KR100820566B1 - Vehicle blower and control method - Google Patents

Abstract

And a blower for blowing air introduced into the air conditioner into the vehicle, a motor unit for rotating the blower, and a controller for transmitting an operation speed value to the motor unit, wherein the controller is configured by a driver's setting. Provided is a vehicle blower for transmitting a value obtained by subtracting a second operating speed value corresponding to a vehicle speed from one operating speed value to the motor unit as the operating speed value. It is possible to control the speed of the blower according to the speed of the vehicle, by suppressing the change in the discharge amount according to the speed of the vehicle, it is possible to discharge the air volume set by the driver, the driver feels the desired air volume to perform a comfortable driving It becomes possible.

Description

Blower for vehicle and control method {BLOWER FOR VEHICLE AND CONTROL METHOD OF THE SAME}

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows roughly the structure of the vehicle air conditioner in embodiment of this invention.

2 is a graph showing a change in the value of f (v) according to the vehicle speed in the embodiment of the present invention.

3 is a graph showing a change in the value of f (b) according to the number of blowers in the embodiment of the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vehicle blower and a control method thereof, and more particularly, to a vehicle blower and a method of controlling the same, by controlling the speed of the blower according to the speed of the vehicle so as to discharge a desired amount of air from the air conditioner.

In general, an air conditioner mounted on a vehicle is classified into a cooling device that cools the air in the vehicle and adds comfort to the occupant, and a heating device that provides warmth by heating the air.

In the vehicle interior, the temperature of the indoor air rises due to various heat applied from the outside and the inside, such as the sun, the atmosphere, the road, or the engine. In this case, the driver operates the air conditioner. The device is activated.

The operation speed of the blower is determined by the driver's selection or by the command value of the controller in the autonomous driving mode. The blower mainly has a discrete operating speed. For example, the first stage operates at the slowest speed, so the amount of discharge air is small. As the number of stages increases, the operating speed increases, and the seventh stage operates at the fastest speed. do. Of course, according to the type of the blower and the air conditioner equipped with the same, it is possible to have different stages of operation, such as 1 to 6 stages, 1 to 8 stages.

By the way, in the blower mounted in the conventional vehicle, when the driver selects the speed of the blower, the blower operates at a fixed speed determined accordingly. At this time, when the inflow direction of the air to the air conditioner is set to the outside air, the amount of running wind due to the running of the vehicle increases into the air conditioner as the vehicle speed increases, and this running wind is added to the air blowing amount of the blower. As a result, as the vehicle speed increases, an increased amount of air is discharged than the discharge amount of the blower selected by the driver. This interferes with the comfortable driving and adversely affects the driver's filling.

The present invention is to solve the problems of the prior art, by controlling the speed of the blower according to the speed of the vehicle, to provide a vehicle blower operable to discharge the air volume set by the driver regardless of the speed of the vehicle and a control method thereof. It aims to do it.

The vehicle blower of the present invention includes a blower for blowing air introduced into the air conditioner into the vehicle, a motor unit for rotating the blower, and a control unit for transmitting an operation speed value to the motor unit. And a value obtained by subtracting the second operating speed value according to the vehicle speed from the first operating speed value set by the driver, is transmitted to the motor unit as the operating speed value. In addition, the second operating speed value is preferably increased as the vehicle speed increases, and the second operating speed value is preferably decreased as the first operating speed value according to the driver's setting increases. . The second operating speed value is more preferably a product of a first value that increases as the speed of the vehicle increases and a second value that decreases as the first operating speed value increases by the driver's setting.

The control method of the vehicle blower of the present invention includes a blower for blowing air introduced into the air conditioner into the vehicle, a motor unit for rotating the blower, and a controller for transmitting an operation speed value to the motor unit. A control method of a vehicle blower, the method comprising: receiving, by the controller, a first operating speed value according to a driver's setting, calculating, by the controller, a second operating speed value according to a vehicle speed, and controlling, by the controller, the first operating speed value; And transmitting the value obtained by subtracting the second operating speed value from the operating speed value to the motor unit as the operating speed value. In addition, the second operating speed value is preferably a product of a first value that increases as the vehicle speed increases and a second value that decreases as the first operating speed value set by the driver increases.

Hereinafter, a vehicle blower and a control method thereof according to an embodiment of the present invention will be described with reference to FIGS. 1 to 3.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows roughly the structure of the vehicle air conditioner in embodiment of this invention.

