JP2008006877A - Air passage opening/closing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an air passage opening/closing device capable of suppressing the generation of noise when an opening portion opening of an opening/closing door is small, and easily adjusting a flow rate of air. <P>SOLUTION: A first groove portion 288 between a first seal lip 284 provided on a peripheral edge of a door plate portion 282 and an auxiliary lip 286, and a second groove portion 289 between the auxiliary lip 286 and a second seal lip 285 have different width W, W2. Therefore, the generation of regular vortexes of air flowing around the door plate portion 282 can be suppressed, and the generation of noise can be suppressed. The auxiliary lip 286 is provided between the first seal lip 284 and the second seal lip 285, and not provided between the seal lips 284, 285, so that a minute air flow rate can be accurately adjusted. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an air passage opening and closing device that opens and closes an air passage through which air flows.

  As a prior art, there is an air passage opening and closing device disclosed in Patent Document 1 below. In this air passage opening and closing device, the opening provided in the air conditioning case is opened and closed with an opening and closing door, and the opening and closing door body is elastically deformed when the opening and closing door closes the opening, A seal lip for closing a gap between the opening / closing door body and the air conditioning case is provided.

At the tip of the seal lip, a plurality of convex portions are arranged side by side in the direction in which the seal lip extends. As a result, when the opening degree of the opening / closing door, where the wind speed is relatively high, is small, the flow of air that has passed between the seal lip and the outer edge of the opening of the air conditioning case is disturbed, and an air vortex train is generated. Is suppressed to prevent the generation of abnormal noise.
JP 2005-138629 A

  However, in the above-described prior art air passage opening and closing device, the opening of the opening and closing door is opened at the tip of the sealing lip because a plurality of protrusions are arranged side by side in the direction in which the sealing lip extends. When is small, there is a problem that air flows between the plurality of convex portions and it is difficult to control the air flow rate.

  The present invention has been made in view of the above points, and can suppress the generation of abnormal noise when the opening degree of the opening / closing door is small and also adjust the air flow rate when the opening degree of the opening / closing door is small. An object of the present invention is to provide an air passage opening and closing device that can be easily performed.

In order to achieve the above object, in the invention described in claim 1,
A case (21) having openings (26, 27) through which air flows and forming an air passage therein;
An opening / closing door (28) for opening and closing the opening (26, 27),
The open / close door (28)
A door plate (282);
Provided at the periphery of the door plate (282) and elastically deformed by being pressed by the case (211) when the openings (26, 27) are closed, and the door plate (282) and the case (211). An air passage opening and closing device having seal lips (284, 285) that can be closed between
The open / close door (28)
At the periphery of the door plate portion (282), it protrudes outward from the periphery, and extends along the periphery while forming groove portions (288, 289) therebetween, at least one of which is the seal Having three or more protrusions (284, 285, 286) consisting of lips (284, 285);
When the openings (26, 27) are opened, the respective widths (288, 289) of the plurality of grooves (288, 289) determined by the tips (284a, 285a, 286a) of the three or more protrusions (284, 285, 286) ( W1 and W2) are different in adjacent groove portions (288 and 289).

  According to this, when the open / close door (28) opens the openings (26, 27), three or more protrusions including seal lips (284, 285) provided on the periphery of the door plate (282). The plurality of groove portions (288, 289) formed between the portions (284, 285, 286) have different widths (W1, W2) in the adjacent groove portions (288, 289).

  Therefore, the opening / closing door (28) opens the openings (26, 27), and the wind speed of the air flowing between the three or more protrusions (284, 285, 286) and the case (21) is small. Even in a relatively fast case, the occurrence of regular vortex trains of air can be suppressed by the plurality of grooves (288, 289) having unequal widths (W1, W2).

  Thereby, even if it is a case where the opening part opening degree of an opening-and-closing door (28) is small, it can suppress that an abnormal noise generate | occur | produces.

  In addition, the protrusions (286) other than the seal lips (284, 285) for suppressing the occurrence of regular vortex streets of air do not need to be provided on the front end side of the seal lips (284, 285). Even when the door (28) opens the openings (26, 27) and the opening degree is small, the air flow rate can be adjusted with high accuracy.

  In this way, it is possible to suppress the generation of noise when the opening degree of the opening / closing door (28) is small, and to easily adjust the air flow rate when the opening degree of the opening / closing door (28) is small. Can do.

  In the invention according to claim 2, the projection (284) on one end side in the direction (X) perpendicular to the extending direction among the three or more projections (284, 2851, 286) is a seal lip. (284).

  According to this, since the seal lip (284) is disposed at the end in the direction (X) in which three or more protrusions (284, 2851, 286) are arranged, the seal lip (284) is disposed. On the side, the state of closing the opening (261) can be easily formed.

In the invention according to claim 3, in the invention according to claim 2,
The open / close door (28) opens and closes the opening (261) by rotating the door plate (282) around the rotation shaft (281).
Of the three or more protrusions (284, 2851, 286), the protrusions (2851, 286) excluding the seal lip (284) have a turning radius of the tip (2851a, 286a) of the seal lip (284). It is characterized by being smaller than the turning radius of the tip (284a).

