KR101243227B1 - Ventilation System and control Method of the same of - Google Patents

Abstract

The present invention relates to a ventilation system and a control method thereof, and an object of the present invention is to prevent cold air from directly entering a room, so that condensation does not occur in a room without having a heater for compensating for outside temperature, The present invention provides a ventilation system and a control method for preventing the cold draft.

To this end, the ventilation system according to the present invention includes an indoor unit in which an indoor air circulation passage through which indoor air is circulated is formed; It includes a total heat exchanger for providing the introduced outside air upstream of the circulation passage so that the introduced outside air is mixed with the indoor air flowing through the indoor air circulation passage to be discharged to the room.

Ventilation system, total heat exchanger, cold draft

Description

Ventilation system and control method of the same of

The present invention relates to a ventilation system having a total heat exchanger and a control method thereof, and more particularly, to prevent cold air from directly entering a room, and to prevent dew condensation in a room without providing a heater for compensating the outside temperature. The present invention relates to a ventilation system and a control method for preventing a user from experiencing a cold draft.

In general, a ventilation system is a device that allows fresh outdoor air to flow into a room using a blower fan, and indoor air polluted by the respiration of living organisms to exhaust the polluted indoor air to the outside. .

However, the ventilation system is discharged to the outside without recovering the cold air or heat of the indoor air using only the blowing fan, and at the same time, the outdoor air having the temperature and temperature difference of the indoor air is introduced into the room. Accordingly, since the room needs to be cooled or heated again, the ventilation system requires energy for cooling or heating the room, causing an energy loss.

In order to overcome this disadvantage, the ventilation system has a trend that is provided with a total heat exchanger to recover the cold air or heat from the indoor air that is exhausted to the outside to provide the outside air supplied to the room.

On the other hand, the conventional ventilation system allows the outdoor air to be introduced into the room without recovering sufficient heat from the total heat exchanger while the outdoor air is introduced into the room when the outdoor air temperature is drastically low in winter or cold conditions. Accordingly, there is a problem that the cold outside air flows directly into the room, condensation occurs in the room, and the user experiences a cold draft.

In order to solve this problem, recently, a ventilation system for providing an outside temperature compensation heater at the outside air inlet side of the total heat exchanger to allow the cold outside air to be introduced into the total heat exchanger has been proposed.

However, the above-described ventilation system having an outside temperature compensation heater has a disadvantage of requiring much power consumption for the operation of the ventilation system because the outside temperature compensation heater needs to be operated. Furthermore, there is a problem of increasing the manufacturing process of the ventilation system and increasing the manufacturing cost, since the heater for compensating the outside temperature must be separately installed.

Accordingly, an object of the present invention is to prevent cold air from flowing directly into the room, to prevent condensation from occurring in the room without having an external air temperature compensation heater, and to prevent the user from experiencing a cold draft. It is to provide a ventilation system and a control method thereof.

Ventilation system according to the present invention for achieving the object of the present invention as described above is an indoor unit formed with an indoor air circulation passage through which the indoor air circulates; It includes a total heat exchanger for providing the introduced outside air upstream of the circulation passage so that the introduced outside air is mixed with the indoor air flowing through the indoor air circulation passage to be discharged to the room.

The air supply duct may further include an air supply duct connecting at least a portion of the air supply outlet of the total heat exchanger and the inlet of the indoor unit.

Ventilation system according to the present invention for achieving the object of the present invention as described above in another aspect is an indoor unit including an indoor inlet fan and an indoor blowing fan motor for rotating the indoor blowing fan to circulate the indoor air; A total heat exchanger which receives the outside air and provides the outside air to the suction port; And a controller for controlling the rotation of the indoor blower fan according to a result of comparing the outside temperature with a reference value.

Here, if the outside temperature is less than the reference value, the controller adjusts the rotational speed of the indoor blowing fan motor according to the outside temperature. At this time, the outside air temperature and the rotational speed of the indoor blowing fan motor is in a proportional relationship.