The vehicle air conditioner includes an air inlet door 110, a blower 120, an eva core 130, a heater core 140, a temporal door 150, and a mode door 160 inside the frame 100. . In addition, the controller 180 controls various doors 110, 150, and 160 of the air conditioner and receives a vehicle speed value from the vehicle speed sensor 190. Although only the input line and the output line connected to the controller 180 are directly related to the present invention, in reality, the air conditioner is additionally connected to a portion requiring control. In addition, the control unit 180 is generally installed separately for the air conditioner, but may be included in the control unit for controlling the entire vehicle.

The air inlet door 110 determines whether the air inflow direction is to be air or bet, and is connected to a motor (not shown) directly controlled by the controller to open and close the door. In FIG. 1, the air inlet door 110 is shielded in the direction of the bet, and the air is introduced into the air conditioner. However, when the air inlet door 110 is in a state 111 that shields the outside air, Bet flows in. The state of the air inflow door 110 is determined by a signal input from the control unit through the control line 181.

The blower 120 is for discharging the air introduced into the air conditioner and discharging the air into the vehicle, and includes a motor unit 121 and a blower 122. The motor unit 121 rotates the blower 122 at a speed determined according to the input speed value, voltage value, or duty ratio. When only a simple speed value is input from the controller 180 through the control line 182, a circuit for converting the speed value into a voltage value or a duty ratio is provided inside or outside the motor unit 121.

Eva core 130 takes the heat from the air blown by the blower by heat exchange to convert to a low temperature state, the heater core 140 serves to convert the air to a high temperature state by heating. A temporal door 150 is installed in front of the heater core 14 to prevent the blown air from passing through the heater core 140 (state of FIG. 1), or the blown air passes through the heater core 140. To be heated (state of 151).

The mode door 160 determines whether the air discharged from the air conditioner will be discharged in the vent direction or the floor direction. In the state of FIG. 1, the liquid is discharged in the floor direction, and in the state indicated by reference numeral 160-1, the liquid is discharged in the vent direction. A signal from the controller 180 is also input to the mode door 160, but is not illustrated.

In the air conditioner configured as described above, for example, it is assumed that the driver sets the blower to one stage. When the blower is set to the first stage, the operating voltage Mv of the motor unit 121 is 3V, and the rotation shaft of the motor unit 121 rotates at the speed accordingly, so that the blower 122 performs blowing. Here, the value transmitted from the control unit 180 to the motor unit 121 is a signal having information that the blower is set to the first stage, and the motor unit 121 may operate by converting the voltage value or duty ratio corresponding to this signal. Alternatively, the motor unit 121 may be operated by directly transmitting a voltage value or a duty ratio corresponding to the operation of the blower in the first stage from the controller 180 to the motor unit 121. The present invention encompasses all such similar operations, and the operating speed values recited in the claims are intended to encompass them all. However, for the sake of simplicity, the following description will be made assuming that a voltage value is transmitted from the controller 180 to the motor unit 121.

When the driver sets the blower to the first stage and the operating voltage Mv = 3V is transmitted from the controller 180 to the motor unit 121, the blower 122 rotates at the corresponding rotation speed to perform blowing. If the airflow volume is maintained in accordance with the first stage, the driver can feel the desired airflow volume and perform a comfortable driving.

However, the blower blows the air flowing in from the outside of the air conditioner, and in particular, when the air inlet door 110 is set to enter the outside air, there is a difference in the air inflow rate according to the vehicle speed, and the vehicle speed is high. In this case, it is inevitable that the amount of air discharged from the blowing amount according to the rotational speed of the blower is discharged into the vehicle.

Therefore, in the present invention, the vehicle speed sensor 190 detects the speed of the vehicle and transmits it to the controller 180 to control the airflow amount according to the speed of the vehicle. The vehicle speed sensor 190 may have various forms such as a general speed sensor and a sensor for detecting a speed from the rotational speed of the wheel, and the vehicle speed sensor 190 is not particularly limited as long as the vehicle speed sensor is transmitted to the controller 180.

Fig. 2 is a graph showing the change of the f (v) value according to the vehicle speed in the embodiment of the present invention. Here, f (v) is a value that increases with the speed of the vehicle and is a value subtracted from the operating voltage of the motor unit 121, that is, the first operating speed value Mv, by the driver's setting. For example, if the driver sets the blower to one stage and the vehicle is driving at 50 km / h with the first operating speed value Mv = 3V, the corresponding f (v) value is shown in the graph of FIG. 2. This value becomes 0 to operate at the operating speed value Mv '= Mv-f (v) = 3V of the motor unit 121. When the speed of the vehicle is continuously increased and the vehicle travels at 140 km / h, the f (v) value becomes 0.9 and the operating speed value Mv 'of the motor 121 is equal to the first operating speed value Mv. By setting the second operating speed value f (v) = 3-0.9 = 2.1 V, the rotation speed of the blower 122 set when the speed of the vehicle is increased is lowered. However, since the amount of air introduced from the outside has increased because the running speed of the vehicle is high, the same amount of air can be discharged into the vehicle as the vehicle runs at 50 km / h.