  According to this, when the door plate portion (282) is rotated around the rotation shaft (281), the protruding portion (2851, 286) excluding the seal lip (284) in the rotation space of the seal lip (284). ) Rotate. Therefore, it is not necessary to provide a space for the protrusions (2851, 286) except the seal lip (284) to rotate, and the case (21) can be prevented from being enlarged.

  In the invention according to claim 4, the protrusions (284, 285) at both ends in the direction (X) orthogonal to the extending direction among the three or more protrusions (284, 285, 286) are sealed. It is characterized by a lip (284, 285).

  According to this, since the seal lips (284, 285) are disposed at both ends in the direction (X) in which three or more protrusions (284, 285, 286) are arranged, the seal lips (284, 285) are It is possible to easily form a state in which the openings (26, 27) are closed on both sides of the arrangement.

Further, in the invention according to claim 5, in the invention according to claim 4,
The open / close door (28) opens and closes the openings (26, 27) by rotating the door plate (282) around the rotation shaft (281).
Of the three or more protrusions (284, 285, 286), the protrusion (286) excluding the seal lips (284, 285) at both ends has a turning radius (286R) at the tip (286a), and seals at both ends. The tip (284a, 285a) of the tip (284a, 285a) of the lip (284, 285) is smaller than the larger one of the turning radii (284R, 285R).

  According to this, when the door plate portion (282) is rotated around the rotation shaft (281), the seal lip (284, 285) is sealed within the rotation space of the seal lip having the larger rotation radius. The protrusions (2851, 286) excluding the lips (284, 285) and the seal lip having the smaller turning radius rotate. Therefore, it is not necessary to provide a space for the projecting portion (286) except the seal lips (284, 285) to rotate, and the case (21) can be prevented from being enlarged.

  In the invention described in claim 6, the protrusion (286) excluding the seal lips (284, 285) at both ends of the three or more protrusions (284, 285, 286) has a tip (286a). It is characterized in that it projects on the plane (290) connecting the tips (284a, 285a) of the seal lips (284, 285) at both ends or outward from the plane (290).

  According to this, it is possible to reliably form a plurality of grooves (288, 289) having a relatively deep depth. Therefore, it is possible to reliably suppress the generation of regular vortex trains of air and to reliably suppress the generation of abnormal noise.

  In the invention according to claim 7, of the three or more projecting portions (284, 285, 286), the projecting portion (286) excluding the seal lip (284, 285) has one in the extending direction. A notch part (286c) is formed in the part.

  According to this, the air flow is disturbed by the air flowing through the notch (286c), and the generation of regular vortex streets can be further suppressed.

  The invention according to claim 8 is characterized in that the three or more projecting portions (284, 285, 286) are integrally formed.

  According to this, when the seal lip (284, 285) is formed, the protruding portion (286) excluding the seal lip (284, 285) can be easily formed.

  In addition, the code | symbol in the parenthesis attached | subjected to each said means is an example which shows a corresponding relationship with the specific means as described in embodiment mentioned later.

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

  FIG. 1 is a longitudinal sectional view showing a schematic configuration of an indoor unit 1 of a vehicle air conditioner that employs an air passage opening and closing device according to an embodiment to which the present invention is applied. FIGS. It is sectional drawing which shows schematic structure of the air mix door 28 provided in.

  As shown in FIG. 1, the indoor unit 1 of the vehicle air conditioner of the present embodiment is installed in the posture shown in FIG. 1 below the instrument panel in the front part of the vehicle interior, and is roughly divided into a blower unit 10, an air conditioning unit 20, and the like. These two parts are arranged side by side.

  The blower unit 10 is for sucking inside air inside the vehicle compartment or outside air outside the vehicle compartment inside the indoor unit 1, and an inside / outside air switching box (not shown) is arranged in the vehicle width direction (front and back direction in FIG. 1). Has been.

  The blower unit 10 is provided with an electric blower 11. The blower 11 includes a centrifugal multiblade fan 12 and a fan driving motor 13, and the centrifugal multiblade fan 12 is disposed in a scroll casing 14.

  A duct portion 15 that forms a flow path extending from the outlet of the scroll casing 14 is formed on the air flow downstream side of the scroll casing 14 of the blower unit 10. The duct portion 15 is for introducing the blown air blown from the blower unit 10 into the evaporator 22 described later. The duct portion 15 connects the outlet portion of the blower unit 10 to the inlet portion of the air conditioning unit 20.

  The air conditioning unit 20 includes an evaporator (cooling heat exchanger, cooling heat exchanger) 22 and a heater core (heating heat exchanger, heating heat) in one common air conditioning case (corresponding to the case of the present invention) 21. This is a type that incorporates an exchange 23).

