KR101697328B1 - An Auto Control System, Air Conditioning Equipment for Environmental-Friendly Energy Saving - Google Patents

Abstract

The present invention detects circulating air in a pressure sensor, a temperature sensor, and a CO ₂ sensor installed inside an air conditioner, and automatically adjusts the air volume of a blower according to a set condition, It is possible to reduce the energy and to improve the air quality of the room and to automatically adjust the air volume of the blower according to the discriminated image condition, The present invention relates to an automatic control method for an energy saving type air conditioner capable of reducing energy consumed by a general mode (208). If the normal mode 208 is pressed as a result of the first step, the pressure sensor 200 and the air discharge chamber 138 installed at one side of the bottom surface of the filter chamber 122 are installed at one side of the bottom surface of the air discharge chamber 138 A second step of sending a control signal to the CO ₂ detection sensor 146; If the sensed pressure value of the filter chamber 122 is received from the pressure sensing sensor 200 after the second step, a third step of comparing the sensed pressure value with a predetermined pressure value is performed.

Description

[0001] The present invention relates to an automatic control method for an energy saving type air conditioner,

[0001] The present invention relates to an automatic control method for an air conditioner, and more particularly, to an automatic control method for an air conditioner that detects circulating air in a pressure sensor, a temperature sensor, and a CO ₂ sensor installed inside an air conditioner, The present invention relates to an automatic control method for an energy saving type air conditioner, which can reduce the energy generated during operation of the air conditioner and improve the air quality of the room.
According to the present invention, an image of a camera attached to a room is discriminated and the air volume of the blower is automatically controlled according to the discriminated image condition, thereby reducing the energy generated during operation of the air conditioner. The present invention relates to an automatic control method for a machine.

Energy-saving equipment and minimizing the installation area are inevitably required for all equipment using energy, and it takes time and money to satisfy them, and the demand level of users is also diversified. Therefore, simplification of operation method and high efficiency are becoming important parts.
In addition, since the management of air quality for multi-use facilities is legislated, it is necessary to manage the environmental and health problems for the residential people more precisely, but the related buildings are more enclosed and the need for further improvement and refinement need.
Generally, an air conditioner is a device that performs cooling, heating, and purifying functions in order to keep the indoor air at optimum conditions such as temperature, humidity, airflow, and air purification according to the purpose of use.
The air conditioner has been filed in the Korean Intellectual Property Office (KIPO) for a number of cases. For example, the contents of a patent application filed with the patent application No. 10-2009-0038687 (the name of the invention: air conditioner) 1,
An air handling unit including a blowing fan for supplying mixed air of outdoor air and indoor air to the room, a heat exchanger for exchanging the mixed air blown by the blowing fan with cold water, and a temperature sensor for sensing temperature; And a chiller that includes a compressor, a condenser, an expansion mechanism, and an evaporator, and the evaporator is connected to the heat exchanger by a water pipe to supply cold water to the heat exchanger. The chiller communicates with the air handling unit, And sets the cold water set temperature of the cold water supplied from the evaporator to the heat exchanger according to the result, and varies the operating capacity of the compressor according to the set cold water temperature.
1 denotes an air handling unit, 11 denotes an indoor air suction unit, 12 denotes an indoor air discharge unit, 13 denotes an outdoor air suction unit, 14 denotes an air discharge unit, 15 denotes a handling unit case, 21 denotes a ventilation duct Numeral 22 denotes an exhaust duct, numeral 23 denotes an air duct, numeral 24 denotes an air supply duct, numeral 26 denotes a mixing chamber, numerals 27 and 28 denote blowing fans, numeral 29 denotes a blower, numeral 30 denotes an air inlet, numeral 31 denotes an air outlet, numeral 32 denotes a housing, 35 is a motor, 36 is a drive pulley, 37 is a belt, 38 is a driven pulley, 40 is a heat exchanger, 41 and 42 are water pipes, 43, 44 and 45 are a damper, 46 and 47 are temperature sensors, Reference numeral 51 denotes a compressor, 52 denotes a condenser, 53 denotes an expansion mechanism, 54 denotes an evaporator, 55 denotes an oil separator, 56 denotes an oil recovery channel, 57 denotes an outdoor fan, and 58 denotes a cold water pump.