As described above, according to the present invention, a value obtained by subtracting the second operating speed value according to the vehicle speed from the first operating speed value Mv according to the driver's setting is transmitted to the motor unit 121 to be discharged into the vehicle according to the vehicle speed. It is possible to suppress the discharge amount to be changed. In FIG. 2, in order to prevent frequent changes of the f (v) value when the vehicle speed is weakly changed in a predetermined section, control by a so-called hysteresis method is performed for each speed section. In addition, the f (v) value exists only when the vehicle speed is 80 km / h or more, thereby eliminating the influence of the amount of air introduced only at a predetermined speed or more. This is because the driving wind due to the running of the vehicle is not very large below the predetermined speed.

3 is a graph showing a change in the value of f (b) according to the number of blowers in the embodiment of the present invention. Here, f (b) is a value that decreases as the number of stages of the blower set by the driver increases, and is multiplied by the value of f (v) to be a value subtracted from the first operating speed value Mv. That is, the equation of the operating speed value Mv '= first operating speed value Mv-second operating speed value f (v) x f (b) of the motor unit 121 is established.

As described above, the reason for reducing the second operation speed value as the number of blowers increases is as follows. As the speed of the vehicle increases, the amount of air flowing into the air conditioner is increased and added to the air blowing amount by the rotation of the blower 122. The number of stages of the blower set by the driver is increased to increase the rotation speed of the blower 122. This reduces the degree of influence as the vehicle speed increases. Therefore, f (b) shown in FIG. 3 is made in consideration of such circumstances, and the value of the second operating speed value decreases as the number of blower stages set by the user increases, thereby being subtracted from the first operating speed value. It is to reduce.

For example, if the driver sets the number of blowers to one stage and the vehicle travels at 140 km / h, 0.9 V corresponding to the second operating speed value f (v) × f (b) = 0.9 × 1 is calculated. 1 is subtracted from the operating speed value.If the driver sets the number of blowers to 7 gears and the vehicle is traveling at 140 km / h, 0.9 × 0.3 = 0.27 V corresponding to the second operating speed value is subtracted from the first operating speed value. Thus, as the vehicle speed increases, the second operating speed value decreases. As the second operating speed value decreases, a value subtracted from the first operating speed value set by the driver decreases, so that the air of the discharge amount desired by the driver is discharged into the vehicle.

In the above-described embodiment, the air inlet door 110 has been described to set the inflow of the outside air, but the air inlet door 110 is set to enter the inside or mixed with the inside and outside air is also suitable The value stored in the controller may be set and applied to calculate the second operation speed value.

According to the present invention, it is possible to control the speed of the blower in accordance with the speed of the vehicle, by suppressing the change in the discharge amount in accordance with the speed of the vehicle, it is possible to discharge the air volume set by the driver, the driver feels the desired air volume A comfortable driving can be performed.

Claims (6)

delete delete In the blower mounted on the vehicle air conditioner, A blower for blowing air introduced into the air conditioner into the vehicle, A motor unit for rotating the blower; A control unit for transmitting an operation speed value to the motor unit, The controller transmits a value obtained by subtracting a second operating speed value according to the vehicle speed from the first operating speed value set by the driver as the operating speed value to the motor unit, And the second operating speed value increases as the speed of the vehicle increases, and decreases as the first operating speed value according to the driver's setting increases. The method according to claim 3, And the second operating speed value is a product of a first value that increases as the vehicle speed increases and a second value that decreases as the first operating speed value set by the driver increases. A control method of a vehicle blower comprising a blower for blowing air introduced into an air conditioner into a vehicle, a motor unit for rotating the blower, and a control unit for transmitting an operation speed value to the motor unit, Receiving, by the controller, a first operation speed value according to a driver's setting; Calculating, by the controller, a second operation speed value according to the vehicle speed; And transmitting, by the control unit, a value obtained by subtracting the second operating speed value from the first operating speed value to the motor unit as the operating speed value. The method according to claim 5, The second operating speed value is a control of a vehicle blower, which is a product of a first value that increases as the speed of the vehicle increases and a second value that decreases as the first operating speed value according to the driver's setting increases. Way.

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