KR100705667B1 - Apparatus and method for controlling suction air of support blower for air conditioner - Google Patents

Abstract

The present invention relates to an auxiliary blower intake air control of an air conditioner provided with an auxiliary blower on an upper part of the air conditioner and adjusting an intake amount of air introduced into the auxiliary blower so that the room can be cooled quickly. To this end, in an air conditioner that sucks and cools indoor air according to the air volume selected by a user and discharges the cooled air to a discharge part, the air conditioner is partitioned into a partition having an air vent connected to the discharge part on the upper part of the discharge part. An auxiliary blower that sucks a part of the cooled air discharged to the air from the vent and discharges the air to the front of the air conditioner; An intake air adjusting unit installed in the venting unit to adjust an opening degree of the venting unit to control a flow rate of air sucked into the auxiliary blower; And a control unit outputting a control signal of the intake air adjusting unit so that the flow rate of the air flowing into the auxiliary blower is constant by adjusting the opening degree of the venting unit according to the air volume selected by the user. Therefore, there is an advantage that the cool air can be sufficiently sucked in the auxiliary blower installed to supply the cool air to the upper front of the air conditioner.

Air Conditioner, Auxiliary Blower, Suction Control

Description

Apparatus and method for controlling suction air of support blower for air conditioner

1 is a perspective view showing a blowing operation of a general air conditioner.

Figure 2 is a block diagram schematically showing a conventional air conditioner configuration.

Figure 3 is a block diagram schematically showing the configuration of the auxiliary blower intake air control device of the air conditioner according to the present invention.

Figure 4 is a perspective view showing the blowing operation of the air conditioner, the auxiliary blower intake air control device of the air conditioner according to the present invention.

5 is a cross-sectional view showing the configuration of the air conditioner of FIG.

Figure 6 is a flow chart showing a secondary blower intake air control process of the air conditioner according to the present invention.

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

100: input unit 110: suction unit

120: discharge portion 130: auxiliary discharge portion

200: sensor unit 300: control unit

400: cooling unit 500: auxiliary blower

510: auxiliary blowing fan 600: intake air control unit

610: partition 620: vent

630: throttle 640: motor

The present invention relates to an auxiliary air blower intake air control of the air conditioner, and more particularly, to install an auxiliary blower on the upper part of the air conditioner, and to adjust the intake amount of air introduced into the auxiliary blower to allow the air conditioner to be quickly cooled. It relates to blower intake air control.

In general, an air conditioner is composed of a compressor, an outdoor heat exchanger (hereinafter referred to as an outdoor unit), a capillary tube, an indoor heat exchanger (hereinafter referred to as an indoor unit), and the like. Adjust to the desired level.

As shown in FIG. 1, the indoor heat exchanger of the air conditioner is provided with a suction part 20 for sucking indoor air in a lower part of the front surface of the main body 10 of the air conditioner, and a discharge part 30 for discharging air cooled by the air conditioner. Is installed in the upper front of the main body 10, the input unit 40 for controlling the operation of the air conditioner is installed in the front center of the main body 10.

In addition, as shown in FIG. 2, the air conditioner performs a cooling cycle according to an operation control signal output from the control unit 50 and the control unit 50 controlling the operation of the air conditioner according to various control signals input through the input unit 40. It consists of the cooling part 60 which drives.

The cooling unit 60 for driving the cooling cycle is a compressor 61 for compressing at high temperature and high pressure, and the high temperature and high pressure refrigerant gas transferred from the compressor 61 is exchanged with the surrounding air for the low temperature and high pressure liquid. A condenser 62 having a blower fan 70 and a drive motor 71 for driving the blower fan so as to be changed into a coolant state, and a coolant transferred to a liquid state in the condenser 62 at low temperature and low pressure. The evaporator 64 is evaporated while passing the low-temperature and low-pressure refrigerant transferred from the capillary tube 63 which depressurizes to the liquid and gas state of the liquid, and the ambient heat is kept at a low temperature, and the evaporator 64 is cooled. The refrigerant in the liquid state is filtered from the blowing fan 72 for discharging the compressed air into the room, the drive motor 73 for driving the blowing fan 72, and the refrigerant gas vaporized by the evaporator 64. With an accumulator (65) that allows it to flow back into the compressor. It is.