And a hood for exhausting the polluted air of the kitchen, wherein the control unit causes the indoor blowing fan motor to rotate when the hood is in operation, and closes the electric expansion valve of the indoor unit to operate the hood. Allow the exhaust fan motor to stop.

In addition, the control method of the ventilation system according to the present invention for achieving the object of the present invention as described above is an indoor unit having an indoor circulation flow path for circulating the indoor air; In the control method of the ventilation system comprising a total heat exchanger for providing the inlet air to the suction port side of the indoor unit so that the incoming outdoor air is mixed with the indoor air flowing through the indoor circulation flow path to be discharged into the room. Detects outside temperature; Comparing the sensed outside temperature with a reference value; The rotation of the indoor blower fan motor of the indoor unit is controlled according to the comparison result.

Here, when the sensed outside temperature is greater than the reference value, the rotation of the indoor blower fan motor of the indoor unit is stopped.

In another aspect, the control method of the ventilation system according to the present invention for achieving the object of the present invention as described above is a hood and the indoor unit is formed with a hood for discharging the polluted air of the kitchen, the indoor air circulation passage to allow the indoor air circulated In the control method of the ventilation system comprising a total heat exchanger for providing the inlet air to the inlet of the indoor unit so that the outside air is mixed with the indoor air flowing through the indoor air circulation flow path to be discharged into the room, if the hood is operating Rotate the indoor blower fan motor, allow the electric expansion valve of the indoor unit to operate closed, allow the air supply fan motor of the heat exchanger to rotate, and stop the exhaust fan motor of the heat exchanger.

By the ventilation system and the control method according to the present invention as described above, the cold air is prevented from flowing directly into the room, the dew condensation is prevented from occurring in the room without having a heater for compensating the outside temperature, the user is cold This has the effect of not experiencing a cold draft.

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

1 and 2, the ventilation system 1 according to the present invention includes a hood 100 for exhausting polluted air in a kitchen, an indoor unit 300 for air conditioning the room, and a system for ventilating indoor air. And a control unit 600 for controlling the total heat exchanger 200 and the ventilation system 1.

The hood 100 has a hood inlet 111 and a hood exhaust port 112 formed therein, and a hood body 110 having a hood exhaust passage 140 formed therein, and a hood fan installed on the hood exhaust passage 140. The hood fan motor 130 for rotating the hood fan 120 and the hood controller 150 for controlling the hood 100 as a whole are included.

The hood body 110 is installed in the kitchen so that the hood inlet 111 at the upper side of the range toward the range and the hood exhaust port 112 is exposed to the outdoors or connected to the exhaust duct.

A hood input unit 151 is provided on an input side of the hood control unit 150, and a hood fan motor driver 152 that drives the hood fan motor 130 is provided on an output side. The hood controller 150 receives a driving command from the hood input unit 151 by the user, and supplies the control signal according to the driving command to the hood fan motor driving unit 152 to rotate or stop the hood fan motor 130. Be sure to

The hood controller 150 is communicatively connected to the controller 600 to provide the controller 600 with information about whether the hood 100 is operated.

The hood fan 120 is rotated by the hood fan motor 130 to suck the contaminated air of the kitchen through the hood inlet 111, and blows the contaminated air of the kitchen sucked in this way to the hood exhaust port 112. Accordingly, the contaminated air of the kitchen passes through the hood inlet 111, the hood exhaust passage 140, and the hood exhaust port 112, and then is exhausted to the outdoor or exhaust duct. As a result, the kitchen has a contaminated air is exhausted out of the kitchen is a pleasant state.

The indoor unit 300 includes an indoor unit main body 310 having an indoor unit suction port 311 and an indoor unit discharge port 312 formed therein, and an indoor air circulation passage 360 formed therein, and installed on the indoor air circulation passage 360. A heat exchanger 330, an electric expansion valve 331 for expanding the refrigerant flowing into the heat exchanger 330, an indoor blowing fan 320 installed on one side of the heat exchanger 330 for forced circulation of indoor air; , The indoor blowing fan motor 321 rotating the indoor blowing fan 320 and the indoor unit controller 350 for controlling the indoor unit 300 as a whole, and an indoor temperature for providing a signal according to the indoor air temperature to the indoor unit controller 350. Sensor 351.