  The air-conditioning case 21 is made of a resin molded product having some elasticity and excellent strength, such as polypropylene, and is made up of a plurality of divided case bodies. The divided case body accommodates the heat exchangers 22 and 23 and a device such as a door described later, and then is integrally coupled by a fastening means such as a metal spring clip or a screw to form an air conditioning case 21.

  In the present embodiment, the air conditioning case 21 is integrally formed with the scroll casing 14 and the duct portion 15.

  An air inlet 24 is provided at a front portion of the lower portion of the air conditioning case 21, and air blown from the blower unit 10 flows into the air inlet 24 through the duct portion 15.

  In the air conditioning case 21, the evaporator 22 is disposed at a position immediately after the air inlet 24 so as to cross the entire area of the air passage. As is well known, the evaporator 22 is a heat exchanger (air refrigerant heat exchanger) that cools air by absorbing the latent heat of evaporation of the refrigerant in the refrigeration cycle from the air.

  A heater core 23 is disposed downstream of the evaporator 22 in the air flow (vehicle rear side). The heater core 23 reheats the cold air that has passed through the evaporator 22, and hot engine cooling water (hot water) flows through the heater core 23 and heats the air using the cooling water as a heat source.

  In the air conditioning case 21, a cold air bypass passage 25, which is a bypass passage through which air (cold air) flows by bypassing the heater core 23, is formed above the heater core 23.

  The heater core 23 has a first opening (corresponding to an opening of the present invention) 26 into which air passing through the heater core 23 flows in on the vehicle front side, and a second opening (an opening of the present invention) at the upstream end of the cold air bypass passage 25. 27) is provided with an air mix door 28 for adjusting the air volume ratio between the air passing through the heater core 23 (warm air) and the air passing through the cool air bypass passage 25 (cold air). The air mix door 28 is a so-called butterfly door composed of a rotary shaft 281 rotatably supported by the air conditioning case 21 and two flat door plate portions 282 and 2821 coupled to the rotary shaft 281. It is.

  Cold air that mixes the cold air and the hot air by combining the cold air from the cold air bypass passage 25 and the hot air from the heater core 23 at the downstream side (the vehicle upper side) of the heater core 23 and the cold air bypass passage 25. A mixing space 30 is formed.

  On the upper surface of the air conditioning case 21, a defroster opening 31 is opened at a front portion of the vehicle. The defroster opening 31 is where the temperature-controlled air flows from the cold / hot air mixing space 30. The defroster opening 31 is connected to a defroster outlet through a defroster duct (not shown), and blows wind from the outlet toward the inner surface of the vehicle front window glass.

  On the upper surface of the air conditioning case 21, a face opening 32 is opened at a position on the vehicle rear side of the defroster opening 31. This face opening 32 is where the temperature-controlled air flows from the cold / hot air mixing space 30. The face opening 32 is connected to a face air outlet through a face duct (not shown), and blows wind from the air outlet toward an occupant head in the passenger compartment.

  Further, a foot opening 33 is opened on the side surface of the air conditioning case 21. The foot opening 33 also receives the temperature-controlled air from the cold / hot air mixing space 30. The foot opening 33 is connected to a foot outlet through a foot duct (not shown), and blows wind from the outlet toward the passenger's feet in the passenger compartment.

  A face defroster door 34 for opening and closing both openings 31 and 32 is disposed between the defroster opening 31 and the face opening 32 in the air conditioning case 21. The face defroster door 34 is a so-called cantilever door configured by a rotating shaft 341 rotatably supported by the air conditioning case 21 and a single flat door plate portion 342 coupled to the rotating shaft 341. is there.

  In addition, between the face opening 32 and the foot opening 33 in the air conditioning case 21, the common opening 32 </ b> A and the foot opening 33 communicating with the defroster opening 31 and the face opening 32 are opened and closed. A foot door 35 is provided. The foot door 35 is a so-called butterfly door configured by a rotating shaft 351 rotatably supported by the air conditioning case 21 and two flat door plate portions 352 and 353 coupled to the rotating shaft 351. .

  The defroster opening 31, the face opening 32, and the foot opening 33 are opened and closed by a face defroster door 34 and a foot door 35, which are two blowing mode doors, and each opening 31, 32, according to the set blowing mode. The air volume ratio sent out from 33 is adjusted.

  In the above-described configuration, the first opening 26 and the second opening 27 correspond to the opening in the present embodiment, and the air mix door 28 corresponds to an open / close door that opens and closes both the openings 26 and 27. The defroster opening 31 and the face opening 32 also correspond to the openings in the present embodiment, and the face defroster door 34 corresponds to an opening / closing door that opens and closes both the openings 31 and 32. Further, the common opening 32A and the foot opening 33 also correspond to the opening in the present embodiment, and the foot door 35 corresponds to an opening / closing door that opens and closes both the openings 32A and 33. The rotation shafts 281, 341, and 351 correspond to the rotation shafts referred to in the present invention.