Accordingly, the controller 50 controls the cooling unit 60 to drive a cooling cycle according to the input of the operation control signal of the input unit 40, and the air cooled in the cooling unit 60 is the intake unit of the indoor unit main body 10. Heat exchanged in the indoor air sucked through the 20 and the evaporator 64 to cool the room through the discharge unit 30 of the indoor unit main body 10 through the blowing fan and the motor (72 and 73).

However, such a conventional air conditioner can quickly cool a room temperature by discharging cold air into a room through a single discharge port, but has a structural problem due to the discharge amount of a cold air and a single discharge port. There is a problem that cooling is difficult.

In addition, when the cold air sucked into the auxiliary blower is not sufficiently supplied, there is a problem that the cold air discharged to the auxiliary blower is not sufficiently discharged.

Accordingly, the present invention is to propose an apparatus and method for allowing the cooled air to reach the near and far distance of the room sufficiently to achieve a rapid cooling.

In order to solve the above problems, an object of the present invention is to provide an auxiliary blower intake air control device of an air conditioner so that sufficient cold air can be provided to a room located far from the air conditioner.

It is also an object of the present invention to provide a method for controlling an auxiliary blower intake air of an air conditioner so that sufficient cold air can be provided to a remote room.

In order to achieve the above object, the present invention provides an air conditioner that sucks and cools indoor air according to a user's selected air volume and discharges the cooled air to a discharge unit. An auxiliary blower which is partitioned into partition walls having a discharge portion and sucks a part of the cooled air discharged to the discharge portion from the vent portion and discharges it to the front side of the air conditioner;

An intake air adjusting unit installed in the venting unit to adjust an opening degree of the venting unit to control a flow rate of air sucked into the auxiliary blower; And

And a control unit for outputting a control signal of the intake air control unit so that the flow rate of the air flowing into the auxiliary blower is constant by adjusting the opening degree of the ventilation unit according to the air volume selected by the user.

The apparatus may further include a sensor unit installed inside the discharge unit to detect at least one of a flow rate, a flow rate, and a wind pressure of the cooled air discharged to the discharge unit.

The control unit may output a control signal of the intake air control unit so that the opening degree of the ventilation hole is adjusted according to the information detected from the sensor unit.

In addition, the intake air adjusting unit for adjusting the opening degree of the ventilator so that the flow rate of the air sucked into the auxiliary blower is controlled to adjust the opening degree of the ventilator; And a rotation shaft is connected to one side of the adjustment plate, characterized in that it comprises a control plate driving motor for rotating the control plate around the rotation axis.

In addition, the present invention provides a control method of an auxiliary air intake air control device of an air conditioner, the control unit detecting an operation signal of the air conditioner from an input unit for cooling the air conditioner;

Determining, by the controller, whether a driving signal of an auxiliary blower is input from the input unit;

Detecting, by the controller, flow rate information of air discharged from the discharge unit of the air conditioner when an operation signal of the auxiliary blower is input;

The control unit analyzes the flow rate information of the air detected in the step of detecting the flow rate information of the air discharged from the discharge unit of the air conditioner, and adjusts the opening degree of the vent between the auxiliary blower and the discharge unit in accordance with the analysis result Outputting a control signal of the intake air controller; And

And outputting a driving signal of the auxiliary blower by the controller.

The detecting of the flow rate information of the air discharged from the discharge unit of the air conditioner may include detecting the air flow rate information selected from an input unit for inputting an operation control signal of the air conditioner and the flow rate information of the air discharged from the discharge unit of the air conditioner. And at least one of the flow rate information of the air detected from the sensor unit and the rotation speed information of the blower motor for discharging cold air.

