KR100796565B1 - Apparatus and method for controlling rise and fall of exhaust port for air-conditioner - Google Patents

Abstract

An apparatus and a method for controlling rise and fall of a discharge port of an air conditioner are provided to prevent erroneous operation in opening and shutting of a door and a discharge flap due to a design tolerance and formation of a position detector, thereby improving the reliability of judging erroneous operation. A main body has a suction port for introducing air and a discharge flap located inside the main body in non-operation while descending in operation to discharge cooled air to a front. A flap driving unit(230) is installed in the main body for driving the discharge flap to ascend and descend. A magnet member is installed at one side of the discharge flap for generating a magnetic field. A hall sensor part(200) is installed in the main body for detecting intensity of the magnetic field of the magnet member changing when the discharge flap ascends and descends. A timer(210) counts time to maintain a signal for operation of the flap driving unit, reflecting a tolerance generated in a manufacturing process of the discharge flap and an error generated in operating the flap driving unit. A controller(220) outputs a signal for starting operation to the flap driving unit, and outputs a signal for stopping operation to the flap driving unit in accordance with the counted time in case that the detected intensity of the magnetic field exceeds preliminarily set intensity.

Description

Air outlet discharge control device and method {APPARATUS AND METHOD FOR CONTROLLING RISE AND FALL OF EXHAUST PORT FOR AIR-CONDITIONER}

1 is a perspective view showing an indoor unit of a conventional wall-mounted air conditioner according to the prior art,

Figure 2 is a perspective view of the air conditioner installed discharge outlet lifting control device of the air conditioner according to the present invention.

Figure 3 is a block diagram showing the discharge port lift control device of the air conditioner according to the present invention.

4 is a cross-sectional view showing a cross section of the air conditioner provided with a discharge opening and lowering control device of the air conditioner of FIG.

5 is a flowchart illustrating a discharge hole lifting control process of the air conditioner according to the present invention;

6 is a flow chart showing a discharge hole lifting control process of the air conditioner according to the present invention.

(Explanation of symbols for the main parts of the drawing)

100: air conditioner 110: main body

120: suction port 130: discharge flap

200: Hall sensor 210: Timer

220: control unit 230: flap drive unit

240: display portion 250: magnet member

The present invention relates to a discharge opening and lowering control of an air conditioner, and more particularly, to a discharge opening and closing control of an air conditioner, which determines whether or not a malfunction occurs during opening / closing operation of the discharge door or the discharge flap of the air conditioner, and improves the reliability of the malfunction determination. .

A general air conditioner is manufactured in a form in which the indoor unit and the outdoor unit are separated, and are connected to each other by a pipe for circulating refrigerant and wiring for mutual transmission of power and control signals.

That is, in the condenser provided in the outdoor unit, the refrigerant having a high temperature and high pressure is cooled by heat exchange with external air, and the cooled refrigerant is supplied to the evaporator provided in the indoor unit in the form of a mist through an expansion valve to exchange heat with the indoor air. Through the refrigerant vaporizes to cool the indoor air to supply cool air to the indoor space.

1 is a perspective view showing an indoor unit of a conventional wall-mounted air conditioner according to the prior art, the indoor unit of the wall-mounted air conditioner according to the prior art is installed on the front side of the main body 11 and the main body 11 to form the main body And an openable cover panel 10 having a suction port 12 to form an external appearance.

In addition, a heat exchanger is provided in an inner space surrounded by the main body 11 and the cover panel 10, and a blower fan for forced inflow of air is provided inside the heat exchanger, and air flowed into the lower portion of the blower fan. The air discharge port 17 for discharging the back to the indoor space is provided.

The air outlet 17 is provided with a flap 15 for adjusting the air direction up and down, the flap 15 is automatically driven by a flap drive unit, such as a motor or an actuator, depending on whether the air conditioner is operating flap By opening and closing the 15 and the air discharge port 17, the appearance can be kept beautiful when the air conditioner is not in operation.

The air conditioner is configured by using an optical sensor or using a micro switch or the like to detect the opening and closing of the flap 15 and the air outlet 17.

However, when the sensor is configured using an optical sensor, contaminants such as dust are deposited on the light receiving part that receives the light according to the long-term use, and thus it is impossible to receive the light emitted from the light emitting part. And malfunctions.

In addition, when the switch is configured using a micro switch, the switch is mechanically recognized to recognize the opening and closing operation. Therefore, a malfunction occurs due to a tolerance caused during design and a tolerance generated during mass production and an error due to a change in the switch bar during manufacturing and assembly. There is a problem.