  The door plate portions 282, 2821, 342, 352, 353 of the respective opening / closing doors are provided with seal structure portions having a characteristic structure to which the present invention is applied at the respective peripheral edges. Since the configurations of these seal structures are the same, the configuration will be described below using the air mix door 28.

  As described above, the air mix door 28 according to the present embodiment includes the rotary shaft 281 rotatably supported by the air conditioning case 21 (see FIG. 1) and the rotary shaft 281 as illustrated in FIG. It has flat door plate portions 282 and 2821 that are directly connected and extend in the radially outward direction of the rotary shaft 281, and a seal structure portion 283 is formed on the periphery (peripheral portion) of the door plate portions 282 and 2821. (The seal structure on the door plate 2821 side is not shown).

  As shown in the enlarged cross-sectional view of the main part in FIG. 3, the rectangular plate-like door plate portion 282 of the air mix door 28 is disposed on the first opening portion 26 side when closing the first opening portion 26 (see FIG. 1). A first surface 282a to be a surface, a second surface 282b to be a surface on the second opening 27 side when closing the second opening 27 (see FIG. 1), and an end surface (tip surface of the right side tip portion in the drawing) ) 282c. The seal structure portion 283 is formed on the end surface 282c of the door plate portion 282.

  As described above, since the door plate portion 282 has a rectangular shape, in addition to the end surface 282 on the right front end side in the drawing, a similar end surface (side end surface) is also provided on the side end side in the front and back direction of the paper surface (not shown). The same seal structure is formed on these end faces. That is, the seal structure portion 283 whose cross section is shown in FIGS. 2 and 3 is extended along the U-shaped peripheral edge portion of the door plate portion 282.

  The seal structure portion 283 includes a first seal lip 284, a second seal lip 285, an auxiliary lip 286, and a base portion 287. The base portion 287 is a portion joined to the end surface 282c of the door plate portion 282, and the first seal lip 284, the second seal lip 285, and the auxiliary lip 286 project from the base portion 287 outward (rightward in the drawing). Is provided.

  The door plate portion 282 is integrally formed with the rotary shaft 281 and is made of a hard resin having relatively elasticity such as polypropylene. On the other hand, in the seal structure portion 283, the first seal lip 284, the second seal lip 285, the auxiliary lip 286, and the base portion 287 are integrally formed, and are made of a thermoplastic elastomer or rubber having a lower elastic modulus than the door plate portion 282. It is.

  When the air mix door 28 is manufactured, after the rotary shaft 281 and the door plate portion 282 are integrally formed, the seal structure portion 283 is formed in a mold in which the formed body is disposed, and the base portion 287 of the seal structure portion 283 is formed. Are joined and integrated with the end surface 282c of the door plate portion 282.

  Specifically, the main part of the air mix door 28 is such that the first seal lip 284 protrudes outward (upward in the figure) from the door plate part 282 first surface 282a and outward (rightward in the figure) from the end face 282c. The second seal lip 285 is formed so as to protrude outward (downward in the drawing) from the second surface 282a and outward (rightward in the drawing) from the end surface 282c.

  The surface of the first seal lip 284 on the right side in the drawing (tip in the extending direction of the door plate portion 282) 284a (outside as the seal structure portion 283 in the thickness direction of the door plate portion 282 (X direction in the drawing)) When the door plate portion 282 closes the first opening 26 (see FIG. 1), the convex seal portion 284b that contacts the opening peripheral portion 211 (see FIGS. 1 and 4) of the air conditioning case 21 is provided. Is provided.

  In addition, the right end of the second seal lip 285 in the drawing (tip in the extending direction of the door plate portion 282) 285a (outside as the seal structure portion 283 in the thickness direction of the door plate portion 282 (X direction in the drawing)). A convex seal portion 285b that contacts the opening peripheral portion 212 (see FIG. 1) of the air conditioning case 21 when the door plate portion 282 closes the second opening portion 27 (see FIG. 1) is provided on this surface. It has been.

  The first seal lip 284 and the second seal lip 285 have a symmetrical shape with a center line 282d passing through the center of the door plate portion 282 in the thickness direction. That is, the first seal lip 284 and the second seal lip 285 are formed so as to protrude outward from the base 287 in a V shape.

  Between the first seal lip 284 and the second seal lip 285, an auxiliary lip 286 that protrudes outward (rightward in the drawing) from the base 287 is disposed. The auxiliary lip 286 is formed in a wall shape having a substantially uniform thickness, and a center line 286d passing through the center in the thickness direction is offset toward the second seal lip 285 side.

  That is, although the center line 282d of the door plate portion 282 and the center line 286d of the auxiliary lip 286 are parallel to each other, the auxiliary lip 286 is formed so that the center lines do not coincide (do not coincide).

  Due to this arrangement positional relationship, the width W1 of the first groove 288 formed between the first seal lip 284 and the auxiliary lip 286, and the second width formed between the second seal lip 285 and the auxiliary lip 286. The width W2 of the groove 289 is unequal.

