KR0146315B1 - Louver control apparatus of an airconditioner - Google Patents

Abstract

The present invention relates to a louver control device of an air conditioner that can control the rotation angle of the louver accurately by using a DC motor. The present invention has a reversible cooling cycle, and intakes the air in the room and heat exchanges with the refrigerant flowing in the cooling cycle, and then discharges the heat-exchanged air into the room through the discharge port 12 to perform a cold half room, the discharge port 12, in the air-conditioning and air conditioning unit equipped with a wind direction control louver 13 for determining the discharge wind direction, the rotational speed of the DC motor 40, DC motor 40 for driving the wind direction control louver 13 is determined. Decelerating member 20, the louver motor driver 70 for driving the DC motor 40, the function selection unit 60 for setting the desired wind direction angle, and the wind direction control louver 13 to lower the ratio of The driving time M of the DC motor 40 until the set wind direction angle is formed based on the fully open position of the louver open detecting unit 30 and the wind direction control louver 13 to be detected is calculated, and the calculation is performed. DC motor 40 rotates forward for the specified time (M) Or a microprocessor 50 for outputting a control signal to the louver motor driver 70 to reverse rotation.

Description

Louver control device of air conditioner

1 is a front view schematically showing an indoor unit of a conventional air conditioner

2 is a front view schematically showing an indoor unit of an air conditioner according to the present invention.

3 is a perspective view showing the mechanical configuration of the louver controller in FIG.

4 is an electrical block diagram of the louver control device of the air conditioner of the present invention.

5 is a flowchart for explaining the operation of the louver control device of the air conditioner of the present invention.

* Explanation of symbols for main parts of the drawings

1: indoor body 2: suction grill

3: Cold air outlet 4: Wind direction control louver

5: louver motor 10: basic body

11: suction grill 12: cold air outlet

13: Wind direction control louver 13a: rotating shaft

20: reduction gear box 30: louver open detection unit

31: Slit board 32: Photo interrupt

32a: casing 32b: open

32C: light emitting element 32d: light receiving element

40: louver motor 50: microprocessor

60: function selection section 70: louver motor drive section

The present invention relates to a louver control device of an air conditioner, and more particularly, to a louver control device of an air conditioner capable of accurately controlling the rotation angle of a louver using a general direct current motor.

As is well known, an air conditioner has a cooling cycle consisting of a compressor, a condenser, a capillary tube, an evaporator, and a refrigerant pipe connecting them in series, and absorbs and heats the room in the process of changing the refrigerant through the cooling cycle. Or it is a device that heats the room by releasing heat. For the sake of convenience, the cooling function plate will be described as an example.

1 is a front view schematically showing an indoor unit of a conventional air conditioner. As shown in FIG. 1, the indoor unit of the air conditioner is disposed at the central portion of the main body 1 with a suction grill 2 for inhaling relatively hot air in the room, and below the suction grill 2. A cold air discharge port 3 is formed which discharges the cooled air in exchange with the heat contained in the refrigerant passing through the evaporator. This air suction and discharge operation is performed by an indoor fan not shown. In the cold air discharge port 3, the wind direction control louver 4 is generally rotatably extended to determine the discharge direction of the cold air, and at one end thereof, the louver motor 5 for driving the wind direction control louver 4 is wind direction. It is installed to be axially coupled with the control louver (4).

As the louver motor 5, a stepping motor is generally used. When the occupant operates the wind direction adjusting key through a function setting means, for example, a remote controller, the stepping motor rotates in the forward and reverse directions according to the manipulation amount. ) Is rotated to the required position. As is well known, the stepping motor has the advantage that the rotation angle control is relatively accurate because the input pulse is rotated by a predetermined angle each time one input pulse is input. Since the reference angle can be changed due to the accumulation of deviation or external force, a louver position detecting means for setting the reference angle is required separately.

