JPH07132731A - Air conditioner for vehicle - Google Patents

Abstract

PURPOSE:To prevent air conditioning airflow including objectionable smell from being blown off toward an occupant's face. CONSTITUTION:Louvers 5a-5d for changing the blowing-off direction of cooling air from blowing-off parts 4a-4d mounted on an air duct 2 are arranged so as to be turned to the right and left by servo-motors 6a-6d. A control circuit 15 computes the integrated water amount of an evaporator 8 surface based on the detected outputs from the first and second sensors 12 and 13 which detect the temperature of air in the upstream and downstream of the evaporator 8, the blast air amount by a blower 7 and the like, judges if it falls in the condition of objectionable smell generated based on the computed results and the operating condition of the evaporator 8, and if it falls, the louvers 5a-5d are turned through the servomotors 6a-6d so that the blowing-off direction of cooling air from the respective blowing-off ports 4a-4d may avoid an occupant A' or B's face part to the right or left.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vehicle in which a cooling heat exchanger is arranged in an air duct, and cooling air is blown into a vehicle compartment from a vent outlet provided on the most downstream side of the air duct. Regarding air conditioners.

[0002]

2. Description of the Related Art In this type of vehicle air conditioner, when its operation is stopped, odorous substances (dust, mold, etc.) adhering to the heat exchanger diffuse into the air duct.
Since the air stays, air with an offensive odor may be blown out when the operation is restarted, and when the blown air is directed to the occupant's face, the above offensive odor gives offense to the occupant. Points are pointed out.

In order to deal with such a problem, an air conditioner for a vehicle as disclosed in Japanese Patent Laid-Open No. 61-54316 has been conventionally considered. That is,
This device is equipped with an air conditioning duct with a vent outlet that opens toward the occupant's face and other outlets (a foot outlet or an external outlet that communicates with the outside of the vehicle). During the period until the temperature of the heat exchanger becomes equal to or lower than a predetermined temperature (period in which an offensive odor is likely to occur), air is blown out from an outlet other than the vent outlet.

[0004]

Generally, during cooling operation by a vehicle air conditioner, in order to efficiently reduce the temperature inside the vehicle compartment, it is necessary to bring cooling air from the vent outlet. The advantage is well known. However, in the device of the conventional configuration, until a predetermined time elapses after the start of the cooling operation, a state in which the cooling air is not blown out from the vent outlet, that is, a state in which the temperature in the vehicle interior cannot be efficiently reduced Therefore, there is a problem that the cooling speed in the vehicle compartment is reduced by that amount. In short, with the conventional configuration, although it is possible to prevent the air-conditioning air containing an offensive odor from being blown toward the occupants, there is a circumstance in which the rapid effect of the cooling effect in the passenger compartment is reduced, and the occupants can exert the cooling effect early. There was a problem that this could not be realized even if it was desired to be done.

The present invention has been made in consideration of the above circumstances, and it is an object of the present invention to reliably prevent a situation in which conditioned air containing an offensive odor is blown toward the occupant's face at the beginning of the cooling operation. Another object of the present invention is to provide an air conditioning system for a vehicle that enables the effect of cooling the vehicle interior to be exhibited at an early stage.

[0006]

In order to achieve the above object, the present invention comprises a cooling heat exchanger arranged in an air duct, and a vehicle from a vent outlet provided on the most downstream side of the air duct. In a vehicle air conditioner configured to blow cooling air into a room, a wind direction changing unit configured to change a blowing direction of the cooling wind from the vent outlet, and a drive for operating the wind direction changing unit. Means and
A judging means for judging whether or not the heat exchanger satisfies a predetermined offensive odor generating condition, and through the driving means when it is judged that the offensive odor generating condition is satisfied during the cooling operation state. A control means is provided for operating the wind direction changing means so as to change the blowing direction of the cooling air from the vent outlet so as to avoid the occupant's face in the passenger compartment.

