JP2010120441A - Air-conditioning wind blow-off mechanism - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an air-conditioning wind blow-off mechanism capable of improving the blow-off efficiency of air-conditioning wind even if three blow-off ports are switched to open states and closed states. <P>SOLUTION: The air-conditioning wind blow-off mechanism is provided at the downstream side in a case in an air conditioner for an automobile. The air-conditioning wind blow-off mechanism includes the three blow-off ports 32-34, a mode door 7, and a drive mechanism 8. The mode door 7 switches the three blow-off ports 32-34 to the open states and the close states, and comprises two doors 71, 72. Each of the doors 71, 72 is formed to have a fan-shaped cross section, and configured to turn vertically. The drive mechanism 8 controls the turning movement of the respective doors 71, 72 so that the turning range of respective doors 71, 72 is within a space from one-side ends to other ends of two adjoining blow-off ports. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an air-conditioning air blowing mechanism that blows air-conditioned air from each air outlet by switching and opening and closing three air outlets in an automobile air conditioner that cools and heats the interior of the automobile.

  2. Description of the Related Art Conventionally, an automobile is equipped with an automobile air conditioner that cools and heats the passenger compartment. As an automobile air conditioner, for example, an automobile air conditioner 1 described in Patent Document 1 has been proposed.

In the conditioned air blowing mechanism of the automobile air conditioner 1, three outlets 21, 31, 41 are provided along the movement locus of the mode door 51 at the downstream end of the case 2. The mode door 51 is configured to open and close by switching the three outlets 21, 31, 41 by sliding up and down by the drive mechanism 53.
JP 2001-328419 A

  However, in the conventional air-conditioning wind blowing mechanism, as shown in FIG. 8, the lower end portion 84 of the mode door 51 projects to the downstream side in the case 2 in the differential mode. For this reason, the conditioned air was subjected to resistance by the mode door 51 when passing through the downstream side, and was not efficiently blown out from the differential outlet 21.

  The present invention has been made in view of such conventional problems, and an object thereof is to provide an air-conditioning air blowing mechanism that can improve the air-conditioning air blowing efficiency even if the three air outlets are switched and opened and closed. To do.

  In order to solve the above-described problem, in the conditioned air blowing mechanism according to claim 1 of the present invention, the mode door disposed in the case of the automobile air conditioner is moved by the drive mechanism, and the downstream end of the case is moved. An air-conditioning air blowing mechanism configured to blow out air-conditioned air from each air outlet by switching and opening and closing three air outlets provided along the movement path of the mode door, wherein the mode door includes: Each door is formed in a cross-sectional fan shape and the other in a cross-sectional fan shape or plate shape so that two adjacent air outlets can be switched and opened and closed. The drive mechanism is configured to rotate the doors up and down so that the doors open and close by switching between the two adjacent outlets, and the rotation ranges of the doors are adjacent to each other. One from one end of the air outlet to be between to the other end, is characterized by controlling the rotation of each door.

  Moreover, in the air-conditioning air blowing mechanism according to claim 2 of the present invention, in the air-conditioning air blowing mechanism according to claim 1, both the rotation shafts of the two doors are used, and one rotation shaft is the other rotation shaft. The drive mechanism is connected to the two rotation shafts configured coaxially and rotated to rotate the doors up and down. It is characterized by being configured.

  Moreover, in the air-conditioning air blowing mechanism according to claim 3 of the present invention, in the air-conditioning air blowing mechanism according to claim 2, the drive mechanism has two cam holes fixed to the both rotation shafts. A door drive lever, a slider having a pin that engages with each cam hole of the two door drive levers, and the two door drive levers by sliding the slider in accordance with the rotational directions of the two rotary shafts. Drive means for rotating the doors to rotate, and the two door drive levers are formed by opening a space of a predetermined size around the rotation shafts of the both, and the slider is formed in the space. It is characterized by being arranged inside.

  Moreover, in the air-conditioning wind blowing mechanism according to claim 4 of the present invention, in the air-conditioning wind blowing mechanism according to any one of claims 1 to 3, A rotation restricting portion that contacts each door and determines the fully closed position of the door is provided, and the drive is performed so that the rotation of the door stops when the door contacts the rotation restricting portion. It features a mechanism.

  In the air-conditioning air blowing mechanism according to claim 5 of the present invention, in the air-conditioning air blowing mechanism according to claim 4, the two doors are adjacent to each other with the two doors contacting each other. It is characterized by being formed in the same sectional fan shape so as to close the outlet.

