KR20050120158A - Air conditioner for vehicle - Google Patents

Abstract

In the present invention, a seat evaporator and a seat heater core are disposed in an air flow path, and a vent discharge port, a defrost discharge port, and a floor discharge port for discharging air conditioning air to all the seats in the car interior are formed, and the seat for dividing the air flow path into two regions. A front seat air conditioning case having a front wall and a front seat temporal door configured to independently control a temperature of an area divided by the front seat partition wall, and a front seat mode door configured to control an opening degree of the vent, defrost, and a floor discharge port; A seat air conditioner having a seat blower for blowing air into the seat air conditioner case;

A rear seat evaporator is disposed above the air flow path, a rear heater core is disposed below the rear seat evaporator, and a vent outlet and a floor outlet for discharging air conditioning air to the rear seat of the car are formed, and the air passage is divided into two regions. The rear stone partition wall is divided, and is installed between the rear stone evaporator and the rear heater core to open and close the upstream of the rear stone evaporator and the upstream of the heater core, and to independently control the temperature of the area divided by the rear stone partition wall. A rear seat air conditioner case having a rear seat temporal door and a rear seat mode door for adjusting an opening degree of the vent and the floor outlet;

It provides a vehicle air conditioner comprising a; a rear seat air conditioner having a rear seat blower for blowing air to the rear seat air conditioner case.

Description

Air conditioner for vehicle {Air conditioner for vehicle}

The present invention relates to a vehicle air conditioner for cooling and heating a rear seat of a vehicle, and more particularly, to a multi-zone type vehicle air conditioner capable of rapid temperature change and independently adjustable left and right.

In general, an air conditioner is provided inside a vehicle to heat or cool the inside and outside air to inflow or circulate into the interior of the vehicle to maintain a proper indoor temperature of the vehicle, thereby providing a comfortable ride to the occupant. The air conditioner includes a case provided with a plurality of flow passages for the flow of air sucked therein, and a blower installed and built in one side of the case to blow air in and out of the vehicle into the air conditioning case and blow along the flow passage; An evaporator (Evacore) for cooling the air discharged from the blower through heat exchange, and a heater core for heating the air through the evaporator is basically provided. By placing the evaporator upstream of the heater core in the flow path of the air discharged from the blower, the excess moisture contained in the outside air is removed through the evaporator.

Such a vehicle air conditioner includes a cooling device and a heating device. The cooling process of the cooling device is a heat exchange process in which refrigerant compressed by a compressor driven by an engine power is introduced into the compressor through a condenser, an expansion valve, and an evaporator in turn. It cools to a low temperature state by heat exchange with and flows into a room, thereby cooling the inside of a vehicle. The heating process of the heating device is a heat exchange process in which the coolant that has cooled the engine returns to the engine through the heater core, and the inside and outside air blown by the blower is introduced into the vehicle interior in a warm state by heat exchange between the coolant and the heater core. Heating.

However, in the conventional automotive air conditioner as described above, the air-conditioning air is blown into the interior of the vehicle face face (floor vent) and floor vent (floor vent) is placed in front of the front seat, the cooling efficiency of the rear seat is lowered There has been a problem of not smoothly air-conditioning the entire interior of the vehicle.

An invention for solving the above problems is disclosed in Korean Patent No. 2001-0059264 by the present applicant. According to the prior art disclosed above, an auxiliary air conditioner is provided that operates independently from the main air conditioner to efficiently perform cooling and heating of the rear seat.

A schematic partial perspective view of a vehicle having a main air conditioner and an auxiliary air conditioner of this type is shown in FIG. 1A. The main air conditioner Ma blows air through the wind shield openings 292'a, b, the center and side openings 291'a, b, and the floor openings 293'a, b, and the auxiliary air conditioning Apparatus Aa blows air through the vent and floor discharge ports 12a, b, 13a, b.

The auxiliary air conditioner has an auxiliary evaporator and an auxiliary heater core, each working fluid flowing through these auxiliary evaporators and auxiliary heater cores branched from the main air conditioner and flowing through each auxiliary evaporator and auxiliary heater core. After the air is returned to the main air conditioner, the inflow of the working fluid is controlled by using a solenoid or a water valve to control the temperature of the air conditioning wind.