  In this example, the thickness of each of the first seal lip 284, the auxiliary lip 286, and the second seal lip 285 is about 1 mm, the width W1 is about 7 mm, and the width W2 is about 5 mm.

  As is clear from FIG. 3, the widths W1 and W2 of the grooves 288 and 289 are the distance between the tip 284a of the first seal lip 284 and the tip 286a of the auxiliary lip 286, and the tip 285a of the second seal lip 285. The distance between the auxiliary lip 286 and the tip 286a is determined.

  In other words, at the periphery of the door plate portion 282, the first seal lip 284, the auxiliary lip 286, and the second seal lip 285 protrude outward from the periphery of the door plate portion 282. Groove portions 288 and 289 are formed between them (while being spaced apart from each other), and are formed as three projecting portions extending along the periphery of the door plate portion 282. The widths W1 and W2 of the two groove portions 288 and 289 determined by the tip ends 284a, 286a, and 285a of the first seal lip 284, the auxiliary lip 286, and the second seal lip 285, which are the three protruding portions, are different. Yes.

  That is, the first protrusions 284a, 286a, and 285a of the first seal lip 284, the auxiliary lip 286, and the second seal lip 285, which are the three protrusions, are orthogonal to the extending direction of the three protrusions (the X direction in the drawing, In the thickness direction of the door plate portion 282, the pitches are unequal.

  As apparent from FIGS. 2 and 3, these three protrusions are formed from the first surface 282 a side of the door plate portion 282 toward the second surface 282 b side, the first seal lip 284, the auxiliary lip 286, The seal lips 285 are arranged in this order. Of the three protrusions, the protrusions at both ends in the direction orthogonal to the extending direction along the periphery of the door plate 282 (the X direction in the drawing) are the first and second seal lips. 284 and 285.

  The auxiliary lip 286 is formed such that its front end 286a is positioned on a plane 290 connecting the front end 284a of the first seal lip 284 and the front end 285a of the second seal lip 285 at both ends in the X direction in the drawing.

  Accordingly, as shown in FIG. 2, the rotation center of the rotation shaft 281 is larger than the distance from the rotation center point 281a of the rotation shaft 281 to the tips 284a and 285a of the first and second seal lips 284 and 285. The distance from the point 281a to the tip 286a of the auxiliary lip 286 is smaller. That is, in the auxiliary lip 286, the turning radius 286R of the tip 286a is smaller than the turning radius 284R of the tip 284a of the first seal lip 284 (equal to the turning radius 285R of the tip 285a of the second seal lip 285). ing.

  Next, the air flow in the main part of the present embodiment will be described based on the above configuration.

  When the air mix door 28 closes the first opening 26, the first seal lip 284 of the seal structure portion 283 is elastically deformed toward the auxiliary lip 286 side by the seal portion 284 b being pressed by the opening peripheral portion 211 of the air conditioning case 21. Then, the first seal lip 284 is in close contact with the opening peripheral edge 211. As a result, the first seal lip 284 closes the space between the air mix door 28 door plate 282 and the air conditioning case 21 opening peripheral portion 211, and the entire amount of the cool air flowing out of the evaporator 22 flows into the second opening 27. .

  On the other hand, when the air mix door 28 closes the second opening portion 27, the second seal lip 285 of the seal structure portion 283 is pushed toward the auxiliary lip 286 side by the seal portion 285b being pressed by the opening peripheral portion 212 of the air conditioning case 21. Due to elastic deformation, the second seal lip 285 is in close contact with the opening peripheral edge 212. As a result, the second seal lip 285 closes the space between the air mix door 28 door plate 282 and the air conditioning case 21 opening peripheral portion 212, and the entire amount of cold air flowing out of the evaporator 22 flows into the first opening 26. Then, it is reheated by the heater core 23.

  Here, a case where the air mix door 28 opens the first opening 26 with a small opening will be described. As shown in FIG. 4, when the air mix door 28 slightly opens the first opening portion 26, the air mix door 28 is relatively positioned between the seal structure portion 283 of the air mix door 28 and the opening peripheral portion 211 of the air conditioning case 21. An air flow with a high wind speed is generated.

  When passing through the respective leading ends 285a, 286a, and 284a of the second seal lip 285, the auxiliary lip 286, and the first seal lip 284, a part of the main flow is peeled off to form an air flow vortex.

  In the vortex array composed of a plurality of vortices generated at this time, the width W1 (see FIG. 3) of the first groove portion 288 and the width W2 (see FIG. 3) of the second groove portion 289 are not equal. It ’s hard to be.

  When the air mix door 28 opens the second opening 27 with a small opening, an air flow is generated in the direction opposite to that shown in FIG. 4 in the seal structure 283 of the air mix door 28, but the first opening A regular vortex row is not easily formed by the same mechanism as when the portion 26 is opened with a small opening.