  In the air-conditioning air blowing mechanism according to claim 6 of the present invention, in the air-conditioning air blowing mechanism according to claim 5, the two doors are in close contact with at least one of the contact portions of the two doors. It is characterized in that a sealing means is provided.

  In the air-conditioning wind blowing mechanism according to claim 1 of the present invention, the mode door is composed of two upper and lower doors, and the rotation range of each door is from one end to the other end of two adjacent outlets. Set in between. As a result, the mode door does not protrude to the downstream side in the case even when the three air outlets are switched and opened and closed, so the conditioned air is blown out from the air outlet without receiving resistance. Therefore, the air-conditioning air blowing mechanism according to claim 1 can improve the air-conditioning air blowing efficiency even if the three air outlets are switched and opened and closed.

  Moreover, in the air-conditioning wind blowing mechanism according to claim 2 of the present invention, the rotating shafts of the two doors are configured to be coaxial, and a drive mechanism is connected to both the rotating shafts so that each door rotates up and down. Configured to work. Therefore, the air-conditioning wind blowing mechanism according to claim 2 can simplify the connection structure between the drive mechanism and both rotating shafts, compared to the case where the rotating shafts of the two doors are not coaxial. Therefore, the manufacturing cost can be reduced.

  Moreover, in the air-conditioning air blowing mechanism according to claim 3 of the present invention, the two door drive levers of the drive mechanism are formed so that a space is formed around both rotation shafts configured coaxially. A slider was placed in the space. Thereby, the drive mechanism can suppress the axial length as compared with the case where the slider is disposed outside the two door drive levers. Therefore, the air-conditioning air blowing mechanism according to claim 3 can reduce the thickness of the driving mechanism.

  Moreover, in the air-conditioning wind blowing mechanism according to claim 4 of the present invention, a rotation restricting portion is provided at each peripheral edge of the three outlets, and the drive mechanism is provided when each door comes into contact with each turning restricting portion. The rotation of the door was stopped. Therefore, the drive mechanism can easily control the rotation range of each door as compared with the case where there is no rotation restricting portion. Therefore, the air-conditioning air blowing mechanism according to claim 4 can easily improve the air-conditioning air blowing efficiency.

  Moreover, in the air-conditioning wind blowing mechanism according to claim 5 of the present invention, the two doors are formed in the same type of cross-sectional fan shape, and the two doors come into contact with each other so as to block the two outlets adjacent to each other. did. Therefore, the air-conditioning air blowing mechanism according to claim 5 can suppress the rotation range of the two doors as compared with the case where the two doors are not in contact with each other and the two adjacent air outlets are closed. Therefore, the space occupied by the mode door in the case can be suppressed. Therefore, the air-conditioning wind blowing mechanism according to claim 5 can further reduce the size of the case.

  Moreover, in the air-conditioning wind blowing mechanism according to claim 6 of the present invention, at least one of the contact portions of the two doors is provided with sealing means for bringing the two doors into close contact with each other. As a result, the two doors can completely block the two adjacent air outlets, so that the conditioned air can be prevented from leaking from the two air outlets. Therefore, the air-conditioning air blowing mechanism according to claim 6 can improve the air-conditioning efficiency.

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

First embodiment:
FIG. 1 is a longitudinal sectional view of an automotive air conditioner 1 showing a first embodiment of the present invention. This automotive air conditioner 1 includes an air conditioner main body 2 and a control device (not shown).

  The air conditioner main body 2 includes a case 3. An air suction port 31 is provided at the upstream end of the case 3. The air inlet 31 takes in air in the vehicle interior and air outside the vehicle interior. In the case 3, an intake door (not shown), a fan (not shown), a cooling heat exchanger 4, a heating heat exchanger 5, and the like are arranged from the side closer to the air inlet 31. .

  The above equipment will be briefly described. First, the intake door switches the air intake port 31 to the vehicle interior side or the vehicle interior side. The fan takes air from the air inlet 31 and sends it to the downstream side. The cooling heat exchanger 4 cools the air sent from the fan using a refrigerant. The heating heat exchanger 5 warms the air that has passed through the cooling heat exchanger 4 using engine cooling water (hot water).

  In the case 3, an air mix door 6 is provided between the cooling heat exchanger 4 and the heating heat exchanger 5. The air mix door 6 adjusts the amount of air that is turned up and down and sent to the heat exchanger 5 for heating.