However, in the prior art as described above, the temperature control of the air conditioning wind is made by inflow and blocking of the working fluid. Therefore, even if the operator fluctuates the desired temperature of the air conditioning wind, the continuity of the working fluid flowing through the auxiliary evaporator and the auxiliary heater core does not immediately respond to the operator's operation, so that the temperature of the air conditioning wind can not be switched quickly, thereby providing a predetermined time delay. By doing so, the problem of lowering the responsiveness of the apparatus was necessarily accompanied.

In addition, the conventional auxiliary air conditioner has a selective operation of the discharge direction in the upper vent mode for blowing the same air-conditioning air passing through the auxiliary evaporator and the auxiliary heater core to the upper half of the rear seat or the lower vent mode for discharging to the lower half of the rear seat. Although possible, the air conditioning wind through the auxiliary evaporator is mixed with the air conditioning wind through the auxiliary heater core alone to implement the temperature adjustment mode, or the bi-level mode (bi-) which discharges cold air through the upper vent and warm air through the lower vent. It was not possible to implement level mode.

In addition, according to the related art, since independent driving of the auxiliary air conditioner is not possible, it is impossible to implement a multi-zone type air conditioning system capable of temperature control according to the left and right regions. In order to realize the multi-zone type air conditioning, it was necessary to have several independent auxiliary air conditioners, which resulted in an increase in the number of parts and an increase in the production process stages, which ultimately raises the production cost significantly. Attaching several devices requires more mounting space, countering the trend toward compact equipment and hindering the workability of equipment installation.

An object of the present invention is to provide a vehicle air conditioner having improved rear responsiveness and having a rear seat air conditioner that can be independently controlled left and right in a compact structure.

Another object of the present invention is to provide a vehicle air conditioner having a simple structure for reducing production cost and improving performance.

In order to achieve the above object, according to an aspect of the present invention, the electrode evaporator and the heater heater core are disposed in the air flow path, and the vent discharge port, the defrost discharge port, the floor discharge port for discharging the air conditioning air to all the seats in the car interior are formed. Become,

A barrier rib for dividing the air flow path into two regions;

A seat air conditioner case having a seat temper door for independently controlling a temperature of a region divided by the seat septum, and a seat mode door for adjusting the opening degree of the vent, defrost and floor discharge ports;

A seat air conditioner having a seat blower for blowing air into the seat air conditioner case;

The rear seat evaporator is disposed above the air flow path, and the rear seat heater core is disposed below the rear seat evaporator.

Vent vents and floor outlets for discharging air conditioning air to the rear seats of the car interior are formed,

A rear stone partition wall dividing the air flow path into two regions;

A rear temper door and the vent and floor installed between the rear evaporator and the rear heater core to open and close the upstream of the rear evaporator and the upstream of the heater core and to independently control the temperature of the area divided by the rear bulkhead. A rear-seat air-conditioning case having a rear-seat mode door for adjusting the opening degree of the discharge port;

It provides a vehicle air conditioner comprising a; a rear seat air conditioner having a rear seat blower for blowing air to the rear seat air conditioner case.

According to another aspect of the invention, the angle formed by the center line of the rear seat evaporator and the rear seat heater core provides a vehicle air conditioner, characterized in that 15 ° to 40 °.

According to another aspect of the present invention, the rear seat door provides a vehicle air conditioner, characterized in that located between the rear blower and the rear evaporator and the rear heater core.

According to another aspect of the present invention, the vent and the floor discharge port of the rear seat air conditioning case provides a vehicle air conditioner, characterized in that the opening degree is controlled by each one of the rear seat mode door in the divided area.

Hereinafter, a vehicle air conditioner according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings. Here, for the sake of clarity, the same reference numerals are given to the same components.

As shown in FIG. 1B, the front seat air conditioner case 280 is downstream of the air flow passage blown from the front seat blower 210, and is configured to heat the front seat evaporator 220 for cooling the blown air and the blown air. The front seat heater core 230 may be disposed.