However, since the conventional air conditioner configured as described above uses an inverter motor for adjusting the air flow rate, a separate inverter control panel must be installed.
Further, there is a problem in that it is troublesome to use after adjusting the driving pulley in the equipment when adjusting the air volume in the conventional air conditioner, and there is a problem that the air volume adjustment is limited to about -20% to + 20%.
Particularly, in the conventional air conditioner, there is a troublesome problem that repetitive driving pulley replacement work is required to adjust the air volume once adjusted, and there is a problem that the CO ₂ sensor is not attached to the inside and the air quality can not be improved there was.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide a pressure sensor, a temperature sensor, and a CO ₂ sensor installed in the air conditioner, Automatic control of the energy saving type air conditioner which can reduce the energy generated during the operation of the air conditioner and improve the indoor air quality by automatically controlling the air flow rate of the blower automatically according to the detected condition .
It is another object of the present invention to provide an energy saving type air conditioner capable of automatically reducing the air volume of a blower in accordance with a discriminated condition of an image signal of a camera attached to a room, And an automatic control method of an air conditioner.

However, the object of the present invention is not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided an automatic control method for an energy saving type air conditioner,
A first step of determining whether the normal mode 208 is pressed;
If the normal mode 208 is pressed as a result of the first step, the pressure sensor 200 and the air discharge chamber 138 installed at one side of the bottom surface of the filter chamber 122 are installed at one side of the bottom surface of the air discharge chamber 138 A second step of sending a control signal to the CO ₂ detection sensor 146;
A third step of comparing the sensed pressure value with the sensed pressure value when the sensed pressure value of the filter chamber 122 is received from the pressure sensing sensor 200 after the second step;
If the sensed pressure value is greater than a predetermined pressure value, the controller 100 sends a control signal to the first BLDC motor 110 having the fan 112 installed on the bottom surface of the air suction chamber 106, A fourth step of discharging the outdoor air sucked by the fan 112 connected to the one BLDC motor 110 to the air storage chamber 114 through the first through hole of the first partition wall 108;
The fourth step after the air exhaust chamber 138, a CO ₂ value is received CO ₂ a predetermined value if the detection of the air discharge chamber 138 from the CO ₂ sensor 146 is installed on one side of the bottom surface and the sensing of the A fifth step of comparing the CO ₂ values obtained in step
Is smaller than the comparison detects a CO ₂ value of CO ₂ value is pre-set in said fifth step by sending a control signal to a 2BLDC motor 142 a is provided with a fan 144 is installed on the bottom surface of the air discharging chamber (138) The fan 144 connected to the second BLDC motor 142 discharges the air stored in the air discharge chamber 138 to the room through the fifth through hole 136 of the fifth partition wall 140 and the discharge port of the casing 104 A sixth step;
And a seventh step of stopping the second BLDC motor 142 by sending a control signal to the second BLDC motor 142 if the CO ₂ value detected in the sixth step is greater than a predetermined CO ₂ value.

As described above, the automatic control method of the energy saving type air conditioner according to the present invention detects the circulating air in the pressure sensor, the temperature sensor, and the CO ₂ sensor installed inside the air conditioner, The air volume of the blower is automatically controlled to automatically reduce the energy generated in the operation of the air conditioner and improve the indoor air quality.
Further, the present invention has an effect of reducing the energy generated during operation of the air conditioner by discriminating the video signal of the camera attached to the room and automatically controlling the air volume of the blower automatically according to the discriminated conditions.