  Further, on the downstream side in the case 3, an conditioned air generation region 3 s is formed above the heating heat exchanger 5. In the conditioned air generation region 3s, the chilled air generated by passing through the cooling heat exchanger 4 and the warm air generated by passing through the heating heat exchanger 5 are mixed to generate conditioned air A. ing.

  Furthermore, an air-conditioning air blowing mechanism according to the present invention is provided on the downstream side in the case 3. The air-conditioning air blowing mechanism includes three air outlets 32 to 34, a mode door 7, and a driving mechanism 8.

  First, the three outlets 32 to 34 will be described. The three air outlets 32 to 34 are provided along the movement locus of the mode door 7 at the downstream end of the case 3, and are, in order from the top, the differential air outlet 32, the vent air outlet 33, and the foot air outlet 34. Yes.

  Although not shown, the differential outlet 32 is disposed on the instrument panel toward the windshield via a differential nozzle. Although not shown, the vent outlet 33 is disposed toward the front seat on the instrument panel via a vent duct. Although not shown, the foot outlet 34 is disposed toward the feet of the front seat occupant via the foot duct.

  Moreover, the three blower outlets 32-34 are formed in the same magnitude | size. Furthermore, the rotation control parts 35-38 which determine the fully-closed position of each door 71 and 72 are provided in the peripheral part of each blower outlet 32-34. Specifically, a first rotation restricting portion 35 is provided on the right peripheral portion of the differential outlet 32. In addition, a second rotation restricting portion 36 is provided at the peripheral portion on the left side of the differential outlet 32 (the peripheral portion on the upper side of the vent outlet 33). Further, a third rotation restricting portion 37 is provided at the lower peripheral portion (the peripheral portion on the left side of the foot air outlet 34) on the lower side of the vent air outlet 33. Further, a fourth rotation restricting portion 38 is provided at the right peripheral portion of the foot outlet 34. Each rotation restricting portion 35 to 38 protrudes into the case 3.

  Next, the mode door 7 will be described. FIG. 2 is a perspective view of the mode door 7. The mode door 7 opens and closes by switching the three outlets 32 to 34. The mode door 7 is composed of two doors 71 and 72.

  The two doors 71 and 72 are arranged up and down. The 1st door 71 rotates up and down, opens and closes by switching between the differential blower outlet 32 and the vent blower outlet 33, and is formed in cross-sectional fan shape. The second door 72 is pivoted up and down to open and close by switching between the vent outlet 33 and the foot outlet 34. The second door 72 is located inside the first door 71 and is formed in a fan shape in the same shape as the first door 71.

  Further, the two doors 71 and 72 are in contact with each other and are formed so as to block two adjacent outlets, that is, the differential outlet 32 and the vent outlet 33, or the vent outlet 33 and the foot outlet 34. .

  Further, the two doors 71 and 72 are provided with the sealing means of the present invention. In the present embodiment, an inlay type is adopted as the sealing means. This will be described below.

  FIG. 3 is a longitudinal sectional view of the mode door 7, and FIG. 4 is a perspective view of an upper portion of the second door 72. As shown in FIGS. 3 and 4, the upper end surface (opening end surface) of the second door 72 is provided with a recess 72 a throughout. On the other hand, as shown in FIG. 3, a convex portion 71 a is provided on the entire lower end surface (opening end surface) of the first door 71. The convex portion 71a is formed to be able to fit into the concave portion 72a. Therefore, the two doors 71 and 72 are configured to be in close contact by the convex portion 71a and the concave portion 72a.

  FIG. 5 is a longitudinal sectional view showing a connection structure between the rotation shafts 711 and 721 of the two doors 71 and 72 and the drive mechanism 8. A shaft hole 711 a is formed in the rotation shaft 711 of the first door 71. The rotation shaft 721 of the second door 72 is fitted in the shaft hole 711a. Thereby, the two rotating shafts 711 and 721 are configured coaxially. Further, the tip side portion of the rotation shaft 721 of the second door 72 extends from the tip side portion of the rotation shaft 711 of the first door 71, and is inserted through the bearing hole 3 a provided in the case 3. The case 3 is rotatably supported.

  On the other hand, the drive mechanism 8 drives the mode door 7. As shown in FIGS. 5 and 6, the drive mechanism 8 includes a first door drive lever 81, a second door drive lever 82, a slider 83, and drive means 84.