The air-conditioning case 280 includes a vent discharge port 291a and b extending to the interior of the vehicle, and in particular, the sides and center openings 291'a and b of the vehicle's seats, see FIG. Defrost discharge ports 292a, b extending to the shield openings 292'a and b, and floor discharge ports 293a and b extending to the floor openings 293'a and b are formed. And / or air passing through the front heater core 230 is discharged through these discharge ports. In addition, while the air blown through the front seat blower 210 passes through the front seat evaporator 220 and the front seat heater core 230, the temperature of the flow air is adjusted by the front seat temporal doors 260a and b, and the front seat mode. The outlet of air may be selected through the doors 270a and b.

The air flow passage formed by the front seat air conditioning case 280 is divided into two zones by the front seat partition wall 250, and the two divided zones may be independently controlled. That is, the seat temporal doors 260a and b and the seat mode doors 270a and b are rotated through respective driving means, which are each independently arranged and controlled with the seat partition wall 250 interposed therebetween and not shown, respectively. The indoor seats can be controlled at different temperatures independently from each other, and left and right independent mode control can be performed, such as the left side can be implemented in the defrost mode and the right side can be implemented in the floor mode.

Meanwhile, FIG. 1C shows a schematic exploded perspective view of the rear seat air conditioner 100. The rear seat air conditioner may be arranged in the arm rest between the front left and right seats, or in the lower part of the console box, so as to secure a wide space inside the vehicle, particularly the rear seat and the trunk.

The rear seat air conditioner for a vehicle has a rear seat air conditioning case 1 in which a flow passage is formed so that incoming air flows through the inside.

The rear ventilator 10 is built in the inlet side of the rear seat air conditioning case 1, and the outlet side of the rear seat air conditioning case 1 includes vent outlets 12a and b and floor outlets 13a and b. 1) is provided with a rear stone partition wall 60 that divides the internal air flow path into two regions, that is, the left and right regions. The rear seat blower 10 may be used in various types of blowers, the blower is formed on both sides of the rear seat blower, for example, the air inlet is formed on both sides of the rear seat blower to prevent vibration due to the operation biased to one side and intake more smoothly Preference is given to using.

The rear seat evaporator 20 is disposed downstream of the rear seat blower 10, and the rear seat evaporator 20 reduces humidity by reducing moisture contained in the air discharged from the rear seat blower 10. The rear seat heater core 30 is disposed at a lower position of the rear seat evaporator 20 downstream of the rear seat blower 10. The rear seat evaporator 20 and the rear seat heater cores 30 are arranged such that the angle α formed between their center lines is 15 ° to 40 ° for ease of air flow, efficiency of space layout, and interference between devices. It is preferable.

In addition, between the rear seat evaporator 20 and the rear seat heater core 30, that is, downstream of the rear seat blower 10, at the upstream branch point of the rear seat evaporator 20 and the rear seat heater core 30, the rear seat blower 10 is located. By selecting the flow path of the discharged air, that is, by adjusting the upstream of the rear-side evaporator 20 and the upstream of the rear-side heater core 30, the temperature of the left and right regions divided by the rear-side bulkhead 60 are independently controlled. Temp doors 40a and b are mounted. The temporal doors 40a and b are rotationally driven by an actuator (not shown), for example a step motor, the temporal doors 40a and b closing the inlet to the rear seat evaporator 20. Not only can it be held in a position to close the position and the inlet to the rear seat heater core 30, but it can also be held at any point between these closed positions. The rear seat temporal doors 12a and b are located between the rear seat blower 10, the rear seat evaporator 20, and the rear seat heater core 30 to blow air from the rear seat blower 10 to the rear seat evaporator 20. By selectively flowing any one path according to a temperature selected by a user without passing through the rear-seat heater cores 30, heat loss that may occur during cooling and / or heating of each of the left and right regions may be prevented.

Mode doors 50a and b are disposed downstream of which the flow passage through the rear evaporator 20 merges with the flow passage through the rear heater core 30. The combined flow passage branches back to the starting point of the mode doors 50a and b.

The mode doors 50a and b are also arranged and independently operated one by one with respect to the left and right divided regions, thereby adjusting the opening degrees of the vent outlets 12a and b and the floor outlets 13a and b connected to the lower side. The flow rate of the discharged air can be adjusted. Similar to the temper doors 40a and b, the mode doors 50a and b are also rotationally driven by an actuator not shown, for example, a stepper motor, respectively, which is also used for each branched flow passage. It may be maintained at any point between the positions of closing the inlet. The branched flow passages are connected to the vent discharge ports 12a and b and the floor discharge ports 13a and b, respectively, which are outlets of the rear stone air conditioning case 1.

