KR20190118729A - Blower unit of air conditioner for vehicle - Google Patents

Abstract

Disclosed is an air blower unit of an air conditioner for a vehicle, which can prevent interference between doors, minimize a size in a height direction, and prevent a leak due to wind pressure of introduced air. The air blower unit of an air conditioner for a vehicle includes an intake duct in which an indoor air inlet port and an auxiliary indoor air inlet port for an inflow of indoor air and an outdoor air inlet port for an inflow of outdoor air are formed. Moreover, the air blower unit comprises: a first door configured to adjust an opening rate of a portion of the outdoor air inlet portion and the indoor air inlet port; a second door configured to adjust an opening rate of the other portion of the outdoor air inlet portion; and a third door configured to adjust an opening rate of the auxiliary indoor air inlet port. The second door and the third door are disposed to face each other, and a drive area is vertically disposed to avoid interference of the second door and the third door.

Description

Blower of vehicle air conditioner {BLOWER UNIT OF AIR CONDITIONER FOR VEHICLE}

The present invention relates to a blower of a vehicle air conditioner, and more particularly to a blower of the vehicle air conditioner for selectively transporting the bet or the outside air into the interior of the air conditioning case of the vehicle.

In general, a vehicle air conditioner is a device for heating or cooling an interior by introducing external air into a room or by circulating the indoor air to heat or cool the air conditioner, and a blower for blowing the internal and outdoor air into the air conditioning case, and an air conditioning system. An inside of the case includes an evaporator for cooling action and a heater core for heating action, and selectively blows air cooled or heated by the evaporator or heater core to each part of the vehicle interior.

In Korean Patent Laid-Open Publication No. 10-2011-0136257 (2011.12.21), which has been previously applied, a vehicle blower for introducing a part of the bet even in the outdoor mode by installing an auxiliary door for opening and closing the inlet hole has been disclosed. 1 is a cross-sectional view showing the inside of a blower of a conventional vehicle air conditioner.

As shown in Figure 1, the conventional air conditioner for a vehicle air conditioner is provided with a blower case (1). Blowing case (1) has an internal air inlet 11 through which the internal air is introduced and an external air inlet 12 through which the outdoor air is introduced. The blower case 1 includes a discharge port for discharging internal and external air introduced through the internal air inlet 11 and the external air inlet 12, and a blower fan 23 is provided therein.

The air blow case 1 is formed of an intake duct 10 and a scroll case 20 assembled in the vertical direction. The intake duct 10 has an internal air inlet 11 and an external air inlet 12 formed at an upper portion thereof, an open lower portion thereof, and an internal and outdoor air conversion door 15 for opening and closing the internal and external air inlets 11 and 12 therein. ) Is rotatably installed. Scroll case 20 is coupled to the open lower portion of the intake duct 10, the discharge port is formed on one side is coupled to the inlet side of the air conditioning case.

Inside the scroll case 20, a blowing fan 23 for rotatably blowing inside and outside air introduced into the intake duct 10 to the inlet side of the air conditioning case is installed. An air filter 30 is provided to filter foreign substances in the air flowing into the blower case 1. The lower part of the scroll case 20 is provided with a motor 24 for driving the blowing fan 23.

In the blower case 1, an auxiliary air inlet hole 36 is formed upstream of the blower fan 23 in the air flow direction. The ventilation case 1 is provided with an auxiliary internal door 40. The auxiliary internal door 40 is provided inside the blower case 1, and one side is coupled to an upper portion of the internal air inlet hole 36 to open or close the internal air inlet hole 36 as it flexes flexibly. The air inflow hole 36 introduces a part of the air into the blower case 1 in the outdoor air mode.

In the blower configured as described above, in the internal air mode, the internal and external air switching doors 15 open the internal air inlet 11 and the external air inlet 12 is closed. The bet introduced through the betley inlet 11 by the operation of the blower fan 23 flows into the inside of the blower fan 23 through the air filter 30, and is discharged in a radial direction, and the discharged bet is scroll case 20. It is blown to the air-conditioning case while moving along the inside of the.

In addition, in the external air mode, the internal and external air conversion doors 15 close the internal air inlet 11 and open the external air inlet 12. The outside air introduced through the outside air inlet 12 by the operation of the blowing fan 23 passes through the air filter 30, flows into the inside of the blowing fan 23, and is discharged in a radial direction, and the discharged outside air is a scroll case. It is blown to the air-conditioning case side while moving along the inside of (20). The auxiliary internal door 40 opens the internal air inlet hole 36 by the negative pressure generated in the intake duct 10 when the blowing fan 23 rotates.