[0007]

When the heat exchanger satisfies the predetermined offensive odor generating condition, the judgment means determines that. In the state where such a judgment is made, in the cooling operation state in which cooling air is blown out from the vent outlet,
In the control means, by operating the wind direction changing means through the driving means, the control for changing the blowing direction of the cooling air from the vent outlet to a direction avoiding the occupant's face in the passenger compartment is performed. I will do it. As a result, it is possible to prevent the air-conditioning air containing the offensive odor from the heat exchanger from being blown toward the occupant's face, and eliminate the possibility of giving the occupant an unpleasant odor.
The temperature in the vehicle compartment can be efficiently reduced by the cooling air blown from the vent outlet.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of the present invention will be described below with reference to FIGS. FIG. 1 schematically shows a schematic sectional structure of an automobile air conditioner and an electrical configuration of essential parts. In FIG. 1, the air duct 2 included in the air conditioning unit 1 has an intake port 3 that selectively communicates with an outside air introduction port or an inside air introduction port (neither is shown) at the most upstream side and at the most downstream side. The vent outlet duct 4 is connected to the opening 2a, and the four branch ducts of the vent outlet duct 4 are respectively the center outlets 4a located on the instrument panel of the automobile.
And 4b, the right air outlet 4c, and the left air outlet 4d (each corresponding to the vent air outlet in the present invention). Although not shown, on the most downstream side of the air duct 2,
A heat outlet and a defroster outlet are provided.

Louvres 5a to 5d (corresponding to the wind direction changing means in the present invention) configured to be able to change the blowing direction are attached to each of the outlets 4a to 4d, and these louvers 5a to 5d are attached. Are configured to be rotated in the left-right direction, for example, by servomotors 6a to 6d (corresponding to the driving means in the present invention) provided correspondingly. The louvers 5a to 5d are configured to be rotatable in both left and right and up and down directions by a manual operation.

A blower 7 is provided in the air duct 2 so as to correspond to the suction port 3. In a state where the blower 7 is operated, the air duct 2 is blown into the air duct 2 from the suction port 3 side. The wind that flows in the ~ 4d direction is generated. Further, an evaporator 8 (corresponding to a heat exchanger in the present invention) for cooling the wind generated by the blower 7 is provided in the air duct 2, and the wind is heated on the downstream side thereof. The heater core 9 is provided. In addition to the air mix damper 10 and the vent outlet damper 11, which are each rotated by a servomotor (not shown), an inside / outside air switching damper (not shown) and the like are provided in the air duct 2.

The first sensor unit 12 detects the temperature T1 and the humidity W1 of the upstream air of the evaporator 8, and the second sensor unit 13 detects the temperature T of the downstream air of the evaporator 8.
2 and the humidity W2 are detected, and the temperature sensor 14 is provided so as to detect the temperature T3 of the evaporator 8 (specifically, the pipe wall temperature of the refrigerant inflow side of the evaporator 8), and these detection outputs are controlled. It is adapted to be applied to the circuit 15 (corresponding to the judgment means and the control means in the present invention).

Further, the infrared sensors 16 and 17 provided on the instrument panel are provided so as to be able to detect the presence or absence of the occupant A in the driver's seat and the occupant B in the passenger's seat. It is given to 15.

The control circuit 15 comprises a microcomputer, and controls the operation of the blower 7 and the air flow rate, the operation control of a compressor (not shown) in the refrigeration cycle system including the evaporator 8, Opening / closing control of the air mix damper 10, vent outlet damper 11 and damper (not shown), and the servo motors 6a to 6d.
The operation control of the louvers 5a to 5d is performed through the. In this case, the control circuit 15 performs not only the normal air conditioning operation control based on the command from the control panel 18 but also the control for the offensive odor countermeasure as shown in the flowchart of FIG. 2, which will be described below. To do.

That is, FIG. 2 shows the control contents of only the portion related to the gist of the present invention. The control circuit 15 executes a predetermined initialization step S1 after power-on, and then inputs a cooling operation start command. The presence or absence (step S
2) In the state where the cooling operation start command is stopped, a loop including the damper control step S3 is formed, and in this damper control step S3, the vent outlet damper 11 is operated to operate each outlet. 4a
The control for closing the 4d (that is, the bend outlet) is executed.

When the cooling operation start command is input,
The control circuit 15 detects the temperature T detected by the first sensor unit 12.
1 and detection humidity W1, temperature T2 and detection humidity W2 detected by the second sensor unit 13, temperature T3 detected by the temperature sensor 14, and blower 7 set by the control panel 18.
Is read (step S4), and it is determined whether the evaporator 8 is operating (actually, whether the compressor in the refrigeration cycle system including the evaporator 8 is operating) based on its own control output. Yes (Step S
5).