The present invention has been made in order to solve the above-mentioned problems, and provided with a reversible cooling cycle, and intakes the air in the room and heat exchanged with the refrigerant flowing in the cooling cycle to discharge the air thus exchanged into the room through the discharge port In the cooling and cooling air conditioner equipped with a wind direction control louver to determine the discharge direction in the discharge port, the direct current motor for driving the wind direction control louver, the rotational speed of the DC motor to a predetermined ratio A deceleration member, a louver motor driving unit for driving the DC motor, a function selecting unit for setting a desired wind direction angle, a louver opening detecting unit for detecting a complete opening position of the wind direction control louver, and a completely open position of the wind direction control louver To calculate the driving time of the DC motor until the set wind direction angle is formed; During submitted time and characterized in that the direct current motor is equipped with a microprocessor for outputting a control signal to the normal rotation or reverse rotation to the louver motor drive.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration according to a preferred embodiment of the present invention.

2 is a front view schematically showing the indoor unit of the air conditioner according to the present invention, and FIG. 3 is a perspective view showing the mechanical configuration of the louver control device in FIG. 2. Only the wind direction control louver is shown. As shown in Figures 2 and 3, the indoor unit of the air conditioner according to the present invention is disposed in the suction grill (11) for inhaling relatively high temperature air in the room in the central portion of the main body 10, The lower portion of the suction grill 11 is formed with a cold air outlet 12 for discharging the cooled air exchanged with the heat contained in the refrigerant passing through the evaporator. The cold air discharging opening 12 is rotatably extended in the wind direction control louver 13 for determining the up and down discharge direction of the cold air, and a louver motor 40 for driving the wind direction control louver 13 is fixedly installed at one end thereof. The louver motor 40 is preferably implemented as a DC motor as described below. On the other hand, since the conventional DC motor has a large number of revolutions while the torque is small, instead of reducing the number of revolutions appropriately, the wind direction control louver 13 and the louver motor 40 are moved to the reduction gear box 20. Axial coupling is interposed. The louver opening detection unit 30 is installed around the rotational shaft of the wind direction control louver 13 to detect the position of the wind direction control louver 13, and the exact open position. The louver opening detecting unit 30 has a semicircular plate member 31 (hereinafter referred to as a slit plate) in which a slit 31a is formed at a position perpendicular to the horizontal axis of the wind direction control louver 13, and an opening 32b at the bottom thereof. A photo interrupt 32 having a light emitting element 32c and a light receiving element 32d provided in the casing 32a so as to face each other on the rotation radius of the slit 31a. In the above-described configuration, the photo interrupt 32 is disposed so that the slit 31a is exactly positioned on the line connecting the light emitting element 32c and the light receiving element 32d when the wind direction control louver 13 is completely opened. .

4 is an electrical block diagram of the louver control device of the air conditioner of the present invention. As shown in FIG. 4, the electrical configuration of the louver control device of the air conditioner of the present invention is largely controlled by the microprocessor 50 for controlling the overall operation of the device and the louver motor for driving the wind direction control louver 13. 40, a function selection unit 60 for setting a desired wind direction in addition to selecting various functions of the apparatus, a louver open detecting unit 30 and a microprocessor for detecting a fully open position of the wind direction control louver 13 A louver motor driver 70 for driving the louver motor 40 under the control of 50 is provided. In the above-described configuration, the function selection unit 60 may be provided in the remote controller. For example, the function selection unit 60 may be provided with a forward rotation key and a reverse rotation key so that each time the keys are pressed, a predetermined angle, for example, 15 ° Can be reversed. In this case, the microprocessor 50 can perform the accurate wind direction angle control by driving the louver motor 40 for a predetermined multiple of the time by storing in advance the time taken for the wind direction control louver 13 to rotate 15 °. have. To explain this process in more detail, the louver motor driver 70 may be implemented as a single-chip DC motor driver IC, and both at the corresponding output terminals P0 and P1 of the microprocessor 50. When the low level or high level signal is output, the low level signal is output from the corresponding output terminals M0 and M1 of the louver motor driver 70 to stop the operation of the louver motor 40. On the other hand, when the high level and low level signals are respectively output from the corresponding output terminals P0 and P1 of the microprocessor 50, the two output terminals M0 and M1 of the louver motor driver 70 are respectively high level. And when the low level signal is output to rotate the louver motor 40 in the forward direction (clockwise), and the low level and high level signals are output from the corresponding output terminals P0 and P1 of the microprocessor 50, respectively. Low and high level signals are also output from the output terminals M0 and M1 of the louver motor driver 70 to drive the louver motor 40 in the reverse direction (counterclockwise). As described above, the louver opening detecting unit 30 detects that the wind direction control louver 13 is completely opened when the light generated from the light emitting element 32c reaches the light receiving element 32d, and thus the microprocessor 50 Provide this information.