2a and 2b schematically show a cooling operating state of the rear seat air conditioner according to the present invention. In the present embodiment, for the sake of clarity, it is set that the same control operation is performed on the left and right divided areas, but the present invention is not limited thereto.

Arrows in the figure indicate the flow path of air. 2A is a case where cold air is discharged to the vent discharge port 12. The flow passage inlet to the rear seat heater core 30 is completely closed by rotationally driving the temporal doors 40a and b, and the flow passage inlet to the floor outlet 13 is completely closed by rotationally driving the mode doors 50a and b. The air discharged from the rear seat blower 10 is discharged to the vent outlet 12 through the rear seat evaporator 20 to cool the rear seat space of the vehicle interior. 2B is a case where cold air is discharged through the floor discharge port 13. Unlike the mode door 50a and b positions in FIG. 2A, the mode doors 50a and b drive the mode doors 50a and b to close the flow passage inlet to the vent outlet 13.

3a and 3b schematically show a heating operating state of the rear seat air conditioner according to the present invention. 3A illustrates a case where warm air is discharged through the vent discharge port 12. The temporal doors 40a and b are rotated to close the flow passage inlet to the rear seat evaporator 20, and the mode doors 50a and b are rotated to the opposite direction to close the flow passage inlet to the floor outlet 13. . The air discharged from the rear seat blower 10 is discharged to the vent outlet 12 through the rear seat heater core 30 to heat the rear seat space of the vehicle interior. 3B is a case where warm air is discharged to the floor discharge port 13. Unlike the positions of the mode doors 50a and b in FIG. 3A, the mode doors 50a and b drive the actuators of the mode doors 50a and b so as to close the flow passage inlet to the vent outlet 13. Position the doors 50a and b.

4a and 4b schematically show the temperature regulation operating state of the rear seat air conditioner according to the present invention. 4A and 4B, the temporal doors 40a and b are positioned between both inlets, not in positions where either the inlet of the flow passage inlet to the rear seat evaporator 20 or the flow passage inlet to the rear heater core 30 is closed. At some point. In the case of FIG. 4A, the inlet to the floor outlet 13 is completely closed by the rotationally driven mode door 13, and in the case of FIG. 4B, the inlet to the vent outlet 12 is completely closed by the modely driven door 13. . The cold heat exchanged through the rear stone evaporator 20 and the warm heat exchanged through the rear stone core heater 30 are mixed at the position immediately before the mode doors 50a and b. The air mixed at an appropriate temperature is discharged through the vent discharge port 12 or the floor discharge port 13, thereby keeping the temperature near the rear seats, in particular, almost equal to the vehicle interior temperature set by the operator. In this case, the position of the temporal doors 40a and b, i.e., the rotational angle, is set to satisfy the setting environment such as the temperature set by the operator, which is a temperature sensor disposed at the outlet of the rear air conditioner case 1 or the rear seat of the vehicle interior. The temporal doors 40a and b are controlled by deriving a control signal from a controller (not shown) by using a signal sensed through the signal and a signal set by an operator to drive an actuator.

5 is an operational embodiment for implementing a bi-level mode. As in the case of Figs. 4A and 4B, the temporal doors 40a and b are rotationally driven or maintained to a position between the non-closed positions in order to maintain the air temperature appropriately. On the other hand, in order to implement the bi-level mode, the mode doors 50a and b are rotationally driven and maintained at an approximately intermediate position rather than the position of closing each inlet to the vent outlet 12 or the floor outlet 13. As a result, the cold air passing through the rear seat evaporator 20 is guided to flow to the vent discharge port 12, and the warm air passing through the rear seat heater core 30 is guided to flow to the floor discharge port 13.

The above operation is similarly applied to the case of having the temporal doors 41 and 42 and the mode doors 51 and 52 driving independently from each other, so that the interior area of the vehicle, in particular, the left and right areas of the rear seat space are independent. Can be air-conditioned.

The above embodiments are examples for describing the present invention, and the present invention is not limited thereto. For example, in the case of the front seat air conditioning device and the rear seat air conditioning device, various flow paths may be configured. It can also be configured.