1 shows an air conditioner according to the prior art,
2 is a schematic view of an energy saving type air conditioner used in the present invention,
FIG. 3 is a schematic view showing the configuration of the energy saving type air conditioner of FIG. 2,
FIG. 4 is an enlarged view of the air discharge chamber of the energy saving type air conditioner of FIG. 2,
FIG. 5 is an enlarged view of a fan connected to a BLDC motor installed in the air discharge chamber of FIG. 2,
FIG. 6 is a more detailed view of the energy saving type air conditioner of FIG. 2. FIG.

Hereinafter, a preferred embodiment of an automatic control method for an energy saving type air conditioner according to the present invention will be described. In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 2 is a schematic view of an energy saving type air conditioner used in the present invention, FIG. 3 is a view schematically showing the configuration of the energy saving type air conditioner of FIG. 2, FIG. 5 is an enlarged view of a fan connected to the BLDC motor installed in the air discharge chamber of FIG. 2, and FIG. 6 is an enlarged view of the air discharge chamber of the air conditioner in more detail Fig.

2 to 6, the energy saving type air conditioner 100 used in the present invention includes:
A casing (104) having a receiving space and having an outlet at one side of the outer surface;
A controller (102) installed at one side of the outer surface of the casing (104) at a predetermined distance from the discharge port and controlling the energy saving type air conditioner according to a predetermined program;
A first partition wall (108) vertically installed on one side of the casing (104), the first partition wall (108) having a first through hole to provide an air suction chamber (106);
An outdoor air intake port 109 provided on the upper surface of the air intake chamber 106;
And is installed on the bottom surface of the air suction chamber 106 and is electrically connected to the control unit 102 to suck outdoor air through the outdoor air intake port 109 in accordance with the control signal of the control unit 102, A first brushless DC motor 110 having a fan 112 for discharging the first through hole of the first partition 108 to the first through hole;
A second partition 116 vertically installed at one side of the interior of the casing 104 at a predetermined interval from the first partition 108 to provide an air storage chamber 114 having a second through-hole;
An air discharge port 118 installed on the upper surface of the air storage chamber 114 to discharge a part of the air stored in the air storage chamber 114 to the outside;
An air conditioning damper 120 installed in the second through hole of the second partition 116 to discharge the air stored in the air storage chamber 114 to the filter chamber through the second through hole,
A third partition wall 124 vertically installed at one side of the interior of the casing 104 at a predetermined distance from the second partition 116 and having a third through hole to provide a filter chamber 122;
An indoor air inlet 126 installed on the upper surface of the filter chamber 122 to introduce indoor air into the filter chamber 122;
The indoor air is supplied to the filter chamber 122 through the indoor air inlet 126 in accordance with a control signal of the controller 102. The indoor air A pressure sensor 200 for sensing the pressure of the pressure sensor 200;
The indoor air inlet 126 is installed at one side of the bottom surface of the filter chamber 122 at a predetermined distance from the pressure sensing sensor 200 and is electrically connected to the controller 102 to control the indoor air inlet 126 according to a control signal of the controller 102 A temperature sensor 202 for sensing the temperature of the room air flowing into the filter chamber 122;
A filter 128 installed at the third through-hole of the third partition 124 to filter air stored in the filter chamber 122 and discharge the air through the third through-hole to the heat exchange chamber;
A heat exchange chamber 130 vertically installed at one side of the interior of the casing 104 at regular intervals from the third partition wall 124 and provided with a heating means (not shown) and a cooling means (not shown) A fourth barrier rib 132 for providing a second barrier rib;
A fourth through-hole 134 installed at one side of the fourth partition 132 to discharge the heat-exchanged air in the heat exchange chamber 130 to the air discharge chamber;
A fifth partition wall 140 vertically installed on the inner surface of the casing 104 at a predetermined interval from the fourth partition 132 and provided with a fifth through hole 136 to provide an air discharge chamber 138, ;
One or more air discharge chambers 138 are provided on the bottom surface of the air discharge chamber 138. The air discharged from the air discharge chamber 138 is electrically connected to the control unit, A second BLDC motor 142 having a through hole 136 and a fan 144 for discharging the air to the room through a discharge port of the casing 104;
The second BLDC motor 142 is provided at one side of the bottom surface of the air discharge chamber 138 at a predetermined interval from the second BLDC motor 142 having the fan 144. The control signal is electrically connected to the control unit 102, in accordance with the CO ₂ sensor 146 for sensing the CO ₂ of the air stored in the air discharge chamber (138);
And an image discrimination unit 206 electrically connected to the control unit 102 for discriminating between the indoor image information received from the camera 300 and the predetermined indoor image information according to the control signal of the control unit 102.