In addition, since the micro switch is recognized through mechanical contact, there is a problem in that contact failure occurs due to long-term use, causing malfunction.

In order to solve the above problems, an object of the present invention is to determine whether a malfunction occurs during the opening and closing operation of the discharge door or the discharge flap of the air conditioner, and to provide an apparatus and method for controlling the discharge port lift of the air conditioner to improve the reliability of the malfunction determination. do.

In order to achieve the above object, the air outlet outlet control apparatus of the air conditioner according to the present invention has an inlet for air inlet formed at an upper portion thereof, and is positioned inside the non-operating position and descends to the lower side during operation to guide the cooled air to be discharged forward. A main body having a discharge flap formed therein; A flap driving part installed at one inner side of the main body to drive the discharge flap to rise and fall; A magnet member installed at one side of the discharge flap to generate a magnetic field; A hall sensor unit installed at one inner side of the main body to detect a magnetic field strength of the magnet member which is changed when the discharge flap is raised and lowered; A timer for counting the time for the operation signal of the flap driver to be maintained for a predetermined time by reflecting a tolerance generated during the manufacturing process of the discharge flap and an error generated during the operation of the flap driver; And outputting a signal for starting operation to the flap driving unit, and outputting an operation blocking signal to the flap driving unit according to the time counted from the timer when the strength of the magnetic field detected from the hall sensor unit exceeds a preset intensity. It includes a control unit.

In addition, the discharge opening and lowering control method of the air conditioner according to the present invention includes the step of outputting the signal to the flap drive unit by the control unit so that the discharge flap discharged cold air is lowered when the operation signal of the air conditioner is detected; Determining, by the controller, whether a magnetic field is detected according to the drop of the discharge flap from the hall sensor unit which detects the magnetic field strength of the magnet member provided on one side of the discharge flap; If the magnetic field is detected as a result of determining whether a magnetic field is detected, the control unit determines whether the intensity value of the magnetic field exceeds a reference value for determining the end of driving of the flap driver; And when the detected intensity value of the magnetic field exceeds the reference value for determining the end of driving of the flap driving unit, the control unit performs a manufacturing process of the discharge flap. Outputs an off signal to the flap driver according to a time counted from a timer that counts a time for reflecting the tolerance generated in the and the error generated during the operation of the flap driver so that the signal for operation of the flap driver can continue for a predetermined time. It includes a step.

In addition, when the magnetic field is not detected as a result of determining whether the magnetic field is detected, the controller detects a time elapsed after outputting the ON signal of the flap driver and compares it with a reference time for determining malfunction; And when the elapsed time exceeds the reference time for determining the malfunction, the controller outputting a malfunction display signal to a display unit for displaying the malfunction.

When the elapsed time does not exceed the reference time for the malfunction determination as a result of the comparison with the reference time for the malfunction determination, the controller maintains the ON signal of the flap driver.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a perspective view showing an air conditioner installed in the air conditioner lift control apparatus of the air conditioner according to the present invention, Figure 3 is a block diagram showing a discharge hole lift control device of the air conditioner according to the present invention, Figure 4 is a discharge hole lift of the air conditioner of Figure 2 Sectional drawing which shows the cross section of the air conditioner with a control apparatus.

As shown in Figures 2 to 4, the discharge opening and lowering control apparatus of the air conditioner according to the present invention and the air inlet 120 is formed in the upper portion, the lower body 110 with the discharge flap 130 for discharging cold air is formed; The flap driver 230 for driving the discharge flap 130, the control unit 220 for controlling the operation of the flap driver 230, the hall sensor unit 200 for detecting the position of the discharge flap 130, and the hall sensor It includes a magnet member 250 for applying a magnetic field to the portion (200).

The main body 110 has an inlet 120 for introducing air into the upper part of the main body 110, and is located inside the main body 110 when the air conditioner 100 is inactive, and when the air conditioner 100 is operating. It is provided with a discharge flap 130 to descend to the lower portion of the main body 110 to guide the air cooled through the heat exchange in the heat exchanger (not shown) to the front of the main body 110.

In addition, the main body 110 may form an accommodation space so that the discharge flap 130 may be accommodated inside the main body when the air conditioner 100 is inactive, and the discharge flap 130 may descend when the air conditioner 100 operates. A guide rail (not shown) is formed to guide so that it is.