  According to the above-described configuration and operation, even if the air mix door 28 opens the first and second openings 26 and 27 at a very small opening, the first seal lip 284 and the auxiliary lip 286 By making the width W1 of the first groove portion 288 formed therebetween and the width W2 of the second groove portion 289 formed between the second seal lip 285 and the auxiliary lip 286 different, the first and second groove portions 288, The volume of 289 is also different, and the generation of regular air vortex streets can be suppressed. Therefore, when the opening degree of the air mix door 28 is small, it is possible to suppress the generation of abnormal noise due to the vortex street.

  Further, the auxiliary lip 286 is provided between the first seal lip 284 and the second seal lip 285, and the tips 284a and 285a of both the seal lips 284 and 285 are provided with projections for disturbing the air flow. Not provided. Therefore, even when the opening degree of the air mix door 28 is small, the minute air flow rate can be adjusted with high accuracy.

  In this way, it is possible to suppress the generation of abnormal noise when the opening degree of the air mix door 28 is small, and it is possible to easily adjust the air flow rate with high accuracy.

  Further, since the first and second seal lips 284 and 285 are formed as protruding portions at both ends in the X direction (door plate portion 282 plate thickness direction) in the drawing, the first and second openings 26 and 27 are closed. The state to do can be formed easily.

  Further, the auxiliary lip 286 is formed so that the tip 286a thereof is positioned on a plane 290 connecting the tip 284a of the first seal lip 284 and the tip 285a of the second seal lip 285 at both ends in the X direction in the drawing. The turning radius 286R of the tip 286a of the 286 is smaller than the turning radius 284R of the tip 284a of the first seal lip 284 and the turning radius 285R of the tip 285a of the second seal lip 285.

  Accordingly, the first and second groove portions 288 and 289 are formed relatively deep, and the generation of regular air vortex streets can be reliably suppressed. Further, the auxiliary lip 286 does not interfere with the air conditioning case 21.

  This means that even if the auxiliary lip 286 is provided, it does not protrude outward from the rotation trajectories of the first and second seal lips 284 and 285, and the rotation trajectories of the first and second seal lips 284 and 285. The air conditioning case 21 may be set based on the above. It is not necessary to secure a rotation space only for the auxiliary lip 286, and the size of the air conditioning case 21 does not increase. Therefore, it is possible to prevent a decrease in air conditioning performance and an increase in the vehicle mounting space accompanying an increase in the size of the air conditioning case 21.

  The seal structure portion 283 of the air mix door 28 is formed by integrally forming first and second seal lips 284 and 285, an auxiliary lip 286 and a base portion 287. Therefore, the auxiliary lip 286 can be easily provided when the first and second seal lips 284 and 285 are formed.

  In addition, although the effect based on the structure and operation | movement of the air mix door 28 was demonstrated here, it cannot be overemphasized that the same effect is show | played also in the face defroster door 34 and the foot door 35 of this embodiment.

(Other embodiments)
In the above-described embodiment, the seal structure portion 283 having the same shape in cross section is provided on the periphery of the door plate portion 282 of the air mix door 28. That is, the first seal lip 284, the second seal lip 285, and the auxiliary lip 286 are extended so as to form a protruding wall portion having the same cross section at the periphery of the door plate portion 282.

  However, the auxiliary lip may not be a continuous protrusion having the same cross-sectional shape. For example, as shown in FIG. 5, an auxiliary lip 286 provided with cutout portions 286 c in a part of the extending direction (at a plurality of positions with a predetermined interval) may be employed. According to this, not only the effect of the grooves 288 and 289 having different widths, but also the air flow is disturbed by the air flowing through the notch 286c, so that the generation of regular vortex streets can be further suppressed. .

  In the above embodiment, the front end 286a of the auxiliary lip 286 is disposed on the plane 290 connecting the front end 284a of the first seal lip 284 and the front end 285a of the second seal lip 285, and the first and second groove portions 288 are disposed. 289 is formed relatively deep, and the turning radius 286R of the tip 286a of the auxiliary lip 286 is larger than the turning radius 284R of the tip 284a of the first seal lip 284 and the turning radius 285R of the tip 285a of the second seal lip 285. Also, the auxiliary lip 286 is prevented from interfering with the air conditioning case 21 by reducing the size.

  However, the position of the tip 286a of the auxiliary lip 286 is not limited to the plane 290. For example, as shown in FIG. 6, the tip 286a of the auxiliary lip 286 protrudes outward from the plane 290 connecting the tip 284a of the first seal lip 284 and the tip 285a of the second seal lip 285, and the auxiliary lip The turning radius 286R of the 286 tip 286a may be smaller than the turning radius 284R of the tip 284a of the first seal lip 284 (equal to the turning radius 285R of the tip 285a of the second seal lip 285). Accordingly, the first and second groove portions 288 and 289 having relatively deep depths can be reliably formed, and the auxiliary lip 286 can be prevented from interfering with the air conditioning case 21.