The air blower of the conventional vehicle air conditioner requires an effort to reduce the size in the height direction "h" direction, there is a problem that the size reduction is limited due to the operating radius of the door.

In addition, in order to secure an operating space of the auxiliary internal door, a design must be made to avoid interference with the internal and external air conversion doors, and a problem of not limiting the maximum open state of the auxiliary internal door. In addition, there is a problem that leakage occurs due to the air pressure of the air flowing in when the flow path of the internal and external air conversion doors are closed.

Patent Document 1: Republic of Korea Patent Publication No. 10-2011-0136257 (2011.12.21)

In order to solve such a conventional problem, the present invention provides a blower of the vehicle air conditioner that can be reduced in size in the height direction while preventing interference between the doors and to prevent the leakage caused by the wind pressure of the incoming air.

The blower of the air conditioner for a vehicle according to the present invention includes an intake duct formed with an internal air inlet for entering an internal air, an internal air inlet and an internal air inlet for introducing internal air, and controlling a portion of the external air inlet and the opening amount of the internal air inlet. A first door; A second door adjusting an opening amount of another portion of the outside air inlet; And a third door for adjusting the opening amount of the auxiliary bet inlet, wherein the second door and the third door are disposed to face each other, and the driving region is vertically disposed to avoid interference between the second door and the third door. Is placed.

In the above, the seating portion of the second door is disposed above the third door.

In the above, the rotation axis of the second door is disposed below the rotation axis of the third door.

In the above, when the second door is opened, the second door is disposed on the outside air inflow path to perform a guide action.

In the above, when the second door is closed, the closing direction of the second door is configured to be parallel to the flow direction of the air.

In the above, a partition wall disposed between the first door and the second door and partitioning at least a portion of the outside air inflow path and the inside air inflow path is provided.

In the above, the axis of rotation of the second door is located above the extension line of the partition wall.

In the above, the intake duct is composed of an upper case and a lower case, the upper shaft is formed with a rotating shaft fixing portion of the first door and the second door, the sealing surface of the first door and the second door on the upper side of the lower case Is formed.

In the above, the second door is of a flat type, and when the second door is open, an end of the second door is located upward.

The air blower of the vehicle air conditioner according to the present invention can reduce the size in the height direction while preventing interference between the doors, prevents leakage due to the wind pressure of the incoming air, and acts as a small force on the drive unit.

1 is a cross-sectional view showing the inside of a blower of a conventional vehicle air conditioner,
2 is a cross-sectional view showing a blower of the vehicle air conditioner according to an embodiment of the present invention,
3 and 4 are cross-sectional views showing the intake duct according to an embodiment of the present invention,
5 is an enlarged cross-sectional view of a portion of an intake duct according to an exemplary embodiment of the present disclosure.
6 illustrates a bet mode of the blower of the vehicle air conditioner according to an embodiment of the present invention.
7 is a view illustrating an external air mode of the blower of the vehicle air conditioner according to an embodiment of the present invention.

Hereinafter, the technical configuration of the blower of the vehicle air conditioner according to the accompanying drawings in detail as follows.

2 is a cross-sectional view showing a blower of the vehicle air conditioner according to an embodiment of the present invention, Figures 3 and 4 is a cross-sectional view showing an intake duct according to an embodiment of the present invention, Figure 5 is a view of the present invention An enlarged cross-sectional view of a portion of an intake duct according to an exemplary embodiment.

As shown in Figure 2 to 5, the air blower of the vehicle air conditioner according to an embodiment of the present invention is the intake duct 130, the first door 140, the second door 150, and the third A door 160, a blower case 170, an air filter 171, a blower wheel 172, and a blower motor 173 are included.

The blower case 170 is coupled to the lower portion of the intake duct 130 and has an air filter 171, a blower wheel 172, and a blower motor 173 therein. The air filter 171 filters foreign substances in the air passing therethrough. The blower wheel 172 is positioned below the air filter 171, and is coupled to the drive shaft of the blower motor 173 and rotated. As the blower wheel 172 rotates, the inside or outside air introduced through the intake duct 130 is blown to the air conditioner for the vehicle.

The intake duct 130 has an internal air inlet 111 for introducing internal air and an external air inlet 112 for introducing external air. The intake duct 130 is composed of an upper case 110 and a lower case 120. The upper case 110 is formed in a generally dome shape and is fastened to an upper portion of the lower case 120. An inner air inlet 111 is formed on one upper surface of the upper case 110, and an outside air inlet 112 is formed on the other upper surface thereof.

The lower case 120 has an assembly groove formed on the upper surface thereof so as to be assembled with the upper case 110, and has a rectangular frame shape with the upper and lower portions generally opened. A side of the lower case 120 is formed with an auxiliary bet inlet 113 for introducing the bet.