The indoor unit main body 310 is installed in a clean room or the like so that the indoor unit suction port 311 and the indoor unit discharge port 312 face the interior. The indoor unit suction port 311 is provided with an indoor temperature sensor 351 for sensing the indoor temperature. One side of the indoor unit suction port 311, that is, the upstream side of the indoor air circulation passage 360 is connected to the branch supply duct 410 connected to the air supply outlet 212 of the heat exchanger 300, which will be described later, and the heat exchanger 200. The outside air supplied from) flows into the indoor air circulation passage 360.

The heat exchanger 330 includes a refrigerant tube (not shown) through which a refrigerant flows and a plurality of heat exchange fins (not shown) into which a refrigerant tube through which the refrigerant flows is inserted. One end of the refrigerant tube is connected to the refrigerant supply pipe 371 connected to the outdoor unit (not shown) and the other end of the refrigerant tube is connected to the refrigerant return tube 372 connected to the outdoor unit. On the refrigerant supply pipe 371, an electric expansion valve 331, which is controlled by the indoor unit controller 350 and expands the liquid refrigerant provided to the refrigerant tube, is installed. When the refrigerant flows through the refrigerant tube, the heat exchanger 330 allows the refrigerant and air in the vicinity of the heat exchanger 330 to exchange heat with each other.

The indoor blower fan 320 is installed at the indoor unit discharge port 312 side. The indoor blowing fan 320 is rotated by the indoor blowing fan motor 332 controlled by the indoor unit controller 350. On the other hand, when the indoor blowing fan 320 is rotated, the indoor air is sucked through the indoor air intake port 311 and then discharged back into the room through the indoor air discharge port 312 via the indoor air circulation passage 360.

An indoor temperature sensor 351 is provided on an input side of the indoor unit controller 350, and an indoor blower fan motor driver 352 for driving an indoor blower fan motor 332 is provided on an output side. In addition, the indoor unit controller 350 is communicatively connected to the controller 600 to provide the indoor temperature obtained using the indoor temperature sensor 351 to the controller 600 or to blow the indoor air according to a control signal input from the controller 600. The fan motor 332 and the electric expansion valve 351 are controlled.

The total heat exchanger (300) is a total heat exchanger (210) for forming an air supply passage (270) and an exhaust passage (280) therein, and a heat exchanger installed at an intersection of the air supply passage (270) and the exhaust passage (280). Element 220, an air supply fan 240 provided at the outlet side of the air supply passage 270, an air supply fan motor 241 for rotating the air supply fan 240, and an outlet side of the exhaust passage 280 The exhaust fan 230, the exhaust fan motor 231 which rotates the exhaust fan 230, the total heat exchanger controller 250 which controls the total heat exchanger 300, and a signal according to the pollution degree of indoor air. And a pollution sensor 250 provided to the total heat exchanger controller 250 and an outside temperature sensor 251 providing a signal according to the ambient temperature to the total heat exchanger controller 250.

On one side of the total heat exchanger case 210 is formed air inlet 211 through which fresh air is introduced. In addition, an air supply outlet 212 is formed in a diagonal direction of the air supply inlet 211. The air supply inlet 211 and the air supply outlet 212 is connected to the upstream and downstream of the air supply passage 270.

The air supply inlet 211 is provided with an outside air temperature sensor 251 for sensing the outside air temperature. The outside temperature sensor 251 provides a signal corresponding to the outside temperature to the heat exchanger controller 250. Accordingly, the total heat exchanger controller 250 can calculate the outside air temperature.

The air supply outlet 212 is connected to the air supply duct 400, the branch air supply duct 410 branched from the air supply duct 400 is the air discharged through the air supply outlet 212 of the heat exchanger 200 directly to the room It is connected to the indoor unit suction port 311 of the indoor unit 300 so as not to flow.