The fifth through hole 136 of the fifth partition 140 is on the same line as the discharge port of the casing 104. The control unit 102 electrically connects the camera 300, Respectively.

In addition, the control unit 102 is electrically connected to a normal mode 208 in which the camera is not operated, and a video mode 210 for operating the camera is electrically connected.

The operation of the energy saving type air conditioner constructed as above, that is, the automatic control method of the energy saving type air conditioner 100 according to the present invention, will be described below.

A method for automatically controlling the energy saving type air conditioner (100) of the first embodiment.

First, the control unit 102 determines whether the normal mode 208 is pressed (S1-1).
Here, the normal mode means that the energy saving type air conditioner 100 is operated automatically without operating the camera.
When the normal mode 208 is pressed as a result of the determination in S1-1, the controller 102 controls the pressure sensor 200 and the air discharge chamber 138, which are installed on one side of the bottom surface of the filter chamber 122, A control signal is sent to the CO ₂ detection sensor 146 installed at one side (S1-3).

The pressure sensing sensor 200 senses the pressure of air in the filter chamber 122 flowing into the filter chamber 122 through the indoor air inlet 126 according to the control signal of the controller 102, To the control unit 102 (S1-5).
If the sensed pressure value is greater than a predetermined pressure value, the control unit 102 compares the sensed pressure value with the sensed pressure value (S1-7) And sends a control signal to a first brushless DC motor 110 provided with a controller 112 (S1-9).
The fan 112 connected to the first BLDC motor 110 sucks the outdoor air from the outdoor air inlet 109 according to the control signal of the controller 102 and then outputs the drawn outdoor air To the air storage chamber 114 through the first through hole of the first partition 108 (S1-11).

The air outlet 118 discharges a part of the air stored in the air storage chamber 114 to the outside and the air conditioning damper 114 supplies the remaining air stored in the air storage chamber 114 to the outside of the second partition 116 Through the second through hole to the filter chamber 122 (S1-13).

The indoor air inlet 126 introduces indoor air into the filter chamber 122 (S1-15).

The air stored in the filter chamber 122 is filtered by the filter 128 and the filtered air is passed through the third through hole of the third partition wall 124 to the heating means And discharged to a heat exchange chamber 130 provided with a cooling means (not shown) (S1-17).

The heat exchange chamber 130 drives the heating means or the cooling means according to the control signal of the control unit 102 to exchange the air and then the exchanged air is passed through the fourth through hole 134 of the fourth partition wall 132, To the air discharge chamber 138 (S1-19).

The CO ₂ detection sensor 146 installed at one side of the bottom surface of the air discharge chamber 138 is connected to the air discharge chamber 138 discharged to the air discharge chamber 138 in accordance with a control signal of the control unit 102 After sensing the CO ₂ of the air, the sensed CO ₂ value is sent to the control unit 102 (S1-21).
The control unit 102 a predetermined CO ₂ value and the detected value of CO ₂ compared to (S1-23) after, if the detected value of CO ₂ group is less than a predetermined CO ₂ value the bottom surface of the air discharging chamber (138) And sends a control signal to the second BLDC motor 142 equipped with the fan 144 installed in the first BLDC motor 142 (S1-25).
The second BLDC motor 142 drives the fan 144 connected to the second BLDC motor 142 to move the air stored in the air discharge chamber 138 to a position of the fifth partition wall 140 in accordance with the control signal of the controller 102 Through hole (136), and the discharge port of the casing (104).