  As shown in FIG. 6, the first door drive lever 81 is formed in a square plate shape. A shaft hole 81 a is formed in the base end portion of the first door drive lever 81. As shown in FIG. 5, the shaft hole 81 a is fitted with a portion on the distal end side of the rotation shaft 711 of the first door 71. A first cam hole 81 b is provided in a portion other than the base end portion of the first door drive lever 81. The first cam hole 81b is formed in a square shape.

  The second door drive lever 82 is formed in a square plate shape. A shaft hole 82 a is formed in the base end portion of the second door drive lever 82. As shown in FIG. 5, the shaft hole 82a is fitted with a portion on the distal end side of the rotating shaft 721 of the second door 72. A second cam hole 82 b is provided in a portion other than the base end of the second door drive lever 82. The second cam hole 82b is formed in a square shape.

  Further, as shown in FIG. 5, a space S having a predetermined size is formed between the drive levers 81 and 82 in the circumferential direction of the rotation shafts 711 and 721. The slider 83 is disposed in the space S. Further, the slider 83 is formed in a flat plate shape as shown in FIG. A first pin 831 is provided on the surface of the slider 83 on the first door drive lever 81 side. The first pin 831 is engaged with the first cam hole 81b as shown in FIG.

  A second pin 832 is provided on the surface of the slider 83 on the second door drive lever 82 side. The second pin 832 is engaged with the second cam hole 82b as shown in FIG. A cable hook 832a is formed at the tip of the second pin 832. The cable hook 832a is formed in a bowl shape.

  On the other hand, as shown in FIG. 7, the drive means 84 includes a cover 841, a drive cable 842, a guide member 843, a drive source (not shown) of the mode door 7, and a drive control unit ( (Not shown).

  The cover 841 is fixed to a predetermined portion outside the case 3 by attaching portions 841a and 841a. Further, the cover 841 holds the slider 83 so as to be slidable in a direction (left-right direction) along the rotation direction of the rotation shafts 711 and 721. A guide hole 841 b is provided on the side surface of the cover 841. The guide hole 841b is formed to be elongated on the left and right. The second pin 832 of the slider 83 is engaged with the guide hole 841a through the second cam hole 82b. A cable clamp 841c is provided on the left side of the guide hole 841b.

  One end of the drive cable 842 is inserted into the guide member 843. Furthermore, the one end side portion is inserted in a state of being inserted into the guide member 843 and held by the cable clamp 841c, and is further locked to the cable hook 832a. Further, the other end portion of the drive cable 842 is connected to the drive source of the mode door 7.

  Next, the basic operation of the drive unit 84 will be described. When the drive source is activated, the drive cable 842 moves left and right. As a result, the slider 83 slides along the cover 841. Accordingly, the two drive levers 81 and 82 are rotated, and the two doors 71 and 72 are rotated.

  On the other hand, the mode door drive control unit controls the turning operation of the two doors 71 and 72 and constitutes a part of the control device. As is well known, the control device controls the operation of the air conditioner main body 2. The control device is connected to the drive source of the mode door 7 described above, the fan, the heat exchanger 4 for cooling, the heat exchanger 5 for heating, the drive door of the intake door, the air mix door 6 and the like. It is comprised so that operation | movement of each door may be controlled.

  An operation unit (not shown) is connected to the control device. The operation unit is provided on an instrument panel (not shown). This operation unit can set various air conditioning modes (bent mode, differential mode, foot mode) and the like.

  Next, the control of the rotation operation of the two doors 71 and 72 by the mode door drive control unit will be specifically described with reference to FIGS.

  The state shown in FIG. 8A is the foot mode. Specifically, the first door 71 fully closes the differential outlet 32, the second door 72 fully closes the vent outlet 33, and the foot outlet 34 is fully open. In this state, as shown in FIG. 9A, the second pin 832 of the slider 83 is located at one end 82c of the second cam hole 82b, and the first pin 831 is one end of the first cam hole 81b. 81c.

  Here, when the air conditioning mode is switched from the foot mode to the vent mode, the slider 83 slides to the right by a predetermined distance as shown in FIG. As a result, the second pin 832 moves to the right by a predetermined distance and is positioned at an intermediate corner portion 82d of the second cam hole 82b. At the same time, the first pin 831 also moves to the right by a predetermined distance and is positioned at the intermediate corner 81d of the first cam hole 81b.