On the other hand, when the air supply fan 240 is rotated by the air supply fan motor 241, after the outdoor air passes through the air supply inlet 211 and the air supply passage 270 sequentially, it is exhausted through the air supply outlet 212. Accordingly, the fresh outside air discharged from the air supply outlet 212 is mixed with the indoor air circulated by the indoor unit 300 and discharged into the room, or discharged into the room after passing through the indoor unit 300.

The other side of the heat exchanger case 210 is formed with an exhaust inlet 213 through which indoor air flows. An exhaust outlet 214 is formed in a diagonal direction of the exhaust inlet 213. The exhaust inlet 213 and the air supply outlet 214 are connected upstream and downstream of the exhaust passage 280. In addition, a return duct 500 is connected to the exhaust inlet 213 to allow the contaminated air in the room to move toward the heat exchanger 200.

On the other hand, when the exhaust fan 230 is rotated by the exhaust fan motor 231, the polluted air in the room is the return duct 500 and the air passes through the exhaust inlet 213 and the exhaust passage 280 sequentially Thereafter, the gas is exhausted to the outside through the exhaust outlet 214.

An external air temperature sensor 251 and a pollution sensor 252 are provided on an input side of the total heat exchanger control unit 250, and an air supply fan motor driver 253 and an exhaust fan motor 231 for driving the air supply fan motor 241 on the output side. An exhaust fan motor driving unit 254 for driving the engine is provided. The heat exchanger controller 250 is communicatively connected to the input unit 610.

When the heat exchanger control unit 250 receives an operation command from the input unit 610, it calculates the pollution degree of the indoor air using a signal input from the pollution sensor 252, and calculates the air supply amount and the displacement according to the pollution degree. do. Then, the rotation speeds of the exhaust fan 230 and the air supply fan 240 corresponding to the air supply amount and the exhaust amount according to the pollution degree are calculated. Then, a control signal corresponding to the rotational speed is provided to the air supply fan motor driver 253 and the exhaust fan motor driver 254. Accordingly, the air supply fan motor driving unit 253 and the exhaust fan motor driving unit 254 rotate the exhaust fan 230 and the air supply fan 240 at a rotational speed according to the pollution degree, and the heat exchanger 200 of the indoor air It operates properly with the displacement and the air supply according to the pollution degree.

The total heat exchanger controller 250 calculates the outside air temperature using a signal input from the outside air temperature sensor 251, and provides the calculated outside air temperature to the controller 600.

The control unit 600 is provided with an input unit 610 for allowing a user to operate on the input side of the control unit 600 and communicates with the heat exchanger control unit 250, the indoor unit control unit 350, and the hood control unit 150. In connection with the overall control of the ventilation system 1.

The controller 600 controls the rotation of the indoor blower fan motor 332 according to the result of comparing the outside temperature with the reference value. In other words, if the outside temperature is less than the reference value, the rotational speed of the indoor blowing fan motor 332 is adjusted according to the outside temperature. Here, the outside temperature and the rotational speed of the indoor blower fan motor are proportional.

In addition, the control unit 600 causes the indoor blower fan motor 332 to rotate when the hood 100 is in operation, closes the electric expansion valve 331 of the indoor unit 300, and exhausts the heat exchanger 200. Allow the fan motor 231 to stop.

Hereinafter will be described with reference to the control method of the ventilation system according to the present invention.

Referring to FIG. 3, first, when a user applies power to the control unit 600 through the input unit 610 (701), the control unit 600 determines whether the ventilation condition (702). Here, the ventilation condition may be a case where the user inputs a ventilation operation command through the input unit 610.

At this time, if the ventilation condition is not, the control unit 600 waits for operation (703), and determines whether the operation termination condition (704). If the operation is not the end condition, the control unit 600 returns to step 702 described above, and performs the subsequent steps. If the operation is terminated, the power is turned off (705) and ends.