If the CO ₂ value detected in S1-23 is greater than a predetermined CO ₂ value, the control signal is sent to the second BLDC motor 142 (S1-27). At this time, the second BLDC motor 142 is stopped according to the control signal of the controller 102.

A method for automatically controlling an energy saving type air conditioner (100) according to the second embodiment.

First, the control unit 102 determines whether the normal mode 208 is pressed (S2-1).
Here, the normal mode means that the energy saving type air conditioner 100 is operated automatically without operating the camera.
If the general mode 208 is pressed as a result of the determination in S2-1, the controller 102 controls the pressure sensor 200 and the air discharge chamber 138, which are installed on one side of the bottom surface of the filter chamber 122, A control signal is sent to the CO ₂ detection sensor 146 installed at one side (S2-3).

The pressure sensing sensor 200 senses the pressure of air in the filter chamber 122 flowing into the filter chamber 122 through the indoor air inlet 126 according to the control signal of the controller 102, To the control unit 102 (S2-5).
If the sensed pressure value is smaller than the predetermined pressure value, the control unit 102 compares the sensed pressure value with the sensed pressure value (S2-7) (Step S2-9).

The temperature sensor 202 senses the temperature of the air in the filter chamber 122 flowing into the filter chamber 122 through the indoor air inlet 126 according to the control signal of the controller 102, To the control unit 102 (S2-11).
The control unit 102 compares the sensed temperature value with the preset temperature value (S2-13). If the sensed temperature value is greater than the predetermined temperature value, the control unit 102 compares the sensed temperature value with the fan installed on the bottom surface of the air- And sends a control signal to the first BLDC motor 110 having the first controller 112 (S2-15).
The fan 112 connected to the first BLDC motor 110 sucks the outdoor air from the outdoor air inlet 109 according to the control signal of the controller 102 and then outputs the drawn outdoor air To the air storage chamber 114 through the first through hole of the first partition 108 (S2-17).

The air outlet 118 discharges a part of the air stored in the air storage chamber 114 to the outside and the air conditioning damper 114 supplies the remaining air stored in the air storage chamber 114 to the outside of the second partition 116 Through the second through hole to the filter chamber 122 (S2-19).

The indoor air inlet 126 introduces indoor air into the filter chamber 122 (S2-21).

The air stored in the filter chamber 122 is filtered by the filter 128 and the filtered air is passed through the third through hole of the third partition wall 124 to the heating means And discharged to a heat exchange chamber 130 provided with a cooling means (not shown) (S2-23).

The heat exchange chamber 130 drives the heating means or the cooling means according to the control signal of the control unit 102 to exchange the air and then the exchanged air is passed through the fourth through hole 134 of the fourth partition wall 132, To the air discharge chamber 138 (S2-25).

The CO ₂ detection sensor 146 installed at one side of the bottom surface of the air discharge chamber 138 is connected to the air discharge chamber 138 discharged to the air discharge chamber 138 in accordance with a control signal of the control unit 102 After sensing the CO ₂ of the air, the sensed CO ₂ value is sent to the control unit 102 (S2-27).
The control unit 102 a predetermined CO ₂ value and the detected value of CO ₂ compared to (S2-29) after, if the detected value of CO ₂ group is less than a predetermined CO ₂ value the bottom surface of the air discharging chamber (138) And sends a control signal to the second BLDC motor 142 equipped with the fan 144 (S2-31).
The second BLDC motor 142 drives the fan 144 connected to the second BLDC motor 142 to move the air stored in the air discharge chamber 138 to a position of the fifth partition wall 140 in accordance with the control signal of the controller 102 Through hole (136), and the discharge port of the casing (104).

If the CO ₂ value detected in S2-29 is greater than a predetermined CO ₂ value, the control signal is sent to the second BLDC motor 142 (S2-33). At this time, the second BLDC motor 142 is stopped according to the control signal of the controller 102.

A method for automatically controlling the energy saving type air conditioner (100) according to the third embodiment.