According to the vehicle air conditioner of the present invention, by separating the flow path by appropriately adjusting the arrangement of the rear seat evaporator and the rear seat heater core, it is possible to implement a rear seat air conditioner excellent in response responsive to the operator's operation. . In particular, in the heating mode according to the present invention, the air discharged from the rear seat blower flows into the rear seat heater core without passing through the rear seat evaporator, thereby dehumidifying according to the prior art, which is unnecessary in the case of the rear seat air conditioner which normally uses indoor air. By eliminating the process and reducing the airflow resistance as the air flow path shortens, the rear seat air conditioner can respond more quickly to the operator's operation, while maximizing space utilization due to the compact rear seat air conditioner. It may be.

In addition, the present invention, by forming a central partition in the flow passage from the discharge port of the blower to the discharge port of the rear seat air conditioning case, and having independently operated temporal doors and mode doors, only one rear evaporator and rear heater core, etc. Multi-zone independent type of air conditioning, such as independent rear-right control, can be implemented to reduce production costs by reducing the number of parts and reducing the number of working steps.

In addition, the present invention may implement a bi-level mode by appropriately selecting the position of each mode door with respect to the left and right regions.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. . Accordingly, the protection scope of the present invention will be defined by the technical spirit of the appended claims.

1A is a schematic partial perspective view of a vehicle having a vehicle air conditioner according to the prior art;

Figure 1b is a schematic cross-sectional view of the seat air conditioning apparatus according to the present invention,

1C is a schematic exploded perspective view of a rear seat air conditioner according to the present invention;

2a and 2b is a cooling operation state diagram of the rear seat air conditioner according to the present invention,

3a and 3b is a heating operation state diagram of the rear seat air conditioner according to the present invention,

4a and 4b is a temperature control operating state of the rear seat air conditioner according to the present invention,

5 is a bi-level mode operation state of the rear seat air conditioning apparatus according to the present invention.

<Description of the symbols for the main parts of the drawings>

1 ... secondary air conditioning case 10 ... secondary blower

20 ... Secondary evaporator 30 ... Secondary heater core

40 ... temp door 50 ... mode door

60 ... central bulkhead 70 ... selective duct

100 ... seat air conditioner 200 ... seat air conditioner

Claims (4)

The electrodeposition evaporator 220 and the electrode heater core 230 are disposed in the air passage, Vents 291a and b for discharging the air-conditioning air to all the seats in the car interior, defrost discharge ports 292a and b, and floor discharge ports 293a and b are formed, A barrier rib 250 for dividing the air flow path into two regions; A seat air conditioner case having a seat temporal door 260 that independently adjusts the temperature of a region divided by the seat septum, and a seat mode door 270 that adjusts an opening degree of the vent, defrost, and floor discharge holes. 280); A front seat air conditioner (200) having a front seat blower (210) for blowing air into the front seat air conditioning case; The rear seat evaporator 20 is disposed above the air flow path, and the rear seat heater core 30 is disposed below the rear seat evaporator 20. Vent discharge holes 12a and b) and floor discharge holes 13a and b for discharging air-conditioning air to the rear seats of the car interior are formed, A rear stone partition wall 60 for dividing the air flow path into two regions; It is installed between the rear stone evaporator 20 and the rear stone heater core 30 to open and close the upstream of the rear stone evaporator 20 and the upstream of the heater core, respectively, the temperature of the region divided by the rear stone partition wall 60. A rear-seat air conditioning case (1) having a rear-seat temper door (40a, b) for independently adjusting and a rear-seat mode door (50a, b) for adjusting the opening degree of the vent and floor outlets; And a rear seat air conditioner having a rear seat blower (10) for blowing air into the rear seat air conditioning case (1). The method of claim 1, The angle formed by the center line of the rear seat evaporator (20) and the rear seat heater core (30) is 15 ° to 40 °, characterized in that the vehicle air conditioner. The method of claim 1, The rear seat temper (40a, b) is a vehicle air conditioner, characterized in that located between the rear blower (10) and the rear seat evaporator (20) and the rear seat heater core (30). The method of claim 1, Ventilation and floor discharge port of the rear seat air conditioning case, the opening degree of the vehicle, characterized in that the opening degree is adjusted by each one of the rear seat mode door (50a, b).