Hereinafter, the operation of the louver control device of the air conditioner of the present invention will be described in detail. 5 is a flowchart for explaining the operation of the louver control device of the air conditioner of the present invention. As shown in FIG. 5, in step S10, it is determined whether the power switch of the air conditioner is on, and when it is turned off, the program is terminated. If it is turned on, the process proceeds to step S12 to perform initialization. Next, in step S14, the type of operation selected by the function selection unit 60 is input, and in step S16, a control signal is output to the corresponding circuit component to perform the selected operation. In this way, in operation S18, it is determined whether the wind direction control function is selected through the function selection unit 60. If the wind direction control function is not selected in step S18, the operation continues with the wind direction set in the previous operation, and if the wind direction control function is selected, the process proceeds to step S20, where the wind direction control louver 13 is in the initial position. That is, it is determined whether it is in the fully open position. If the wind direction control louver 13 is not in the fully open position in step S20, the process proceeds to step S22, and after the forward or reverse rotation of the louver motor 40, step S20 is performed again. In this process, if the wind direction control louver 13 is in the fully open position in step S20, the process proceeds to step S24 and the driving time M of the louver motor 40 according to the manipulation amount input in the step S18. ) Is calculated. At this time, the microprocessor 50 should store in advance the relation between the rotation angle of the louver motor 40 and the driving time. In step S26 to step S30, the louver motor 40 is driven for the time calculated in step S24, and in step S32, the driving of the louver motor 40 is stopped by stopping the driving of the louver motor 40. Control, that is, control of the wind direction angle, is completed.

In the above embodiment, the louver open detection unit 30 has been described as being implemented as a photo interrupt, but is not limited thereto. For example, it may be implemented by installing a micro switch in the fully open position of the wind direction control louver. Furthermore, in the above embodiment, the wind direction control louver has been described as having one, but by using an appropriate interlock mechanism, it is possible to simultaneously control the rotation angles of the plurality of wind direction control louvers.

As described above, according to the louver control device of the air conditioner of the present invention, it is possible to reduce the overall price of the air conditioner by enabling accurate wind direction control while using a small-cost DC motor.

Claims (2)

It is equipped with a cost-effective cooling cycle, and intakes air in the room and heat exchanges with the refrigerant flowing in the cooling cycle, and then discharges the heat-exchanged air into the room through the discharge port 12 to perform a cold half room, and discharge port 12 In the air-conditioning combined air conditioner equipped with a wind direction control louver 13 for determining the discharge wind direction, the rotational speed of the DC motor 40, DC motor 40 for driving the wind direction control louver 13 at a predetermined ratio The decelerating member 20 for lowering, the louver motor driving unit 70 for driving the DC motor 40, the function selecting unit 60 for setting a desired wind direction angle, and the louver for detecting the fully open position of the wind direction control louver 13 The driving time M of the DC motor 40 until the set wind direction angle is formed on the basis of the fully open position of the opening detecting unit 30 and the wind direction control louver 13 is calculated, and the calculated time ( DC motor 40 rotates forward or reverse during M). Louver control apparatus of an air conditioner comprising the microprocessor 50, which outputs a control signal to the louver driving motor 70 to former. According to claim 1, The louver opening detecting unit 30, the slit plate (31a) is formed at a position forming a predetermined angle with the horizontal axis of the wind direction control louver 13 and rotates together with the wind direction control louver 13 ( 31 and a photo interrupt 32 having a light emitting element 32c and a light receiving element 32d which are installed to face each other on a rotation radius of the slit 31a in a casing 32a having an opening 32b formed therein. Wind direction control device, characterized in that the air conditioner.