First, the control unit 102 determines whether the image mode 210 is pressed (S3-1).
Here, the image mode means that the energy saving type air conditioner 100 is automatically operated while operating a camera installed at one side of the ceiling of the room.
If the image mode 210 is pressed as a result of the determination in S3-1, the control unit 102 sends a control signal to the camera 300 installed at one side of the ceiling of the room (S3-3).

The camera 300 photographs the motion of the user residing in the space in which the camera is installed according to the control signal of the control unit 102, and then sends the captured moving image information of the user to the control unit 102 (S3 -5).
Then, the control unit 102 sends the received motion image information of the user to the image discrimination unit 204 (S3-7).
Then, the image discrimination unit 204 compares the preset image information with the motion image information of the received user according to the control signal of the controller 102, And sends a video information matching signal to the control unit 102 (S3-9).

When the image information matching signal is received, the control unit 102 is installed at one side of the bottom surface of the pressure sensing sensor 200 and the air discharge chamber 138 provided at one side of the bottom surface of the filter chamber 122 And sends a control signal to the CO ₂ detection sensor 146 (S3-11).

The pressure sensing sensor 200 senses the pressure of air in the filter chamber 122 flowing into the filter chamber 122 through the indoor air inlet 126 according to the control signal of the controller 102, To the control unit 102 (S3-13).
If the sensed pressure value is greater than a predetermined pressure value, the control unit 102 compares the sensed pressure value with the sensed pressure value (S3-15) And sends a control signal to the first BLDC motor 110 having the second control signal 112 (S3-17).
The fan 112 connected to the first BLDC motor 110 sucks the outdoor air from the outdoor air inlet 109 according to the control signal of the controller 102 and then outputs the drawn outdoor air To the air storage chamber 114 through the first through hole of the first partition 108 (S3-19).

The air outlet 118 discharges a part of the air stored in the air storage chamber 114 to the outside and the air conditioning damper 114 supplies the remaining air stored in the air storage chamber 114 to the outside of the second partition 116 And discharged to the filter chamber 122 through the second through hole (S3-21).

The indoor air inlet 126 introduces indoor air into the filter chamber 122 (S3-23).

The air stored in the filter chamber 122 is filtered by the filter 128 and the filtered air is passed through the third through hole of the third partition wall 124 to the heating means And discharged to a heat exchange chamber 130 provided with a cooling means (not shown) (S3-25).

The heat exchange chamber 130 drives the heating means or the cooling means according to the control signal of the control unit 102 to exchange the air and then the exchanged air is passed through the fourth through hole 134 of the fourth partition wall 132, To the air discharge chamber 138 (S3-27).

The CO ₂ detection sensor 146 installed at one side of the bottom surface of the air discharge chamber 138 is connected to the air discharge chamber 138 discharged to the air discharge chamber 138 in accordance with a control signal of the control unit 102 After sensing the CO ₂ of the air, the sensed CO ₂ value is sent to the control unit 102 (S3-29).
The control unit 102 a predetermined CO ₂ value and the detected value of CO ₂ compared to (S3-31) after, if the detected value of CO ₂ group is less than a predetermined CO ₂ value the bottom surface of the air discharging chamber (138) To the second BLDC motor 142 equipped with the fan 144 installed in the first BLDC motor 142 (S3-33).
The second BLDC motor 142 drives the fan 144 connected to the second BLDC motor 142 to move the air stored in the air discharge chamber 138 to a position of the fifth partition wall 140 in accordance with the control signal of the controller 102 Through hole (136), and the discharge port of the casing (104).

If the CO ₂ value detected in step S3-31 is greater than the predetermined CO ₂ value, the control signal is sent to the second BLDC motor 142 (step S3-35). At this time, the second BLDC motor 142 is stopped according to the control signal of the controller 102.

A method for automatically controlling the energy saving type air conditioner (100) according to the fourth embodiment.

First, the control unit 102 determines whether the image mode 210 is pressed (S4-1).
Here, the image mode means that the energy saving type air conditioner 100 is automatically operated while operating a camera installed at one side of the room.
If the image mode 210 is pressed as a result of the determination in S4-1, the control unit 102 sends a control signal to the camera 300 installed at one side of the ceiling of the room (S4-3).