The discharge flap 130 is a rectangular member that is kept inside the main body 110 when the air conditioner 100 is inactive and moves downward of the main body 110 when the air conditioner 100 is operated. A predetermined length protrudes from the lower end of the 110.

The hall sensor unit 200 is installed at one side of the main body 110, and preferably installed at the lower end of the main body 110. The hall sensor unit 200 detects a magnetic field generated from the magnet member and transmits the magnetic field to the controller 220.

That is, the hall sensor unit 200 passes through the hall sensor unit 200 when the magnet member 250 installed at one side of the discharge flap 130 to face the hall sensor unit 200 is raised and lowered. While transmitting the magnetic field strength is detected to the control unit 220.

The control unit 220 for the lowering operation to the flap drive unit 230 to drive the discharge flap 130 accommodated in the main body 110 when the air conditioner 100 operates to lower the predetermined length to the lower end of the main body 110. Output the signal. That is, the flap driving unit 230 performs the forward rotation.

In addition, when the intensity of the magnetic field detected by the hall sensor unit 200 exceeds a preset intensity, the controller 220 counts a predetermined time through the timer 210 and then a signal for blocking operation of the flap driver 230. Outputs an (off signal).

That is, the controller 220 determines that the discharge flap 130 is moved to the lower end of the main body 110 when the magnetic field having a sufficient size is detected by the hall sensor unit 200, and manufactures the main body 110 and the discharge flap 130. Correct discharge flap 130 by outputting a signal for lowering operation to the flap driver 230 for a predetermined time and then outputting an operation blocking signal in consideration of a tolerance generated in the process and an error generated during the operation of the flap driver 230. With the operation of) you can clearly recognize the operation. In this case, the control unit 220 outputs a signal for displaying a normal operation when the discharge flap 130 operates normally, and outputs a signal for indicating a malfunction when the discharge flap 130 malfunctions.

On the other hand, when the operation of the air conditioner 100 is terminated, the controller 220 outputs a signal for the upward operation to the flap driver 230 so that the flap driver 230 performs reverse rotation, and is detected by the hall sensor unit 200. When the intensity of the magnetic field is less than or equal to the preset intensity, the preset time is counted through the timer 210, and then a signal (off signal) for blocking operation of the flap driver 230 is output.

The flap drive unit 230 is installed at one side of the main body 110 including a motor (not shown), and preferably, a rack gear is installed at the flap drive unit 230 and a pinion gear is installed at the discharge flap 130. do.

In addition, the flap driver 230 performs forward and reverse rotation operations according to the rising operation signal and the falling operation signal output from the control unit 220 so that the discharge flap 130 is accommodated in the main body 110. Or to protrude a predetermined length to the lower end of the main body 110.

The display unit 240 is installed on the front surface of the main body 110 to display a normal operation display signal and a malfunction display signal output from the control unit 220 to the user, preferably composed of LED.

The magnet member 250 is installed at a position opposite to the hall sensor unit 200 on one side of the discharge flap 130 to generate a magnetic field.

5 and 6 are flowcharts illustrating a process of controlling the discharge port lift of the air conditioner according to the present invention, and the process of controlling the discharge port lift of the air conditioner according to the present invention will be described in more detail with reference to FIGS. 2 to 6.

When the operation signal of the air conditioner 100 is detected from the user (S100), the control unit 220 turns on the flap driving unit 230 for the lowering operation so that the discharge flap 130 for discharging cold descends to the lower end of the main body 110. Output a signal (S110).

After performing step S110, the controller 220 determines whether a magnetic field of the magnet member 250 installed on one side of the discharge flap 130 is detected from the hall sensor unit 200 (S120).

That is, step S120 is a process for determining whether the discharge flap 130 operates normally or malfunctions according to the driving of the flap driver 230.

When the magnetic field of the magnet member 250 installed on one side of the discharge flap 130 is detected in step S120, the control unit 220 exceeds the reference value for determining the end of driving of the flap driver 230. It is determined whether or not (S130).

That is, step S130 is a process for determining the end of the operation of the flap drive unit 230 when the discharge flap 130 operates normally.

When the intensity value of the magnetic field detected by the magnet member 250 in step S130 does not exceed a reference value for determining the end of the driving of the flap driver 230, the intensity value of the magnetic field is continuously detected.

In addition, when the intensity value of the magnetic field detected by the magnet member 250 in step S130 exceeds the reference value for determining the end of the driving of the flap drive unit 230, the controller 220 in advance through the timer 210. After counting a predetermined predetermined time, the flap driver 230 outputs an off signal for blocking operation (S140). At this time, the controller 220 outputs a signal for displaying a normal operation for displaying the normal operation of the discharge flap 130 to the display unit 240.