  Therefore, as shown in FIG. 8B, the first door 71 maintains the state where the differential outlet 32 is fully closed. On the other hand, the second door 72 rotates downward (to the right in FIG. 8). Then, the upper end 722 of the second door 72 comes into contact with the third rotation restricting portion 37, the lower end 723 comes into contact with the fourth turn restricting portion 38, and the second door 72 stops. As a result, the vent outlet 33 is fully opened and the foot outlet 34 is fully closed. Thereby, the conditioned air A is blown out from the vent outlet 33.

  Next, when the air conditioning mode is switched from the vent mode to the differential mode, as shown in FIG. 9C, the slider 83 slides to the right by a predetermined distance. As a result, the second pin 832 moves to the right by a predetermined distance and is positioned at the other end 82e of the second cam hole 82b. At the same time, the first pin 831 also moves to the right by a predetermined distance and is positioned at the other end 81e of the first cam hole 81b.

  Therefore, as shown in FIG.8 (c), the 2nd door 72 maintains the state which closed the foot blower outlet 34 fully. On the other hand, the first door 71 rotates downward (rightward in FIG. 8). Then, the upper end portion 712 of the first door 71 comes into contact with the second rotation restricting portion 36, the lower end portion 713 comes into close contact with the second door 72, and the first door 71 stops. As a result, the differential outlet 32 is fully opened and the vent outlet 33 is fully closed. Thereby, the conditioned air A is blown out from the differential outlet 32.

  When the air conditioning mode is switched from the differential mode to the foot mode, the slider 83 slides to the left by a predetermined distance as shown in FIGS. 9C to 9A. As a result, the second pin 832 moves to the left by a predetermined distance and is positioned at one end 82c of the second cam hole 82b. At the same time, the first pin 831 also moves to the left by a predetermined distance and is positioned at one end 81d of the first cam hole 81b.

  Accordingly, as shown in FIGS. 8C to 8A, the first door 71 rotates upward (leftward in FIG. 8). Then, the upper end portion 712 of the first door 71 contacts the first rotation restricting portion 35, the lower end portion 713 contacts the second rotation restricting portion 35, and the first door 71 stops.

  On the other hand, the second door 72 is also rotated upward similarly to the first door 71. Then, the upper end 722 of the second door 72 is in close contact with the first door 71, the lower end 723 comes into contact with the third rotation restricting portion 37, and the second door 72 stops. As a result, the foot outlet 34 is fully opened, and the differential outlet 32 and the vent outlet 33 are fully closed. Thereby, the conditioned air A is blown out from the foot outlet 34.

  Thus, in the air-conditioning wind blowing mechanism of the present embodiment, each door 71, 72 has a rotation range between one end of two adjacent outlets and the other end. 72 rotating operations are controlled.

  More specifically, the rotation range of the first door 71 is from the right end (the upper end in FIG. 8) of the differential outlet 32 to the lower end (the right end in FIG. 8) of the vent outlet 33. Further, the rotation range of the second door 72 is between the upper end (the left end in FIG. 8) of the vent outlet 33 and the right end of the foot outlet 34.

  Therefore, even if the mode door 7 is opened and closed by switching the three air outlets 32 to 34, the mode door 7 is not projected to the downstream side in the case 3 unlike the conventional mode door, so the conditioned air A is resistant. It blows out from each blower outlet 32-34, without receiving. Therefore, the air-conditioning air blowing mechanism of the present embodiment can improve the air-conditioning air A blowing efficiency even if the three air outlets 32 to 34 are switched and opened and closed.

  In the air-conditioning wind blowing mechanism of the present embodiment, the rotation shafts 711 and 721 of the two doors 71 and 72 are configured coaxially, and the drive mechanism 8 is connected to the rotation shafts 711 and 721 that are coaxial. The doors 71 and 72 are connected so as to rotate up and down. Therefore, the air-conditioning air blowing mechanism of the present embodiment can simplify the connection structure between the rotating shafts 711 and 721 of both of the drive mechanisms 8 as compared to the case where both rotating shafts are not configured coaxially. Therefore, the manufacturing cost can be reduced.

  In the air-conditioning air blowing mechanism of the present embodiment, the two drive levers 81 and 82 are formed so that a space S is formed around both the rotation shafts 711 and 721, and the slider 83 is in the space S. It was arranged in. Thereby, the drive mechanism 8 can suppress the axial length 8w (see FIG. 5) as compared with the case where the slider 83 is disposed outside the two drive levers 81 and 82. Therefore, the air-conditioning air blowing mechanism of the present embodiment can reduce the thickness of the drive mechanism 8.