The camera 300 photographs the motion of the user residing in the space where the camera is installed according to the control signal of the control unit 102, and then sends the captured moving image information of the user to the control unit 102 (S4 -5).
Then, the controller 102 sends the received motion image information to the image determining unit 204 (S4-7).
Then, the image discrimination unit 204 compares the preset image information with the motion image information of the received user according to the control signal of the controller 102, And sends a video information matching signal to the control unit 102 (S4-9).

When the image information matching signal is received, the control unit 102 is installed at one side of the bottom surface of the pressure sensing sensor 200 and the air discharge chamber 138 provided at one side of the bottom surface of the filter chamber 122 And sends a control signal to the CO ₂ detection sensor 146 (S4-11).

The pressure sensing sensor 200 senses the pressure of the indoor air flowing into the filter chamber 122 through the indoor air inlet 126 according to the control signal of the controller 102, (S4-13).
If the sensed pressure value is less than the predetermined pressure value, the control unit 102 sends a control signal to the temperature sensor 202 (S415) -17).

The temperature sensor 202 senses the temperature of the air in the filter chamber 122 flowing into the filter chamber 122 through the indoor air inlet 126 according to the control signal of the controller 102, To the control unit 102 (S4-19).
The control unit 102 compares the sensed temperature value with the preset temperature value (S4-21). If the sensed temperature value is greater than the predetermined temperature value, the control unit 102 compares the sensed temperature value with the fan installed on the bottom surface of the air- (Step S4-23) to the first BLDC motor 110 having the first BLDC motor 112.
The fan 112 connected to the first BLDC motor 110 sucks the outdoor air from the outdoor air inlet 109 according to the control signal of the controller 102 and then outputs the drawn outdoor air To the air storage chamber 114 through the first through hole of the first partition 108 (S4-25).

The air outlet 118 discharges a part of the air stored in the air storage chamber 114 to the outside and the air conditioning damper 114 supplies the remaining air stored in the air storage chamber 114 to the outside of the second partition 116 Through the second through hole to the filter chamber 122 (S4-27).

The room air inlet 126 introduces the room air into the filter room 122 (S4-29).

The air stored in the filter chamber 122 is filtered by the filter 128 and the filtered air is passed through the third through hole of the third partition wall 124 to the heating means And discharged to a heat exchange chamber 130 provided with a cooling means (not shown) (S4-31).

The heat exchange chamber 130 drives the heating means or the cooling means according to the control signal of the control unit 102 to exchange the air and then the exchanged air is passed through the fourth through hole 134 of the fourth partition wall 132, To the air discharge chamber 138 (S4-33).

The CO ₂ detection sensor 146 installed at one side of the bottom surface of the air discharge chamber 138 is connected to the air discharge chamber 138 discharged to the air discharge chamber 138 in accordance with a control signal of the control unit 102 After sensing the CO ₂ of the air, the sensed CO ₂ value is sent to the control unit 102 (S4-35).
The control unit 102 a predetermined CO ₂ value and the detected value of CO ₂ compared to (S4-37) after, if the detected value of CO ₂ group is less than a predetermined CO ₂ value the bottom surface of the air discharging chamber (138) And sends a control signal to the second BLDC motor 142 equipped with the fan 144 (S4-39).
The second BLDC motor 142 drives the fan 144 connected to the second BLDC motor 142 to move the air stored in the air discharge chamber 138 to a position of the fifth partition wall 140 in accordance with the control signal of the controller 102 Through hole (136), and the discharge port of the casing (104).

If the CO ₂ value detected in step S4-37 is greater than the predetermined CO ₂ value, the control signal is sent to the second BLDC motor 142 (S4-41). At this time, the second BLDC motor 142 is stopped according to the control signal of the controller 102.