That is, in step S140, the magnet member 250 approaches the hall sensor unit 200 according to the lowering operation of the discharge flap 130, and the strength of the magnetic field detected from the hall sensor unit 200 is the magnet member 250. It increases with the approach of.

Therefore, when the intensity of the increasing magnetic field exceeds the preset reference intensity value, it is determined that the discharge flap 130 operates normally, and from the position where the hall sensor unit 200 is installed, to the position where the discharge flap 130 is completely opened. The discharge flap 130 is continuously controlled to maintain the lowering operation for the sum of the time required to move, the design tolerance, the tolerance generated during the manufacturing process, and the additional driving time according to the error of the driving device, and then the discharge flap 130 End the descent operation.

On the other hand, in step S120, when the magnetic field of the magnet member 250 installed on one side of the discharge flap 130 is not detected, the control unit 220 maintains the on-signal output for maintaining the falling operation of the flap drive unit 230 The time elapsed after the on signal for maintaining the falling operation is output (S200), and the detected elapsed time is compared with a reference time for determining whether the discharge flap 130 is malfunctioning (S210). ).

When the elapsed time exceeds the reference time for determining whether the malfunction is in step S210, the controller 220 outputs a malfunction display signal to the display unit 240 to indicate an open malfunction of the discharge flap 130. (S220).

In addition, when the elapsed time does not exceed the reference time for determining whether the malfunction occurs in step S210, the controller 220 performs the step S110 to maintain the falling motion action on signal of the flap driver 230. .

Therefore, it is possible to control the operation of the discharge flap without being influenced by malfunctions caused by contaminants such as dust due to long time use, design tolerances and errors of the driving device.

As described above, the present invention has an effect of preventing a malfunction caused by a design tolerance of a product and a malfunction caused by a deformation of a position detecting device when operating a door and an outlet of an air conditioner.

In addition, the present invention has an advantage that can improve the reliability of the product of the user by improving the reliability of the determination of the malfunction.

Claims (4)

A main body having an inlet for air inlet formed at an upper portion thereof, and having a discharge flap for guiding the cooled air to be discharged forward by descending to a lower position during operation and being lowered during operation; A flap driving part installed inside the main body to drive the discharge flap to rise and fall; A magnet member installed at one side of the discharge flap to generate a magnetic field; A hall sensor unit installed inside the main body to detect a magnetic field strength of the magnet member which is changed when the discharge flap is raised and lowered; A timer counting a time so that an operation signal of the flap driver may be maintained for a predetermined time by reflecting a tolerance generated during the manufacturing process of the discharge flap and an error generated during operation of the flap driver; And A control unit for outputting an operation start signal to the flap drive unit and outputting an operation blocking signal to the flap drive unit according to the time counted from the timer when the intensity of the magnetic field detected from the hall sensor unit exceeds a preset intensity; Discharge opening and lowering control device of the air conditioner comprising a. a) outputting an on signal to the flap driver by the control unit such that the discharge flap for discharging cold air descends when an operation signal of the air conditioner is detected; b) determining, by the controller, whether a magnetic field is detected in accordance with the falling of the discharge flap from the hall sensor unit detecting the magnetic field strength of the magnet member provided on one side of the discharge flap; c) when the magnetic field is detected as a result of the determination of step b, the controller determines whether the intensity value of the magnetic field exceeds a reference value for determining the end of driving of the flap driver; And d) when the detected value of the magnetic field exceeds the reference value for determining the end of driving of the flap driver as a result of the determination of step c, the control unit generates a tolerance generated during the manufacturing process of the discharge flap and the operation of the flap driver. And outputting an off signal to the flap driver according to a time counted from a timer counting a time so that the operation signal of the flap driver can be maintained for a predetermined time by reflecting an error generated during the discharge. Way. The method of claim 2, If the magnetic field is not detected as a result of the determination of step b, the controller detects a time elapsed after outputting an ON signal of the flap driver and compares it with a reference time for determining malfunction; And And if the elapsed time exceeds the reference time for determining the malfunction, the controller may further include outputting a malfunction indication signal to a display unit for displaying the malfunction. Way. The method of claim 3, wherein And the control unit maintains an ON signal of the flap driving unit when the elapsed time does not exceed the reference time for determining the malfunction as a result of the comparison.

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