In addition, it is characterized in that for detecting at least one information of the flow rate, flow rate and wind pressure of the air from the sensor unit.

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

First, repeated description of the same structure as the prior art is omitted.

Figure 3 is a block diagram schematically showing the configuration of the auxiliary blower intake air control device of the air conditioner according to the present invention, Figure 4 is a perspective view showing the blowing operation of the air conditioner is configured with the auxiliary blower intake air control device of the air conditioner according to the present invention, 5 is a cross-sectional view illustrating the air conditioner of FIG. 4.

3 to 5, the auxiliary blower intake air control device of the air conditioner according to the present invention is the cold air discharged from the input unit 100 for detecting the air conditioner operation control signal from the user, and the discharge unit 120 of the air conditioner The sensor unit 200 for detecting the amount of air, the air conditioner 300 for controlling overall operation of the air conditioner and the operation of the auxiliary blower intake air control device, and the air conditioner 400 for driving a cooling cycle of the air conditioner. And, the auxiliary blower 500, and the intake air control unit 600 for controlling the amount of cold air flowing into the auxiliary blower 500.

The input unit 100 is installed on the panel of the front center of the air conditioner to provide operation control signals of various air conditioners such as operation signals of the air conditioner and discharge wind speed of the air conditioner (for example, high speed, medium speed, and low speed wind strength) according to a user's selection. It receives the input and transmits it to the controller 300.

The sensor unit 200 is installed inside the discharge unit 120 of the air conditioner and detects the flow rate of the cold air discharged to the discharge unit 120. In addition, the sensor unit 200 detects not only the flow rate information of the cold air but also information such as the flow rate of the cold air and the wind pressure through which the cold air is discharged through the discharge unit, and transmits the detected information to the control unit 300.

The controller 300 controls the operation of the general air conditioner, the operation of the auxiliary blower 500, and the cold air sucked into the auxiliary blower 500 according to information such as the flow rate, flow rate, and wind pressure of the cold air discharged from the discharge unit 120 of the air conditioner. The amount of can be adjusted and is preferably a microprocessor.

That is, the controller 300 outputs a control signal to the intake air control unit 600 according to the information such as the wind speed or the air volume of the air conditioner detected from the input unit 100 so that the amount of cold air sucked into the auxiliary blower 500 is optimized. By adjusting, the auxiliary blower 500 is maintained to discharge a certain amount of cold air.

In addition, the control unit 300 outputs a control signal to the intake air control unit 600 according to information such as the flow rate of the cold air, the flow rate of the cold air, and the wind pressure of the cold air detected by the sensor unit 200 to the auxiliary blower 500. The amount of cold air sucked is adjusted to be optimized to maintain the auxiliary blower 500 to discharge a predetermined amount of cold air.

The auxiliary blower 500 is installed in a space partitioned by the partition wall 610 on the upper part of the discharge part 120 of the air conditioner, and the discharge part 120 communicates with the inside of the discharge part 120 on one side of the partition wall 610. Ventilation unit 620 is formed to suck the cold air to the auxiliary blower (500).

Therefore, the auxiliary blower 500 sucks a part of the cold air discharged to the discharge part 120 through the vent part 620 to the fan 510 and discharges it to the auxiliary discharge port 130. In addition, the fan 510 of the auxiliary blower 500 is composed of at least one of a turbo fan and a sirocco fan, and preferably a sirocco fan.

In addition, the ventilation unit 620 is installed at the rear side of the fan 510 so that the auxiliary blower 500 may suck cold air from the discharge unit 120, and the ventilation unit 620 according to the blowing amount of the auxiliary blower 500. The size of may vary appropriately.

The intake air adjusting unit 600 is installed at one side of the partition 610 having an air blower 500 on one side of the outlet blower 120 and an air vent 620 on one side, and preferably, the air vent 620. It is installed in close proximity to or installed on the inner side of the vent 620.