If the condition is a ventilation condition in step 702, the control unit 600 supplies a control signal for operating the heat exchanger 200 to the heat exchanger control unit 250. Accordingly, the total heat exchanger controller 250 controls the rotation speed of the exhaust fan motor 231 and the air supply fan motor 241 according to the pollution degree of the indoor air. In other words, if the indoor air contains a large amount of carbon dioxide and the pollution degree input from the pollution sensor 252 is high, the heat exchanger controller 250 supplies a control signal to the air supply fan motor driver 253 and the exhaust fan motor driver 254. The rotational speed of the air supply fan motor 241 and the exhaust fan motor 231 is increased. On the contrary, when the indoor air is low in carbon dioxide and the pollution degree input from the pollution sensor 252 is low, the total heat exchanger controller 250 supplies a control signal to the air supply fan motor driver 253 and the exhaust fan motor driver 254. The rotation speed of the air supply fan motor 241 and the exhaust fan motor 231 is reduced (706).

Next, the controller 600 determines whether the hood 100 is operating (707). In other words, it is determined whether the hood 100 is operating by receiving information on whether the hood 100 is driven from the hood controller 150.

At this time, if the state of the hood 100 is not in operation, the control unit 600 supplies a signal to the heat exchanger control unit 250 for the heat exchanger control unit 250 to transmit outside temperature information. Accordingly, the total heat exchanger controller 250 receives a signal according to the outside temperature from the outside temperature sensor 251, calculates the outside temperature using the input signal, and transmits the calculated outside air temperature to the controller 600. (708).

Next, the control unit 600 determines whether the outside air temperature transmitted from the total heat exchanger control unit 250 is greater than the reference value (709). Here, the reference value may be selected by experiment at a temperature such that the user does not experience a cold draft when the outside air is directly introduced into the room.

At this time, if the outside air temperature is greater than the reference value, the control unit 600 supplies a signal for the indoor blowing fan motor 332 to be stopped to the indoor unit control unit 350. Accordingly, the indoor unit controller 350 supplies a control signal to the indoor blower fan motor driver 352, and the indoor blower fan motor driver 352 causes the indoor blower fan motor 332 to stop, thereby causing the indoor blower fan motor ( 332 is stopped (711).

If the outside air temperature is lower than the reference value, the controller 600 provides a signal to the indoor unit controller 350 to control the air volume of the indoor unit according to the outside air temperature. Accordingly, the indoor unit controller 350 provides the indoor blowing fan motor driver 352 so that the rotational speed of the indoor blowing fan motor 332 is adjusted according to the outside air temperature. Accordingly, the indoor blower fan motor 332 is controlled to rotate in proportion to the outside air temperature (710). Here, in order to sufficiently mix with the indoor air as the outside air temperature is low, the outside air temperature and the rotational speed of the indoor blowing fan motor 332 are in proportion to each other.

Next, the controller 600 determines whether the set time has elapsed so that the steps 710 and 711 are performed during the set time (712). At this time, if the set time has not elapsed, it is determined whether the set time has elapsed. Here, if the ventilation end condition is not the above step 706 and subsequent steps are performed, and if the ventilation end condition is performed step 704 and subsequent steps described above.

If the hood 100 is in operation at step 707, the control unit 600 supplies a signal to the indoor control unit 350 to rotate the indoor blower fan 320 and to close the electric expansion valve 331. do. Accordingly, the indoor unit controller 350 supplies a control signal to the indoor blower fan motor driver 352 so that the indoor blower fan motor driver 352 drives the indoor blower fan motor 332, and the electric expansion valve 331. To close operation (714). At the same time, the control unit 600 supplies a signal to the heat exchanger control unit 250 so that the air supply fan motor 241 is rotated and the exhaust fan motor 231 is stopped. Accordingly, the total heat exchanger controller 250 supplies control signals to the air supply fan motor driver 253 and the exhaust fan motor driver 254 so that the air supply fan motor driver 253 rotates the air supply fan motor 715 and exhausts the air. The fan motor driver 254 stops the exhaust fan motor 231.