  Further, in the conditioned air blowing mechanism of the present embodiment, the rotation restricting portions 35 to 38 are provided at the peripheral portions of the three outlets 32 to 34, and the doors 71 and 72 are in contact with the rotation restricting portions. In this case, the driving mechanism 8 stops the rotation of the doors 71 and 72. Therefore, the drive mechanism 8 can easily control the rotation ranges of the doors 71 and 72 compared to the case where the rotation restricting portions 35 to 38 are not provided. Therefore, the conditioned air blowing mechanism of the present embodiment can easily improve the efficiency of blowing the conditioned air A.

  Moreover, in the air-conditioning wind blowing mechanism of the present embodiment, the two doors 71 and 72 are formed in the same type of cross-sectional fan shape, and the two doors 71 and 72 come into contact with each other to block two adjacent outlets. I did it. Therefore, the air-conditioning air blowing mechanism of the present embodiment suppresses the rotation range of the two doors 71 and 72 as compared to the case where the two doors are not in contact with each other and the adjacent two outlets are closed. Therefore, the space occupied by the mode door 7 in the case 3 can be suppressed. Therefore, the air-conditioning air blowing mechanism of the present embodiment can reduce the size of the case 3.

  Further, in the air-conditioning air blowing mechanism of the present embodiment, sealing means for bringing the two doors 71 and 72 into close contact with each other is provided at the contact portion between the two doors 71 and 72. Thereby, since the two doors 71 and 72 can completely block two adjacent air outlets, it is possible to prevent the conditioned air A from leaking from the two air outlets. Therefore, the air-conditioning air blowing mechanism of the present embodiment can improve the air-conditioning efficiency.

  In this embodiment, the inlay type is applied as the sealing means. However, the sealing means may not be limited to such an inlay type. For example, the upper side of the first door 71 or the second door 72 A sealing material may be provided on at least one of the end faces.

Second embodiment:
FIG. 10 is a perspective view of the mode door 9 showing the second embodiment of the present invention, and FIG. 11 is a diagram for explaining the operation of the mode door 9. In the present embodiment, the same parts as those in the first embodiment are denoted by the same reference numerals, and different parts are mainly described.

  The mode door 9 according to the present embodiment switches the three outlets 320 to 340 to open and close. In addition, these three blower outlets 320-340 are the differential blower outlet 320, the vent blower outlet 330, and the foot blower outlet 340 in order from the top.

  Moreover, this mode door 9 is comprised from the two doors 71 and 92 similarly to the mode door 7 of 1st Embodiment. The two doors 71 and 92 are arranged up and down. The 1st door 71 rotates up and down, switches the vent blower outlet 330 and the foot blower outlet 340, and opens and closes, and is formed in cross-sectional fan shape. The 2nd door 72 rotates up and down, switches between the differential blower outlet 320 and the foot blower outlet 34, and opens and closes, and is formed in plate shape.

  On the other hand, a rotation restricting portion that determines the fully closed positions of the doors 71 and 92 is provided at the peripheral edge of each of the air outlets 320 to 340. Specifically, a first rotation restricting portion 350 is provided on the right side of the differential outlet 320. A second rotation restricting portion 360 is provided on the right side of the foot outlet 340. A third rotation restricting portion 370 is provided on the left side of the foot outlet 340 (below the vent outlet 330). Each rotation restricting portion 350 to 370 protrudes into the case 3. A fourth rotation restricting portion 380 is provided on the upper side of the vent outlet 330 (on the left side of the differential outlet 320). The fourth rotation restricting portion 380 constitutes a part of the outer wall of the case 3.

  The drive mechanism 80 is for driving the mode door 9. As described with reference to FIGS. 5 to 7 of the first embodiment, the drive mechanism 80 includes two door drive levers 81 and 82, a slider 83, and drive means.

  The driving means of the present embodiment is the same as the driving means 84 described in FIGS. 5 to 7 of the first embodiment, and drives the cover 841, the drive cable 842, the guide member 843, and the mode door 7. And a drive control unit for the mode door 7.

  In the present embodiment, the control of the rotation operation of the two doors 71 and 92 by the mode door drive control unit will be specifically described with reference to FIGS. 9 and 11.

  The state shown in FIG. 11A is the differential mode. Specifically, the first door 71 fully closes the vent outlet 330, the second door 72 together with the first door 71 fully closes the foot outlet 340, and the differential outlet 320 is fully open. . In this state, the slider 83 has two pins 831 and 832 at the positions shown in FIG.

  Here, when the air conditioning mode is switched from the differential mode to the foot mode, as shown in FIG. 9B, the slider 83 slides to the right by a predetermined distance.