The foregoing description of the invention is merely exemplary of the invention and is used for the purpose of illustration only and is not intended to limit the scope of the invention as defined in the claims or the claims. Therefore, those skilled in the art will appreciate that various modifications and equivalent embodiments are possible without departing from the scope of the present invention. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: energy saving type air conditioner 102: control unit
104: casing 106: air suction chamber
108: first partition 109: outdoor air intake
110: BLDC motor 112: fan
114: air storage chamber 116: second partition
118: Air outlet 120: Air conditioning damper
122: filter chamber 124: third partition
126: Indoor air inlet 128: Filter
146: CO ₂ detection sensor 200: Pressure detection sensor
202: temperature detection sensor 204: image discrimination unit
300: camera

Claims (4)

A first step of determining whether the normal mode 208 is pressed;
If the normal mode 208 is pressed as a result of the first step, the pressure sensor 200 and the air discharge chamber 138 installed at one side of the bottom surface of the filter chamber 122 are installed at one side of the bottom surface of the air discharge chamber 138 A second step of sending a control signal to the CO ₂ detection sensor 146;
A third step of comparing the sensed pressure value with the sensed pressure value when the sensed pressure value of the filter chamber 122 is received from the pressure sensing sensor 200 after the second step;
If the sensed pressure value is greater than a predetermined pressure value, the controller 100 sends a control signal to the first BLDC motor 110 having the fan 112 installed on the bottom surface of the air suction chamber 106, A fourth step of discharging the outdoor air sucked by the fan 112 connected to the one BLDC motor 110 to the air storage chamber 114 through the first through hole of the first partition wall 108;
The fourth step after the air exhaust chamber 138, a CO ₂ value is received CO ₂ a predetermined value if the detection of the air discharge chamber 138 from the CO ₂ sensor 146 is installed on one side of the bottom surface and the sensing of the A fifth step of comparing the CO ₂ values obtained in step
Is smaller than the comparison detects a CO ₂ value of CO ₂ value is pre-set in said fifth step by sending a control signal to a 2BLDC motor 142 a is provided with a fan 144 is installed on the bottom surface of the air discharging chamber (138) The fan 144 connected to the second BLDC motor 142 discharges the air stored in the air discharge chamber 138 to the room through the fifth through hole 136 of the fifth partition wall 140 and the discharge port of the casing 104 A sixth step;
And a seventh step of stopping the second BLDC motor 142 by sending a control signal to the second BLDC motor 142 when the CO ₂ value detected in the sixth step is greater than a predetermined CO ₂ value,
An eighth step of sending a control signal to the temperature sensor 202 installed on the bottom surface of the filter chamber 122 if the sensed pressure value is less than a preset pressure value in the third step;
If the sensed temperature value of the filter chamber 122 is received from the temperature sensor 202 after the eighth step, comparing the sensed temperature value with a predetermined temperature value;
If the sensed temperature value is greater than a preset temperature value, the controller 100 sends a control signal to the first BLDC motor 110 having the fan 112 installed on the bottom surface of the air suction chamber 106, A step 10 of discharging the outdoor air sucked by the fan 112 connected to the 1 BLDC motor 110 to the air storage chamber 114 through the first through hole of the first partition 108;
The first step 10 and then, the air discharge chamber 138, the bottom surface a CO ₂ value is received CO ₂ a predetermined value if the detection of a CO ₂ sensor 146 is installed on one side of the air discharge chamber (138) and the sense of Comparing the calculated CO ₂ values;
Is smaller than the comparison detects a CO ₂ value of CO ₂ value is pre-set in the second step 11 by sending a control signal to a 2BLDC motor 142 a is provided with a fan 144 is installed on the bottom surface of the air discharging chamber (138) The fan 144 connected to the second BLDC motor 142 discharges the air stored in the air discharge chamber 138 to the room through the fifth through hole 136 of the fifth partition wall 140 and the discharge port of the casing 104 A twelfth step;
And stopping the second BLDC motor 142 by sending a control signal to the second BLDC motor 142 when the CO ₂ value detected in step 12 is greater than a preset CO ₂ value. Automatic control method of air conditioner.
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