  Further, when the turning radius 284R of the tip 284a of the first seal lip 284 and the turning radius 285R of the tip 285a of the second seal lip 285 are not equal (the protruding lengths of the first and second seal lips are different). In this case, the turning radius 286R of the auxiliary lip 286 tip 286a only needs to be smaller than the larger of the turning radius 284R and the turning radius 285R.

  If there is no problem in increasing the size of the air conditioning case 21, the turning radius 286R of the auxiliary lip 286 tip 286a is the rotation radius 284R of the tip 284a of the first seal lip 284 and the tip 285a of the second seal lip 285. It may be larger than the moving radius 285R.

  Further, if the generation of regular vortex trains of air can be suppressed and generation of abnormal noise can be suppressed to a desired level, the position of the tip 286a of the auxiliary lip 286 is on the inner side of the plane 290 (the door plate portion 282). Or the rotating shaft 281 side).

  In the above embodiment, one auxiliary lip 286 is provided between the first seal lip 284 and the second seal lip 285, and the first groove 288 and the second groove 289 are formed between the three protrusions. However, the number of seal lips and auxiliary lips which are protrusions is not limited to three. Three or more grooves may be formed between four or more protrusions including the seal lip. In this case, if at least the widths of the adjacent groove portions are different, the generation of a regular vortex array of air can be suppressed.

  For example, as shown in FIG. 7, two auxiliary lips 2861, 2862 are provided between the first seal lip 284 and the second seal lip 285, and three grooves 2881, 2882, 2883 are provided between these four protrusions. May be formed. In this case, the width W3 of the groove portion 2882 and the width W4 of the groove portion 2882 are different, and the width W4 of the groove portion 2882 and the width W5 of the groove portion 2883 may be different. If the widths of the adjacent groove portions are different as described above, for example, the width W3 of the groove portion 2881 and the width W5 of the groove portion 2883 may be the same.

  In the above embodiment, the seal structure portion 283 has the two seal lips 284 and 285. However, at least one of the three or more projecting portions may be a seal lip. What is necessary is just to be different in the width | variety of two or more groove parts formed by three or more protrusion parts adjacent. Moreover, it is preferable to arrange | position a seal lip in the one end side in the direction orthogonal to a protrusion part extension direction among three or more protrusion parts. Furthermore, it is preferable that the protrusions excluding the seal lip among the three or more protrusions have a turning radius at the tip smaller than the turning radius at the tip of the seal lip.

  For example, as shown in FIG. 8, a seal structure portion that includes three protrusions with one seal lip 284 and two auxiliary lips 2851, 286 may be adopted for the opening / closing door 28. In this case, as long as the width of the groove 288 formed between the seal lip 284 and the auxiliary lip 286 is different from the width of the groove 2891 formed between the auxiliary lip 286 and the auxiliary lip 2851. Good.

  In addition, as shown in FIG. 8, it is preferable that the seal lip 284 is disposed on one end side in the direction X orthogonal to the protruding portion extending direction among the three protruding portions. According to this, it is possible to easily form a state in which the opening 261 is closed on the side where the seal lip 284 is disposed.

  Further, the two auxiliary lips 2851 and 286 can assist in the rotational space of the seal lip 284 if the rotational radii of the distal ends 2851a and 286a are set to be smaller than the rotational radius of the distal 284a of the seal lip 284. The lips 2851, 286 can be rotated. Therefore, the auxiliary lips 2851 and 286 do not interfere with the air conditioning case, and it is not necessary to provide a space only for the rotation of the auxiliary lips 2851 and 286, so that the air conditioning case can be prevented from becoming large.

  In the above embodiment, the first and second seal lips 284 and 285 and the auxiliary lip 286 are integrally formed. However, they may be separate. For example, the auxiliary lip 286 may be made of resin integrally formed with the door plate portion 282.

  Moreover, in the said one Embodiment, the sealing structure part 283 of the same shape is extended in the whole region of the U-shaped peripheral part which consists of the front end side and the side end side of the door board part 282 of the air mix door 28 which is an opening / closing door. However, the auxiliary lip may be partially provided. An auxiliary lip may be provided only in a portion where an air vortex is likely to occur when air flows through a gap between the air-conditioning case and the opening extending portion of the air-conditioning case. For example, an auxiliary lip may be provided only on the side end portion side of the rectangular door plate portion, or an auxiliary lip may be provided only on the distal end portion side.

  In the above-described embodiment, the air mix door 28 and the foot door 35 as the opening / closing doors are so-called butterfly doors, and the face defroster door 34 as the opening / closing door is a so-called cantilever door. It is not limited to (a form in which the door plate portion extends in the radially outward direction of the rotating shaft).

  For example, as shown in FIG. 9, in a rotary door 128 in which the door plate portion 1282 extends in the circumferential direction centering on the rotating shaft 1281, a seal structure portion 283 is formed on the periphery of the door plate portion 1282, and the seal lip and auxiliary The protrusion part which consists of a lip may be made to protrude to the outward of the direction orthogonal to the door plate part 1282 extending direction from the periphery of the door plate part 1282. Moreover, you may apply this invention to a slide door.