Next, the controller 600 determines whether the set time has elapsed so that the steps 714 and 715 are performed during the set time (716). At this time, if the set time has not elapsed, it is determined whether the set time has elapsed. If the set time has elapsed, step 713 and subsequent steps are performed.

1 is a schematic view showing a ventilation system according to the present invention.

2 is a block diagram showing a control system of the ventilation system according to the present invention.

3 is a flowchart illustrating a control procedure of the ventilation system according to the present invention.

<Description of the symbols for the main parts of the drawings>

100: hood 200: heat exchanger

251: outside temperature sensor 300: indoor unit

311: indoor unit intake 600: ventilation system control unit

Claims (9)

An input unit configured to receive a ventilation operation command; An indoor air circulation path through which indoor air is circulated, and an indoor blowing fan circulating the indoor air is installed, and when the ventilation operation command is input through the input unit, the indoor air fan is circulated through the indoor air circulation path. Indoor unit for rotating the; The air supply duct connected to an air supply outlet for discharging the outdoor air into a room, and a branch air supply duct branched from the air supply duct and connected to the indoor unit, and the outside air in the air supply duct through the branch air supply duct being one side of an inlet of the indoor unit And a total heat exchanger configured to discharge the upstream side of the indoor air circulation passage so that the outside air is mixed with the indoor air flowing through the indoor air circulation passage to be discharged into the room. delete An indoor unit including an intake port through which indoor air is introduced and an indoor blowing fan to circulate air; An electric heat exchanger having an air supply fan provided in an air supply flow path through which outside air flows, and an exhaust fan installed in an exhaust flow path through which the indoor air is exhausted, and providing the external air to the intake port; An outside air temperature sensor for sensing the outside air temperature; And a control unit controlling the rotational speed of the air supply fan and the exhaust fan according to the pollution degree, and controlling the rotation of the indoor blower fan according to a result of comparing the outside air temperature with a reference value. The method of claim 3, wherein The control unit is a ventilation system for adjusting the rotational speed of the indoor blower fan motor according to the outside temperature if the outside temperature is less than the reference value. 5. The method of claim 4, And the outside air temperature and the rotational speed of the indoor blower fan motor are proportional to each other. The method of claim 3, wherein Further comprising a hood for exhausting the polluted air of the kitchen, The control unit causes the indoor blowing fan motor to rotate when the hood is in operation, and causes the electric expansion valve of the indoor unit to close and operate, and the exhaust fan motor of the heat exchanger to stop. An indoor unit in which an indoor circulation passage for circulating indoor air is formed; In the control method of the ventilation system comprising a total heat exchanger for providing the inlet air to the suction port side of the indoor unit so that the inlet air is mixed with the indoor air flowing through the indoor circulation flow path and discharged to the room. When the ventilation operation command is input through the input unit detects the pollution degree and the outside temperature of the indoor air; Controlling the rotational speeds of the air supply fan and the exhaust fan provided in the heat exchanger in response to the pollution degree; Comparing the sensed outside temperature with a reference value; Control method of the ventilation system for controlling the rotation of the indoor blower fan motor of the indoor unit according to the comparison result. The method of claim 7, wherein If the detected outside temperature is greater than the reference value, the control method of the ventilation system to stop the rotation of the indoor blowing fan motor of the indoor unit. A hood for discharging polluted air in the kitchen, an indoor unit having an indoor air circulation passage through which indoor air is circulated, and an outdoor air introduced therein are mixed with indoor air flowing through the indoor air circulation passage to discharge the indoor air. In the control method of the ventilation system comprising a total heat exchanger provided on the suction port side of the indoor unit, When the hood is in operation, the indoor blower fan motor is rotated to circulate the indoor air in the indoor air circulation passage, the electric expansion valve of the indoor unit is closed and operated, and the air supply fan motor of the heat exchanger is rotated, Control method of the ventilation system to stop the exhaust fan motor of the total heat exchanger.

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