotating one louver 41, the other louvers 41, 41,. To do. When the louver 41 is rotated until the closed state shown in FIG. 8 is reached, the louver 41 has a posture extending in the vertical direction, and the edges of the louvers 41 adjacent in the vertical direction overlap in the air flow direction to block the air flow. On the other hand, when the louver 41 is rotated until the open state shown in FIG. 7 is reached, the louver 41 assumes a posture extending in the front-rear direction, and a gap is formed between the louvers 41 adjacent to each other in the vertical direction. Air flows through this gap. Since the louver 41 in the open state extends in substantially the same direction as the air flow direction, the louver 41 can guide the air. In addition, the louver 41 in the open state protrudes from the vent blowing duct 13 toward the air mix space R3.

  Since the louver damper 42 includes a plurality of louvers 41, the air circulation ports B1 to B4 are fully closed by combining the louvers 41 while making the louvers 41 have an elongated shape than the air circulation ports B1 to B4. Is possible. Moreover, the opening degree of air circulation port B1-B4 and the opening degree of the communication port 43e are changed by changing the rotation angle of the louver 41. FIG. That is, it is possible to change the opening degree of the air circulation ports B1 to B4 and the opening degree of the communication port 43e which are larger than the shape of the louver 41 while downsizing each louver 41, and each louver 41 becomes small. Therefore, the surrounding space necessary for preventing the louvers 41 from interfering, particularly the space in the air circulation direction, can be narrowed. Therefore, even if the vent damper unit 40 has a plurality of louvers 41, the vent damper unit 40 can be compacted as a whole.

  The louver damper 42 is interlocked with the defroster damper 21 and the heat damper 22. That is, for example, the louver damper 42, the defroster damper 21 and the heat damper 22 are opened and closed by connecting the louver damper 42, the defroster damper 21 and the heat damper 22 by a link member (not shown) and driving the link member by one actuator (not shown). To do. The blowing mode of the vehicle air conditioner 1 can be switched by opening and closing the louver damper 42, the defroster damper 21, and the heat damper 22. As the blowing mode, in addition to the vent mode shown in FIGS. 5 and 6 and the heat mode shown in FIGS. 13 and 14, for example, although not shown, it can be switched to a defroster mode, a bi-level mode, a differential / heat mode, or the like. .

  Next, operation | movement of the vehicle air conditioner 1 comprised as mentioned above is demonstrated. The air-conditioning air sent from the blower unit flows from the air intake port 10 of the casing 4 into the cool air passage R1 of the air passage R and is cooled by the cooling heat exchanger 2. After that, as shown in FIGS. 5 and 6, when the temperature adjustment damper 20 is rotated until it reaches the full cold position, substantially the entire amount of air in the cold air passage R1 flows into the air mix space R3. 5 and 6, the vehicle air conditioner 1 is in the vent mode, the defroster damper 21 and the heat damper 22 are closed, and the louver damper 41 of the vent damper unit 40 is open. Accordingly, substantially the entire amount of air in the air mix space R <b> 3 flows into the vent outlet duct 13. And it flows through the left air circulation port B1, the right air circulation port B2, the center left air circulation port B3 and the center right air circulation port B4 in the frame member 43 of the vent damper unit 40 and flows backward. The air that has circulated through the air circulation ports B1 to B4 flows into the front seat vent duct A, circulates through the center vent outlet and the left and right side vent outlets of the instrument panel, and is supplied to the passenger compartment.

  Also, the air that has flowed particularly downward in the vent blowing duct 13 flows toward the air guide plate portion 44 and flows into the rear vent upstream vent passage 49. Since the rear-seat upstream vent passage 49 extends in the left-right direction, the air that has flowed into the region on the left side of the central portion in the left-right direction of the rear-seat upstream vent passage 49 flows to the right and flows into the communication port 43e. In addition, the air that has flowed into the region on the right side of the central portion in the left-right direction of the rear-seat upstream vent passage 49 flows to the left and into the communication port 43e. Further, in the region of the central part in the left-right direction of the rear-seat upstream vent passage 49, air flows into the communication port 43e while flowing from the front side to the rear side.

  As shown in FIG. 6, the air flowing into the communication port 43 e flows into the rear seat vent duct 17 from the upstream end opening 17 a of the rear seat vent duct 17 and is supplied to the rear seat of the passenger compartment.

  On the other hand, as shown in FIGS. 13 and 14, when the temperature adjustment damper 20 is rotating until it reaches the full hot position, almost the entire amount of air in the cold air passage R1 flows into the hot air passage R2. After being heated, it flows into the air mix space R3. In FIG.13 and FIG.14, the vehicle air conditioner 1 is in heat mode, the louver damper 41 of the defroster damper 21 and the vent damper unit 40 is closed, and the heat damper 22 is open. Therefore, most of the air in the air mix space R3 flows into the heat duct 16 and is supplied to the vicinity of the passenger's feet. When the louver damper 41 of the vent damper unit 40 is closed, the rear-seat upstream vent passage 49 is also closed at the same time, so that air does not flow into the rear-seat vent duct 17.