  In the above embodiment, the case where the present invention is applied to the air mix door and the blowout mode door has been described. However, the present invention is also effective when applied to other open / close doors. For example, the present invention may be applied to an inside / outside air switching door of an inside / outside air switching box.

  In the above-described embodiment, the present invention is applied to the air passage opening / closing device of the vehicle air conditioner. However, the present invention is effective when applied to other air passage opening / closing devices. For example, it may be applied to a stationary air conditioner for home use, a store use, a factory use, etc., or may be applied to a ventilation duct other than the air conditioner.

It is a longitudinal section showing a schematic structure of indoor unit 1 of an air-conditioner for vehicles in one embodiment to which the present invention is applied. 3 is a cross-sectional view showing a schematic structure of an air mix door 28 provided in the indoor unit 1. FIG. 3 is an enlarged cross-sectional view of a main part of the air mix door 28. FIG. 4 is a cross-sectional view illustrating the air flow in the main part of the air mix door 18. FIG. It is a principal part expanded sectional view of the opening-and-closing door in other embodiments. It is a principal part expanded sectional view of the opening-and-closing door in other embodiments. It is a principal part expanded sectional view of the opening-and-closing door in other embodiments. It is a principal part expanded sectional view of the opening-and-closing door in other embodiments. It is sectional drawing of the opening / closing door in other embodiment.

Explanation of symbols

21 Air-conditioning case (case)
26 1st opening part 27 2nd opening part 28 Air mix door (one of opening and closing doors)
211, 212 Opening edge (part of the case)
281 Rotating shaft (Rotating shaft)
282 Door plate part 283 Seal structure part 284 First seal lip (seal lip, projecting part)
284a Tip (tip of first seal lip)
285 Second seal lip (seal lip, protrusion)
285a Tip (tip of second seal lip)
286 Auxiliary lip (protrusion)
286a Tip (tip of auxiliary lip)
288 First groove (groove)
289 Second groove (groove)
W1 Width of the first groove W2 Width of the second groove

Claims (8)

A case (21) having openings (26, 27) through which air flows and forming an air passage therein;
An opening / closing door (28) for opening and closing the opening (26, 27),
The open / close door (28)
A door plate (282);
Provided at the periphery of the door plate (282) and elastically deformed by being pressed by the case (211) when the openings (26, 27) are closed, and the door plate (282) In the air passage opening and closing device having seal lips (284, 285) capable of closing between the case (211),
The open / close door (28)
At the periphery of the door plate portion (282), it protrudes outward from the periphery and extends along the periphery while forming groove portions (288, 289) therebetween, at least one of which Having three or more protrusions (284, 285, 286) consisting of seal lips (284, 285);
Each of the plurality of groove portions (288, 289) determined by the tips (284a, 285a, 286a) of the three or more protrusions (284, 285, 286) when the openings (26, 27) are opened. The width (W1, W2) of the air passage is different between the adjacent groove portions (288, 289).   Of the three or more protrusions (284, 2851, 286), the protrusion (284) on one end side in the direction (X) orthogonal to the extending direction is the seal lip (284). The air passage opening and closing device according to claim 1. The opening / closing door (28) opens and closes the opening (261) by rotating the door plate (282) about a rotation shaft (281),
Of the three or more protrusions (284, 2851, 286), the protrusions (2851, 286) excluding the seal lip (284) have a turning radius at the tip (2851a, 286a), and the seal lip (284). 3. The air passage opening and closing device according to claim 1, wherein the air passage opening and closing device is smaller than the turning radius of the tip (284 a).   Of the three or more protrusions (284, 285, 286), the protrusions (284, 285) at both ends in the direction (X) orthogonal to the extending direction are the seal lips (284, 285). The air passage opening and closing device according to claim 1. The opening / closing door (28) opens and closes the opening (26, 27) by rotating the door plate (282) about a rotation shaft (281),
Of the three or more protrusions (284, 285, 286), the protrusion (286) excluding the seal lips (284, 285) at both ends has a turning radius (286R) at the tip (286a). 5. The air passage opening and closing device according to claim 4, wherein each of the distal ends (284a, 285a) of the seal lips (284, 285) has a smaller turning radius (284R, 285R) than the larger one.   Of the three or more protrusions (284, 285, 286), the protrusion (286) excluding the seal lips (284, 285) at both ends has a tip (286a) at the seal lips (284, 285) at both ends. 6. The air passage opening and closing device according to claim 4, wherein the air passage opening and closing device is located on a plane (290) connecting the leading ends (284 a, 285 a) of the two or more on the outer side than the plane (290).   Of the three or more protrusions (284, 285, 286), the protrusion (286) excluding the seal lip (284, 285) has a notch (286c) in part in the extending direction. The air passage opening and closing device according to any one of claims 1 to 6, wherein the air passage opening and closing device is formed.   The air passage opening and closing device according to any one of claims 1 to 7, wherein the three or more protrusions (284, 285, 286) are integrally formed.

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