The first door 140 adjusts the opening amount of a portion of the outside air inlet 112 and the inside air inlet 111. The second door 150 adjusts the opening amount of the other part of the outside air inlet 112. The third door 160 adjusts the opening amount of the auxiliary bet inlet 113.

The first door 140 is made of a dome door type, and the rotation shaft 141 of the first door is rotatably installed in the upper case 110. As the first door 140 rotates, the first door 140 may cover the entirety of the internal air inlet 111 and approximately half of the external air inlet 112.

The second door 150 is formed of a flat door type, and the rotating shaft 151 of the second door is rotatably installed in the upper case 120. At the edge of the second door 150, a seal member 152 of rubber material for sealing is formed. The seal member 152 is provided on one surface of the second door 150 and is formed along the edge of the second door 150 to be in close contact with the upper surface of the lower case 120. As the second door 150 rotates, the second door 150 may cover the other half of the outside air inlet 112 not covered by the first door 140.

The partition 125 is formed in the intake duct 130. The partition wall 125 is formed in the lower case 120, and extends upward from an upper surface of the air filter 171. The partition wall 125 is disposed between the first door 140 and the second door 150 and partitions at least a portion of the outside air inflow path and the inside air inflow path.

The partition wall 125 divides the internal air inflow path and the external air inflow path, thereby preventing the outdoor air from flowing back to the interior side through the internal air inlet as the running speed of the vehicle increases in the mode of simultaneously mixing the internal air and the internal air.

The partition wall 125 serves to block outside air from flowing back to the room, but air cannot flow through the opposite flow path partitioned by the partition wall 125 in the betting mode, and thus a part of the air filter 171 cannot be utilized. Eventually, it also has a dysfunction that brings about a decrease in air volume. For example, when the partition wall 125 is installed at approximately 7: 3 portions of the inflow path and the outside air inflow path as shown in FIG. 2, air flows only to 70% of the air filter 171 in the bet mode, and the remaining 30 In%, air cannot flow, resulting in a decrease in the overall air volume.

The auxiliary bet inlet 113 and the third door 160 are intake ducts separately from the inlet inlet through the bet inlet 111 in order to solve the problem of a decrease in the air volume caused by the installation of the partition wall 125. 130) flows inside.

The third door 160 is formed of a flap door type of a flexible material. One end of the third door 160 is fixed to an upper portion of the auxiliary bet inlet 113, and is bent by a negative pressure formed in the intake duct 130 in an external air mode to open the auxiliary bet inlet 113 to open the bet. Inflow into the duct 130. The third door 160 is rotated about a pivot axis, that is, the rotation shaft 161.

When the first door 140 is rotated in the maximum direction in the direction of closing the bet inlet 111 (counterclockwise in FIG. 2), the seal member of the first door 140 is in close contact with the upper side of the lower case 120. Is sealed. When the first door 140 is rotated to the maximum in the direction of opening the bet inlet 111 (clockwise in FIG. 2), the sealing member of the first door 140 is in close contact with the upper side of the lower case 120 to seal the sealing. do.

The second door 150 and the third door 160 are disposed to face each other. In addition, the driving region is disposed up and down so as to avoid interference between the second door 150 and the third door 160. The second door 150 formed at the upper portion of the intake duct 30 has a driving area above the third door 160 formed at the side surface of the intake duct 30. Referring to FIG. 3, the driving region S1 of the second door is located above the driving region S2 of the third door.

The seating part of the second door 150 is disposed above the third door 160. That is, when the second door 150 is rotated to the maximum to close the outside air inflow path (clockwise in FIG. 2), the seal member 152, which is a seating part of the second door 150, may not be formed in the third door 160. It is located above the site.

Therefore, when the second door 150 that controls the flow of the outside air and the third door 160 that controls the flow of the auxiliary bet face each other and are disposed in a relatively narrow space, the second door 150 and the third door ( The operating regions of 160 do not overlap each other, and do not limit the maximum open state of the third door 160.

More preferably, the rotation shaft 151 of the second door 150 is disposed below the rotation shaft 161 of the third door 160. Referring to FIG. 4, the height h1 of the rotation shaft of the second door is disposed at a position lower than the height h2 of the rotation shaft of the third door. The second door 150 is inclined when closed. Therefore, the vertical height of the intake duct 130 can be reduced in size, thereby reducing the overall package.

In addition, when the second door 150 is opened as shown in FIG. 4, the second door 150 is disposed on the outside air inflow path to perform a guide action. That is, when the second door 150 is opened, the end of the second door 150 is located upward. In a state where the second door 150 is opened to the maximum, the second door 150 may be formed in parallel in the extending direction of the partition wall 125. For this reason, the second door 150 may perform a partition function together with the partition wall 125 while also performing a guide action of the outside air.