Intake air adjusting unit 600 is a configuration for adjusting the opening degree of the vent 620 so that the flow rate of the air sucked into the auxiliary blower 500, the control plate 630 for adjusting the opening degree of the vent 620 and The rotating shaft is connected to one side of the adjusting plate 630, and the control plate driving motor 640 rotates the adjusting plate 630 around the rotating shaft.

On the other hand, the control plate 630 is a plate-shaped member, the same shape as the vent 620, the cylinder between the discharge port 120 and the auxiliary discharge port 130 in accordance with the drive of the control plate driving motor 640. The base 620 is opened and closed.

In addition, the throttle plate driving motor 640 allows the throttle plate 630 to rotate about the rotation axis, and uses any one of a DC motor, a stepping motor, and a BLDC motor, and is preferably a stepping motor. .

Therefore, the throttle plate driving mutter 640 rotates the throttle plate 630 by a predetermined angle according to the control signal output from the control unit 300, thereby allowing the throttle plate 630 to adjust the opening degree of the vent 620.

6 is a flowchart illustrating a process of controlling an auxiliary blower intake air of an air conditioner according to the present invention, and with reference to FIGS. 3 to 6, the operation of the auxiliary blower intake air control device of the air conditioner according to the present invention will be described.

The auxiliary blower intake air control device of the air conditioner does not operate in the stopped state, and the control plate 630 blocks the vent 620 so that the discharge part 120 and the auxiliary discharge part 130 do not communicate with each other.

When the control unit 300 detects the operation signal of the air conditioner, that is, the cooling operation signal from the input unit 100, the control unit 300 outputs the operation signal to the cooling unit 400 to allow the air conditioner to perform the cooling operation (S100).

At this time, the cooling unit 400 sucks the indoor air through the suction unit 110 according to the operation signal input from the control unit 300, drives a predetermined cooling cycle to evaporate the cooled refrigerant and the sucked indoor air. Heat exchange at 64). The indoor air that is cooled by heat exchange in the evaporator 64, that is, the cold air, is discharged into the room through the discharge unit 120 of the upper part of the air conditioner according to the driving of the blower fan and the motors 72 and 73.

After performing step S100, the controller 300 determines whether a signal for determining whether the auxiliary blower 500 is driven from the input unit 100 is input (S110), and an operation signal of the auxiliary blower 500 is input. If not, the step S100 is performed.

On the other hand, when the operation signal of the auxiliary blower 500 is input from the input unit 100 in step S110, the control unit 300 detects the flow rate information of the air discharged from the discharge unit 120 of the air conditioner (S120).

The flow rate information of the air discharged to the discharge unit 120 in the step S120 is detected based on the air volume or wind speed information (for example, high speed, medium speed, low speed, etc.) input from the input unit 100, or discharge unit of the air conditioner ( 120, information such as a flow rate, a flow rate, and a wind pressure of the air discharged from the sensor unit 200 installed therein is detected.

The air volume or wind speed information can also be detected by analyzing the rotation speed of the drive motor 73 for driving the blowing fan 72.

The control unit 300 outputs a control signal for adjusting the opening degree of the venting unit 620 to the intake air adjusting unit 600 based on the flow rate information of the air detected in step S120 to determine the opening degree of the venting unit 620. Adjust (S130).

Here, the opening degree of the vent 620 is a reference value set in advance for adjusting the opening degree of the cold air discharged to the discharge part 120 (for example, when the reference value of the flow rate discharged at low speed) If higher, the opening degree of the vent 620 is increased to maintain the suction amount of the cold air flowing into the auxiliary blower 500, and if the flow rate lower than the reference value is detected, the opening degree of the vent 620 is the same. It is maintained or reduced so that the suction amount of cold air flowing into the auxiliary blower 500 through the vent 620 is kept constant.