The control circuit 15 executes an operating water content calculating routine S6 when the evaporator 8 is operating, and executes a stopping water content calculating routine S7 when the evaporator 8 is stopped.

In these calculation routines S6 and S7, the amount of water on the surface of the evaporator 8 is read in the data read in step S4 (the temperature T1 and the humidity W1 of the air on the upstream side of the evaporator 8 and the temperature T2 of the air on the downstream side of the evaporator 8).
And humidity W2, temperature T3 of the evaporator 8, blower 7
It is calculated based on the blown air volume V).

That is, the absolute humidity x1 (Kg / Kg ') of the upstream side air of the evaporator 8 and the absolute humidity x of the downstream side air.
2 (Kg / Kg ') can be obtained by calculation using the temperature T1, the humidity W1 and the temperatures T2, W2 as parameters, and the absolute humidity x thus obtained is calculated.
The amount of water on the surface of the evaporator 8 can be calculated based on 1 and x2. Specifically, the water content D1 when the evaporator 8 is operating can be calculated by the following equation, and the water content D2 when the evaporator 8 is not operating can be calculated by the following equation. However, in the following equation, DA is the specific volume (c
m ³ / μg), Se is the effective surface area (cm ² ) of the evaporator 8.

D1 = {(x1−x2) × V} / (DA × Se) ... D2 = {(x2−x1) × V} / (DA × Se) ... In the operating water content calculation routine S6 , The moisture amount D1 on the surface of the evaporator 8 is calculated by the formula, and the result of multiplying the moisture amount D1 by the time when the temperature T3 is below the dew point temperature is sequentially accumulated, thereby Cumulative water content SD1 during operation
To calculate.

Further, the water content calculation routine at stop S7
Then, the moisture amount D2 on the surface of the evaporator 8 is calculated by the calculation based on the formula, and the integrated moisture amount SD2 when the evaporator 8 is stopped is calculated based on the following formula.

SD2 = L · SD1−D2 · t, where L · SD1 is the final value of the cumulative water content SD1 when the evaporator 8 is operating, and t is the elapsed time immediately after the evaporator 8 (compressor) is stopped. (Sampling time).

That is, since the initial value of the cumulative water content SD2 when the evaporator 8 is stopped is the final value of the cumulative water content SD1 when the evaporator 8 is running, the evaporated water content can be subtracted from this final value. Become. Here, according to the experiments conducted by the inventor of the present application, the end timing of the offensive odor generation after the operation of the evaporator 8 is stopped is not the timing at which the temperature of the evaporator 8 exceeds the dew point temperature, but the timing later than this. Is known. This means that, as can be seen from FIG. 3 showing the change state of the accumulated water content on the surface of the evaporator 8, the water (lattice-shaped hatched portion) accumulated during the operation of the evaporator 8 (when the compressor is on) has a dew-point temperature. It is considered that the evaporation cannot be completed until the temperature rises (point A), and the evaporation is completed at the end timing (point B) of the offensive odor generation after the evaporator 8 is stopped. As described above, the cumulative moisture content SD2 at the end of the offensive odor after the evaporator 8 is stopped has a negative value because the dew point temperature is used as a reference in the above calculation.

Here, the air conditioning unit 1 as in this embodiment
In, the amount of water on the surface of the evaporator 8 is known to be involved in the offensive odor generation. The amount of water on the surface of the evaporator 8 during the air conditioning operation gradually increases with the passage of time after the evaporator 8 starts operating, and gradually decreases with the passage of time after the operation is stopped.
The relationship between the cumulative amount of water on the surface of the evaporator 8 (heat exchanger) and the offensive odor generation region is shown by the result of an experiment (a negative cumulative amount of water indicates the amount of water evaporated during the cumulative period). ). In this experiment, the cumulative amount of water at the time when the offensive odor started to be generated after the operation of the evaporator 8 was started and after the operation was stopped was plotted under a plurality of environmental conditions. It can be seen that the offensive odor generation area is different from that in the stopped state.