  Thereby, as shown in FIG.11 (b), the 1st door 71 maintains the state which closed the vent blower outlet 330 fully. On the other hand, the second door 92 is rotated upward, and comes into contact with the first rotation restricting portion 350 and stops. As a result, the differential outlet 320 is fully closed, and the foot outlet 340 is fully open. Thereby, the conditioned air A is blown out from the foot outlet 340.

  Next, when the air conditioning mode is switched from the foot mode to the vent mode, as shown in FIG. 9C, the slider 83 slides to the right by a predetermined distance.

  Thereby, as shown in FIG.11 (c), the 2nd door 92 maintains the state which closed the foot blower outlet 34 fully. On the other hand, the first door 71 rotates downward. And the lower part 713 of the 1st door 71 contact | abuts to the 2nd rotation control part 360, the upper end part 712 contact | abuts to the 3rd rotation control part 370, and the 1st door 71 stops. As a result, the vent outlet 330 is fully opened and the foot outlet 340 is fully closed. Thereby, the conditioned air A is blown out from the vent outlet 330.

  When the air conditioning mode is switched from the vent mode to the differential mode, the slider 83 slides to the left by a predetermined distance as shown in FIGS. 9C to 9A.

  As a result, as shown in FIGS. 11C to 11A, the first door 71 rotates upward. Then, the upper end 712 of the first door 71 contacts the fourth rotation restricting portion 380, the lower end 713 contacts the third rotation restricting portion 370, and the first door 71 stops. On the other hand, the second door 92 rotates downward, and comes into contact with the second rotation restricting portion 360 and stops. As a result, the differential outlet 320 is fully opened, and the vent outlet 330 and the foot outlet 340 are fully closed. Thereby, the conditioned air A is blown out from the differential outlet 320.

  Thus, in the air-conditioning air blowing mechanism of the present embodiment, each door 71, 92 is configured so that the rotation range of each door 71, 92 is between one end of the two adjacent outlets and the other end. 92 pivoting operations are controlled.

  More specifically, the rotation range of the first door 71 is between the upper end of the vent outlet 330 and the right end of the foot outlet 340. Further, the rotation range of the second door 92 is between the right end of the differential outlet 320 and the right end of the foot outlet 340.

  Therefore, since the mode door 9 does not protrude to the downstream side in the case 3 even if the three outlets 320 to 340 are switched to open and close like the conventional mode door, the conditioned air A has a resistance. It blows out from each blower outlet 320-340, without receiving. Therefore, the air-conditioning air blowing mechanism of the present embodiment can improve the air-conditioning air A blowing efficiency even if the three air outlets 320 to 340 are switched to open and close.

  Further, in the conditioned air blowing mechanism of the present embodiment, the rotation restricting portions 350 to 380 are provided at the peripheral portions of the three outlets 320 to 340, and the doors 71 and 92 are respectively applied to the rotation restricting portions 350 to 380. The drive mechanism 80 stops the rotation of the doors 71 and 92 when coming into contact. Therefore, the drive mechanism 80 can easily control the rotation ranges of the doors 71 and 92 compared to the case where the rotation restricting portions 350 to 380 are not provided. Therefore, the conditioned air blowing mechanism of the present embodiment can easily improve the efficiency of blowing the conditioned air A.

  As mentioned above, although embodiment concerning this invention was illustrated, this embodiment does not limit the content of this invention. Various modifications can be made without departing from the scope of the claims of the present invention.

  FIG. 12 is a longitudinal sectional view showing a connection structure between the drive mechanism 108 and the rotating shafts 711 and 172 a of the two doors 71 and 172 of the mode door 107. Here, the second door 172 has a plate shape or a fan shape in cross section, and a shaft hole 172b is formed in the rotation shaft 172a.

  On the other hand, the base end portion 182a of the second door drive lever 182 is formed in a convex shape in section, and is fitted into the shaft hole 172b of the rotation shaft 172a of the second door 172. Therefore, as shown in FIG. 5, the second door drive lever 182 is placed on the rotation shaft 172 a of the second door 172 in comparison with the case where the second drive lever 82 is fitted on the rotation shaft 721 of the second door 72. Since the axial length 108w of the drive mechanism 108 can be further reduced by the amount of the engagement, the drive mechanism 108 can be thinned.