  In any of the blowout modes, the left air passage T1 and the right air passage T2 of the vent damper unit 40 are always open, so that conditioned air can be constantly supplied to the left and right side vent outlets. Thereby, fogging of the side window of the vehicle can be suppressed.

  In this embodiment, the peripheral edge of the damper unit attachment port 14 in the casing 4 and the peripheral edge of the air circulation ports B1 to B4 in the frame member 43 are sealed by the seal member S. Further, since the seal member S extends from the peripheral edge of the damper unit mounting port 14 in the casing 4 to the peripheral edge of the air circulation ports B1 to B4 in the frame member 43, air from between the casing 4 and the frame member 43 is obtained. Leakage can be suppressed by the same seal member S. Therefore, the sealing performance between the frame member 43 and the casing 4 can be enhanced while suppressing an increase in the number of parts.

  Further, since the seal member S is provided between the peripheral portion of the air circulation ports B1 to B4 in the frame member 43 and the front seat vent duct A, the seal member S allows the frame member 43 and the front seat vent duct to be used. A can also be sealed with A.

  Further, since the seal member S is pasted over the first seal surface portion 15a of the casing 4 and the second seal surface portion 48a of the frame member 43, the pasting position of the seal member S is slightly deviated from the illustrated position. Even so, the seal member S can be affixed to a part of the first seal surface part 15a and at least a part of the second seal surface part 48a, and a sealing property can be secured.

  Further, air circulation ports B1 to B4 and a communication port 43e through which conditioned air flows are formed in the frame member 43 of the vent damper unit 40 attached to the casing 4, and the air circulation ports B1 to B4 are opened toward the rear side. On the other hand, the communication port 43e is opened in a direction different from the air circulation ports B1 to B4, that is, downward. A front seat vent duct A extending substantially rearward is connected to the air circulation ports B1 to B4, and a rear seat vent duct 17 extending downward is connected to the communication port 43e. Thereby, the direction of the flow of conditioned air can be set by the frame member 43 at a stage before flowing out of the casing 4. Therefore, it is not necessary to change the direction of the conditioned air flow largely by setting the shapes of the front seat vent duct A and the rear seat vent duct 17, so that the ventilation resistance of the front seat vent duct A and the rear seat vent duct 17 is reduced. It can reduce and the fall of an air volume can be controlled.

  In the description of this embodiment, the vent opening is opened and closed by the louver damper 41. However, the present invention is not limited to this. For example, although not shown, the defroster opening 12 and the heat duct 16 may be opened and closed by the louver damper. Good.

  The above-described embodiment is merely an example in all respects and should not be interpreted in a limited manner. Further, all modifications and changes belonging to the equivalent scope of the claims are within the scope of the present invention.

  As described above, the vehicle air conditioner according to the present invention can be mounted, for example, in an automobile.

DESCRIPTION OF SYMBOLS 1 Vehicle air conditioner 2 Cooling heat exchanger 3 Heating heat exchanger 4 Casing 14 Damper unit attachment port 15a 1st seal surface part 48a 2nd seal surface part 42 Louver damper 43 Frame member 43e Communication port (2nd air circulation port)
43g Lower engagement hole (engagement part)
43h Upper engagement hole (engagement part)
A Front seat vent duct (air conditioning duct)
B1 to B4 air circulation port (first air circulation port)
S Seal member

Claims (7)

A heat exchanger for adjusting the temperature of air-conditioning air;
A casing for housing the heat exchanger;
A vehicle air conditioner having a first air circulation port through which conditioned air generated in the casing flows, and a damper unit having a frame member that holds a damper that changes the opening degree of the first air circulation port. In the device
In the frame member, a second air circulation port through which conditioned air generated in the casing flows is formed to open in a direction different from the first air circulation port. Vehicle air conditioner. In the vehicle air conditioner according to claim 1,
The first air circulation port is a vent opening for a front seat through which conditioned air supplied to a front seat occupant in the passenger compartment flows.
The vehicle air conditioner, wherein the second air circulation port is a rear seat vent opening through which conditioned air supplied to a rear seat passenger in the passenger compartment flows. In the vehicle air conditioner according to claim 2,
A part of said 1st air circulation port is located in the outer side of the said damper, and is always in the open state, The air conditioner for vehicles characterized by the above-mentioned. The vehicle air conditioner according to claim 3,
The vehicle air conditioner, wherein the first air circulation port is disposed on each side in the width direction of the second air circulation port. In the vehicle air conditioner according to any one of claims 1 to 4,
The vehicle air conditioner, wherein the frame member is inserted into an attachment port formed in the casing from the outside of the casing. In the vehicle air conditioner according to any one of claims 1 to 5,
The casing is formed with an attachment port to be attached in a state where the frame member is inserted,
A vehicle air conditioner, wherein a seal member is provided from a peripheral portion of the mounting port in the casing to a peripheral portion of the first air circulation port in the frame member. The vehicle air conditioner according to claim 6,
The seal member is provided between a peripheral portion of the first air circulation port in the frame member and an air conditioning duct connected to the first air circulation port and guiding conditioned air into the vehicle interior. A vehicle air conditioner that seals between a member and the air conditioning duct.

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