The control unit 300 outputs a control signal of the intake air control unit 600 to adjust the opening degree of the ventilator 620, and then outputs a driving signal to the auxiliary blower 500 to drive the auxiliary blower 500, and the auxiliary blower The cold air sucked through the 500 is discharged into the room through the auxiliary discharge port 130.

Therefore, the auxiliary blower 500 can constantly inhale and discharge cold air irrespective of the flow rate, flow rate, etc. of the cold air discharged from the discharge unit 120, and can provide sufficient cold air at a long distance in the room.

As described above, the present invention has an advantage of allowing the cool air to be sufficiently sucked in the auxiliary blower installed to supply the cool air to the upper front surface of the air conditioner.

In addition, according to the flow rate, flow rate, wind pressure, etc. of the cold air discharged to the discharge portion of the air conditioner, the cold air sucked into the auxiliary blower can be kept constant, there is an advantage that the auxiliary blower can discharge the constant cold air.

In addition, there is an advantage that the short-range and long-distance cooling of the room can be made quickly by allowing sufficient cold air to be sucked into the auxiliary blower.

In the above, the present invention has been shown and described with respect to certain preferred embodiments. However, the present invention is not limited to the above-described embodiments, and those skilled in the art to which the present invention pertains can vary as many as possible without departing from the spirit of the present invention as set forth in the claims below. Changes may be made.

Claims (7)

In the air conditioner to suck and cool the indoor air according to the air volume selected by the user, and to discharge the cooled air to the discharge unit, An auxiliary discharge port partitioned and formed into a partition wall having a vent portion communicating with the discharge part on an upper portion of the discharge part; An auxiliary blower configured to suck a portion of the cooled air discharged to the discharge unit through the vent and blow the air to be discharged to the auxiliary discharge port; An intake air adjusting unit installed in the venting unit to adjust an opening degree of the venting unit to control a flow rate of air sucked into the auxiliary blower; And Control the inlet air of the air conditioner including a control unit for outputting a control signal to the intake air control unit to maintain a constant flow rate of the air flowing into the auxiliary blower by adjusting the opening degree of the vent according to the user selected air volume Device. The auxiliary blower of the air conditioner according to claim 1, further comprising a sensor unit installed inside the discharge unit to detect at least one of a flow rate, a flow rate, and a wind pressure of the cooled air discharged to the discharge unit. Air control unit. The auxiliary blower intake air control device of claim 2, wherein the control unit outputs a control signal of the intake air control unit so that the opening degree of the ventilation hole is adjusted according to the information detected from the sensor unit. According to claim 1, wherein the intake air adjusting portion control panel for adjusting the opening degree of the vent; And A rotating shaft is connected to one side of the control panel, the auxiliary blower intake air control device for an air conditioner comprising a control plate driving motor for rotating the control plate around the rotating shaft. As a control method of the auxiliary blower intake air control apparatus of the air conditioner comprised by any one of Claims 1-4, a) controlling, by the controller, operating the air conditioner by detecting an operation signal of the air conditioner from an input unit; b) determining, by the controller, whether a driving signal of an auxiliary blower is input from the input unit; c) detecting, by the controller, flow rate information of air discharged from the discharge unit of the air conditioner when the operation signal of the auxiliary blower is input in step b; d) analyzing, by the control unit, the flow rate information of the air detected in step c, and outputting a control signal of an intake air control unit for controlling an opening degree between the auxiliary blower and the discharge unit according to the analysis result; And e) an auxiliary blower intake air control device of an air conditioner, including the step of outputting a driving signal of the auxiliary blower by the controller. 6. The flow rate information of the air detected in step c includes: air flow rate information selected from an input unit for inputting an operation control signal of the air conditioner; And at least one of the detected flow rate information of the air and rotational speed information of the blower motor for discharging the cold air. The auxiliary blower intake air control device of claim 6, wherein the air information detected by the sensor unit detects at least one of a flow rate, a flow rate, and a wind pressure of the air.

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