  As described above, the air-conditioning air blowing mechanism of the present invention can improve the air-conditioning air blowing efficiency even if the three air outlets are switched and opened and closed. Therefore, the air-conditioning wind blowing mechanism of the present invention can be fully utilized in the technical field.

1 is a longitudinal sectional view of an automotive air conditioner showing a first embodiment of the present invention. It is a perspective view of the mode door which shows the embodiment. It is a longitudinal cross-sectional view of the mode door which shows the embodiment. It is a perspective view of the upper part of the 2nd door of the mode door which shows the embodiment. It is a longitudinal cross-sectional view of the connection structure of the rotating shaft and drive mechanism of two doors of the mode door which shows the embodiment. It is a disassembled perspective view of the drive mechanism which shows the embodiment. It is a side view of the drive mechanism which shows the embodiment. It is a figure explaining operation | movement of the mode door which shows the embodiment. It is a figure explaining operation | movement of the drive mechanism which shows the embodiment. It is a perspective view of the mode door which shows the 2nd Embodiment of this invention. It is a figure explaining operation | movement of the mode door which shows the embodiment. It is a longitudinal cross-sectional view which shows the connection structure of the rotating shaft of two doors of the mode door which shows other embodiment of this invention, and a drive mechanism.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Automobile air conditioner 3 Case 7 Mode door 8 Drive mechanism 9 Mode door 32 Differential blower outlet 33 Vent blower outlet 34 Foot blower outlet 35 1st rotation control part 36 2nd rotation control part 37 3rd rotation control part 38 4th rotation control part 71 1st door 71a Convex part 72 2nd door 72a Concave part 80 Drive mechanism 81 1st door drive lever 81b 1st cam hole 82 2nd door drive lever 82b 2nd cam hole 83 Slider 84 Drive means 92 Second door 108 Drive mechanism 172 Second door 172a Rotating shaft of second door 182 Second door drive lever 320 Differential outlet 330 Vent outlet 340 Foot outlet 350 First rotation restricting section 360 Second rotation restricting section 370 Third rotation restricting portion 380 Fourth rotation restricting portion 711 First door rotation shaft 721 Second door rotation shaft 831 First pin 832 second pin A conditioned air S space

Claims (6)

The mode door arranged in the case of the automobile air conditioner is moved by a drive mechanism, and the three outlets provided along the movement path of the mode door are switched at the downstream end of the case to open and close. Is an air-conditioning air blowing mechanism configured to blow air-conditioning air from each outlet,
The mode door is composed of two doors arranged on the top and bottom, and each door is formed in a cross-sectional fan shape, and the other is a cross-sectional fan shape so that two adjacent air outlets can be switched and opened and closed. Or formed into a plate,
The drive mechanism pivots the doors up and down so that the doors open and close the two adjacent outlets, and the range of rotation of the doors is that of the two adjacent outlets. An air-conditioning air blowing mechanism, wherein the rotation operation of each door is controlled to be between one end and the other end. In the air-conditioning wind blowing mechanism according to claim 1,
The rotating shafts of both of the two doors are formed coaxially so that one rotating shaft fits inside the rotating shaft of the other, and the drive mechanism is configured to rotate both the shafts. An air-conditioning wind blowing mechanism characterized in that each door is rotated up and down by connecting to a shaft and rotating the shaft. In the air-conditioning wind blowing mechanism according to claim 2,
The drive mechanism includes two door drive levers fixed to the rotating shafts and having cam holes, a slider having a pin that engages with each cam hole of the two door drive levers, and the slider. Driving means for rotating the two door drive levers by rotating the two doors according to the rotation direction of both rotary shafts, and rotating the doors;
The air-conditioning wind blowing mechanism, wherein the two door drive levers are formed by opening a space of a predetermined size around both the rotation shafts, and the slider is disposed in the space. In the air-conditioning wind blowing mechanism according to any one of claims 1 to 3,
At each peripheral edge of the three air outlets, there is provided a rotation restricting portion that abuts on each door and determines the fully closed position of each door, and when each door abuts on each rotation restricting portion, An air-conditioning air blowing mechanism, wherein the drive mechanism is configured to stop the rotation of each door. In the air-conditioning wind blowing mechanism according to claim 4,
An air-conditioning air blowing mechanism in which the two doors are formed in the same sectional fan shape so that the two doors come into contact with each other and close two adjacent outlets. In the air-conditioning wind blowing mechanism according to claim 5,
An air-conditioning air blowing mechanism characterized in that a sealing means for closely contacting the two doors is provided on at least one of the contact portions of the two doors.

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