As is apparent from FIG. 4, in the operating state of the evaporator 8, the offensive odor generating condition is satisfied when the cumulative water content SD1 in that state satisfies the following equation, and the evaporator 8 In the operation stopped state, it can be seen that the offensive odor generating condition is satisfied when the cumulative water content SD2 in that state has the relationship of the following equation.

0 <SD1 <30 μg / cm ² -20 μg / cm ² <SD2

Thus, the operating water content calculation routine S6
Due to this, the cumulative water content SD1 during operation of the evaporator 8
After calculating, it is determined whether or not the cumulative water content SD1 satisfies the offensive odor generating condition of the above equation (step S8). Further, after the accumulated moisture amount SD2 when the evaporator 8 is stopped is calculated by the stopped moisture amount calculation routine S7, it is judged whether or not the accumulated moisture amount SD2 satisfies the offensive odor generating condition of the above formula (step S
9).

In the state where it is determined to be "YES" in steps S8 and S9, that is, when the accumulated water content on the surface of the evaporator 8 satisfies a predetermined offensive odor generating condition, the vent outlet damper 11 is used to blow each outlet 4a.about. 4d is opened, the detection signals from the infrared sensors 16 and 17 are read (steps S10 and S11), the blowing direction control step S12 is executed based on the read result, and the process returns to step S2.

In the blowing direction control step S12, when the occupant A is detected, the blowing direction of the cooling air from the center outlet 4a and the light outlet 4c avoids the face of the occupant A to the left or right. Direction (solid arrow Ea in FIG. 1,
(See Ec), turn the louvers 5a and 5c,
When the occupant B is detected, the direction in which the cooling air is blown from the center outlet 4b and the left outlet 4d is a direction avoiding the occupant B's face to the right or left (solid arrow E in FIG. 1).
The louvers 5b and 5d are rotated so that the louvers 5b and Ed) are obtained. As a result, the wind that passes through the evaporator 8 that satisfies the offensive odor generation condition is not directly blown out to the face (especially near the nose) of the occupant A or B.

Further, "NO" in steps S8 and S9.
When the accumulated moisture content on the surface of the evaporator 8 does not satisfy the predetermined offensive odor generating condition, the vent outlet damper 11 causes the outlets 4a to 4 to be discharged.
Step S13 of opening d, step S of blowing direction control
14 are sequentially executed, and the process returns to step S2. In this blowing direction control step S14, the louver 5a is arranged so that the blowing direction of the wind from the center outlet 4a and the light outlet 4c becomes the face direction of the occupant A (see the two-dot chain line arrows Fa and Fc in FIG. 1). The louvers 5b and 5c are rotated so that the direction of the air blown from the center outlet 4b and the left outlet 4d becomes the face direction of the occupant B (see the double-dashed line arrows Fb and Fd in FIG. 1). Rotate 5d. Therefore, in a state in which there is no possibility that the odor is generated from the evaporator 8, the cooling air is blown toward the face parts of the occupants A and B.

In summary, in the above-mentioned embodiment, the accumulated water content on the surface of the evaporator 8 is calculated by calculation, and the evaporator 8 produces an offensive odor based on the comparison between the calculated water content and the experimentally obtained offensive odor producing area. When it is determined whether or not the condition is satisfied, and it is determined that the offensive odor generation condition is satisfied, that is, when the cooling air from each of the air outlets 4a to 4d corresponding to the vent air outlet includes an offensive odor, the air is blown out. Since the direction is changed so as to avoid the occupant's face, there is no fear of giving the occupant an unpleasant sensation due to a strange odor. In this case, the cooling air will be blown out from each of the air outlets 4a to 4d forming the vent outlet suitable for efficiently lowering the temperature in the vehicle compartment.
There is no fear that the cooling speed in the vehicle compartment will be slowed down as in the conventional configuration. Further, in a state in which there is no possibility that a strange odor is generated from the evaporator 8, the blowing direction of the cooling air from each of the outlets 4a to 4d is controlled so as to be toward the occupant's face.
It is possible to positively give the occupants A and B a feeling of cool air, and of course, it is possible to quickly cool the vehicle interior.