In addition, when the second door 150 is closed as shown in FIG. 5, the closing direction of the second door 150 is configured to be parallel to the air flow direction. That is, the second door 150 is sealed while the seal member 152 is in close contact with the sealing surface 122 formed on the lower case 120 at the maximum rotation in the direction (clockwise direction in FIG. 5) to close the outside air inflow path. This is done. In this case, the pressing direction of the second door 150 is directed from top to bottom in the same manner as the air flow direction.

Through this configuration, when the second door 150 is turned off, the door sealing structure is formed in the direction opposite to the air wind pressure, so that less force is applied to the driving unit and air leaks can be prevented.

Meanwhile, the rotation shaft 151 of the second door 150 is positioned above the extension line of the partition wall 125. The upper case 110 has rotation shaft fixing portions of the first door 140 and the second door 150. Sealing surfaces of the first door 140 and the second door 150 are formed on the upper surface of the lower case 120. Therefore, since the two doors are driven in the upper case 110, it is not necessary to form a separate rib or sealing portion in the lower case 120, thereby simplifying the mold design.

6 illustrates a betting mode of the blower of the vehicle air conditioner according to an embodiment of the present invention. Referring to FIG. 6, the first door 140 closes the outside air inflow path and opens the inside air inlet 111, and the second door 150 closes the outside air inflow path. The bet is introduced into the intake duct 130 through the bet inlet 111 and the auxiliary bet inlet 113.

7 is a view illustrating an external air mode of the blower of the vehicle air conditioner according to an embodiment of the present invention. Referring to FIG. 7, the first door 140 closes the inside air inlet 111 and opens the outside air inflow path, and the second door 150 opens the outside air inflow path. The outside air introduced through the outside air inlet 112 is partially introduced into the first door 140 based on the partition wall 125, and the other air flows into the second door 150.

The air blower of the vehicle air conditioner according to the present invention has been described with reference to the embodiment shown in the drawings, but this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible. . Therefore, the true technical protection scope should be defined by the technical spirit of the appended claims.

110: upper case 111: bet inlet
112: outside air inlet 113: secondary bet inlet
120: lower case 122: sealing surface
125: bulkhead
S1: drive area of the second door S2: drive area of the third door
130: intake duct 140: first door
150: second door 151,161: rotating shaft
152: seal member 160: third door
170: blower case 171: air filter
172: blower wheel 173: blower motor

Claims (9)

In the blower of the vehicle air conditioner including an intake duct 130 is formed with a bet inlet 111 for introducing the bet and an auxiliary bet inlet 113 and an outside air inlet 112 for introducing the outside air,
A first door 140 for adjusting a portion of the outside air inlet 112 and the opening amount of the inside air inlet 111;
A second door 150 for adjusting an opening amount of another portion of the outside air inlet 112; And
It is provided with a third door 160 for adjusting the opening amount of the auxiliary bet inlet 113,
The second door 150 and the third door 160 are disposed to face each other, the blowing air of the vehicle air conditioner, the driving area is disposed up and down so as to avoid interference between the second door 150 and the third door 160 Device. According to claim 1,
The seating part of the second door 150 is a blower of the vehicle air conditioner is disposed above the third door (160). The method of claim 2,
The rotary shaft 151 of the second door 150 is a blower of the vehicle air conditioner is disposed below the rotary shaft 161 of the third door (160). According to claim 1,
When the second door 150 is open, the second door 150 is disposed on the outside air inflow path to perform a guide action of the vehicle air conditioner. According to claim 1,
When the second door 150 is closed, the blowing direction of the vehicle air conditioner is configured to be parallel to the flow direction of the air of the second door 150. According to claim 1,
The air blower of the vehicle air conditioner is disposed between the first door (140) and the second door (150), and partition wall (125) for partitioning at least a portion of the outside air inlet path and the inside air inlet path. The method of claim 6,
The rotation shaft 151 of the second door 150 is a blower of the vehicle air conditioner is located above the extension line of the partition wall (125). According to claim 1,
The intake duct 130 is composed of an upper case 110 and a lower case 120,
Rotating shaft fixing parts of the first door 140 and the second door 150 are formed in the upper case 110,
Blower of the vehicle air conditioner is formed with a sealing surface of the first door 140 and the second door 150 on the upper side of the lower case (120). The method of claim 4, wherein
The second door 150 is made of a flat type,
When the second door (150) is open, the end of the second door (150) is a blower of the vehicle air conditioner is located toward the top.

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