In the above embodiment, the blowing direction of the cooling air from each of the outlets 4a to 4d is controlled to be changed to the left or right depending on the presence or absence of the offensive odor generation condition in the evaporator 8 in the cooling operation state. 5 showing a second embodiment of the present invention.
As described above, the blowing direction of the cooling air from each of the air outlets 4a to 4d may be changed up and down depending on the presence or absence of the offensive odor generating condition in the evaporator 8 in the cooling operation state.

Specifically, in FIG. 5, the louvers 5a to 5d are vertically rotated by the servomotors 6a to 6d (see FIG. 1), and then the evaporator 8 is used.
In the state where the offensive odor generating condition (see FIG. 1) is satisfied, the blowing direction of the cooling air from each of the outlets 4a to 4d is the direction avoiding the face of the occupant A or B downward (solid arrow E).
), The louvers 5a to 5d are rotated, and in a state where the offensive odor generation condition in the evaporator 8 is not satisfied, the blowing direction of the wind from the outlets 4a to 4d is the face direction of the occupant A or B. The louvers 5a to 5d may be rotated so that the louvers 5a to 5d (see the double-dotted chain line arrow F) are formed.

The present embodiment having such a structure also exhibits the same effect as that of the first embodiment. Particularly, according to the present embodiment, the condition in which the offensive odor is generated in the evaporator 8 is satisfied. Then, since the cooling air is blown toward the body part of the occupant, there is an advantage that it is possible to obtain the effect of preventing the discomfort due to the offensive odor while giving the occupant an immediate cooling sensation.

In each of the above-described embodiments, the infrared sensors 16 and 17 are used to detect the presence or absence of an occupant, but a so-called seating sensor in which a pressure sensor is set on the seat may be used. Alternatively, a configuration using a seat belt attachment / detachment signal may be used. further,
In each of the above-described embodiments, the configuration in which the blowing direction of the wind from the outlets 4a to 4d is directed toward the occupant A's face when the offensive odor generating condition in the evaporator 8 is not satisfied, is set to that direction. It is also possible to adopt a configuration that can be changed and set according to the occupants' preference.

[0035]

According to the present invention, as is clear from the above description, when the cooling heat exchanger in the air duct satisfies the predetermined offensive odor generating condition during the cooling operation state, Since the cooling air blowing direction from the vent outlet provided is automatically changed so as to avoid the passenger's face in the passenger compartment,
It is possible to reliably prevent the air-conditioning air containing an offensive odor from being blown out toward the passenger's face at the beginning of the cooling operation, and to exert the beneficial effect of being able to exert the cooling effect in the passenger compartment at an early stage. Is.

[Brief description of drawings]

FIG. 1 is an overall schematic configuration diagram showing a first embodiment of the present invention in substance.

FIG. 2 is a flowchart showing control contents of a control circuit.

FIG. 3 is a characteristic diagram showing how the amount of water on the evaporator surface changes.

FIG. 4 is a characteristic diagram for explaining the operation.

FIG. 5 is a schematic side view of essential parts showing a second embodiment of the present invention.

[Explanation of symbols]

In the drawings, 1 is an air conditioning unit, 2 is a duct case, 3 is an inlet, 4a and 4b are center outlets (vent outlets), 4
c is a right outlet (vent outlet), 4d is a left outlet (vent outlet), 5a to 5d are louvers (wind direction changing means), 6a to 6d are servomotors (driving means), 7 is a blower, and 8 is Evaporator (heat exchanger), 12 is a first sensor unit, 13 is a second sensor unit, 14 is a temperature sensor, 1
Reference numeral 5 indicates a control circuit (determination means, control means).

Claims (1)

[Claims] 1. An air conditioner for a vehicle, comprising a cooling heat exchanger arranged in an air duct, and configured to blow cooling air into a vehicle compartment from a vent outlet provided on the most downstream side of the air duct. An air-direction changing unit configured to change a blowing direction of the cooling air from the vent outlet, a driving unit for operating the air-direction changing unit, and the heat exchanger satisfying a predetermined offensive odor generating condition. And the vent outlet by operating the wind direction changing means through the driving means when the judgment means judges that the offensive odor generating condition is satisfied during the cooling operation state. An air conditioner for a vehicle, comprising: a control unit configured to change a direction in which the cooling air is blown out from the vehicle to a direction avoiding the occupant's face in the vehicle interior.