KR20090002491U - Ventilation System - Google Patents

Abstract

The present invention relates to a ventilation system, the present invention is a hood for exhausting the polluted air of the kitchen, the heat exchanger for ventilating the indoor air by adjusting the amount of air to be supplied to the interior and the amount of air discharged to the outdoors according to the operation of the hood It includes.

Hood, Heat Exchanger, Ventilation

Description

Ventilation System

The present invention relates to a ventilation system having a heat exchanger, and more particularly to a ventilation system that can adjust the amount of air supplied from the heat exchanger to compensate for the insufficient indoor air by the operation of the kitchen hood.

In general, a ventilation system is a system for introducing fresh outdoor air into a room using a blowing fan and exhausting indoor polluted air to the outside to freshen the indoor air.

In order to remove the steam generated from cooking and the smell of cooked food, components of the ventilation system may recover cold or heat from the hood installed in the kitchen and the indoor air exhausted to the outside, and provide the outside air supplied to the room. There is a total heat exchanger.

Such a conventional ventilation system allows the indoor air to flow into the room without recovering sufficient heat from the total heat exchanger while the outdoor air flows into the room when the outside 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, such a conventional ventilation system has a problem that the sound pressure of the indoor air is the same as the amount of air supplied and exhausted from the heat exchanger even when the hood of the kitchen is operated and the indoor air is insufficient.

In addition, since the outside air temperature compensation heater that requires a high power consumption in winter or cold conditions when the outside air temperature is significantly low, there is a problem that requires a lot of power consumption for the operation of the ventilation system.

The present invention is to solve the above problems, an object of the present invention is to provide a ventilation system to compensate for the insufficient indoor air by the operation of the kitchen hood by adjusting the amount of air supplied from the heat exchanger.

Another object of the present invention is to provide a ventilation system that prevents cold drafts occurring in winter when the outdoor air temperature is significantly low without using a heater for air temperature compensation.

The present invention for achieving the above object includes a hood for exhausting the polluted air of the kitchen, the heat exchanger for ventilating the indoor air by adjusting the amount of air supplied to the interior and the amount of air discharged to the outdoors according to the operation of the hood. do.

The apparatus may further include a branch duct branched from the outdoor air duct connected to the air supply inlet of the heat exchanger and connected to the ceiling in the room, and a damper connected to the branch duct to allow indoor air to flow into or be blocked by the branch duct.

In addition, the heat exchanger opens the damper when the outdoor temperature is lower than the preset temperature.

In addition, the electrothermal heat exchanger makes the amount of air supplied to the room more than the amount of air discharged to the outside during operation of the hood.

In addition, the electrothermal heat exchanger equalizes the amount of air supplied to the room with the amount of air discharged to the outside when the hood is not operated.

As described in detail above, the present invention is to control the air supply and exhaust air volume of the heat exchanger to prevent the negative pressure of the indoor air caused by the operation of the hood of the kitchen, cold draft (winter) without the use of a separate heater (Cold) It is effective in reducing energy consumed by preventing drafts.

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

1 to 3, the ventilation system according to an embodiment of the present invention is a hood 100 for exhausting the polluted air of the kitchen, a heat exchanger 200 for ventilating the indoor air, a heat exchanger 200 The outdoor air intake duct 400 which connects the outdoor air intake port of the outdoor air and the outdoor air inlet), the damper 300 installed on the ceiling of the indoor space, branched from the outdoor air duct 400, and connects the damper 300 The branch duct 500 allows the indoor air to flow to the air supply inlet 211 of the total heat exchanger 200 by opening the damper 300.

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 heat exchanger 200 to provide information on 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 outside or the exhaust duct. As a result, the kitchen has a contaminated air is exhausted out of the kitchen is a pleasant state.

The damper 300 includes a blade 390 formed inside the damper main body having an opening and closing function, a damper motor 360 for opening and closing the blade 390, and a damper motor driver 330 for driving the damper motor 360. It is.

The damper motor driver 330 is communicatively connected to the total heat exchanger 200, and drives the damper motor 360 under the control of the total heat exchanger 200 to open and close the blade 390.

The total heat exchanger (200) 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 connected to the outdoor air supply duct 400 connected to the outdoor, the branch duct 410 branched from the outdoor air supply duct 400 is connected to the damper 300, the interior of the damper 300 by the open Air flows to the air supply inlet 211 of the total heat exchanger (200).

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.

On the other hand, when the air supply fan 240 is rotated by the air supply fan motor 241 in the state in which the damper 300 is opened, outdoor air is sucked through the outdoor air supply duct 400, and indoor air is branched duct 500 Through the room). The indoor and outdoor air sucked in this way passes through the air supply inlet 211 and the air supply passage 270 sequentially, and is then supplied into the room through the air supply outlet 212.

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.

On the other hand, when the exhaust fan 230 is rotated by the exhaust fan motor 231, the contaminated air in the room passes through the exhaust inlet 213 and the exhaust passage 280 sequentially and then through the exhaust outlet 214. Exhaust to the outdoors.

The exhaust fan 230 and the air supply fan 240 are rotated by the driving speed of each of the connected motors 231 and 241, and contaminated indoors exhausted to the outside by the exhaust fan 230 by the changed rotation speed. There is a change in the air supply amount of the air and the air supply amount of outdoor air supplied to the room by the air supply fan 240.

On the output side of the total heat exchanger controller 250, an air supply fan motor driver 253 for driving the air supply fan motor 241 and an exhaust fan motor driver 254 for driving the exhaust fan motor 231 are provided. The total heat exchanger controller 250 controls the air supply fan motor driver 253 to control the driving speed of the air supply fan motor 241 and the exhaust fan motor driver 254 to control the driving speed of the exhaust fan motor 231 to supply air. The rotation speed of the fan 240 and the exhaust fan 280 is adjusted.

The total heat exchanger controller 250 is communicatively connected to the hood controller 150 to receive the operation of the hood controller 150. Two operation modes are set in the heat exchanger controller 250, and an operation mode is determined according to whether the hood controller 150 is operated. The two types of operation modes are the normal operation mode and the negative pressure operation mode. In the normal operation mode, the exhaust fan 230 and the air supply fan 240 are rotated at the same speed so that the air flow rate and the air flow rate are the same. In addition, the negative pressure operation mode is to compensate for the shortage of the indoor air generated by the operation of the hood 100 to make the outdoor air to the interior by making the rotation speed of the air supply fan 240 faster than the rotation speed of the exhaust fan 230. The amount of air supplied is larger than the amount of indoor air exhausted to the outside to compensate for the shortage of indoor air.

The heat exchanger input unit 290 receives an operation command of the heat exchanger 200 from the user and transmits it to the heat exchanger control unit 250. The heat exchanger controller 250 determines whether ventilation of the indoor air is necessary by using a signal input from the pollution sensor 252 when an operation command is input, and if it is necessary to ventilate the indoor air, the heat exchanger controller 250 transmits the The operation mode of the total heat exchanger is selected according to the operation of 100 to ventilate the indoor air. At this time, if the hood 100 is in operation, the heat exchanger controller 250 selects the negative pressure operation mode to compensate for the shortage of indoor air, and if the hood 100 is not in operation, the heat exchanger controller 250 is in the normal operation mode. To ventilate the room air.

On the other hand, the total heat exchanger controller 250 analyzes the outside temperature transmitted from the outside temperature sensor 251 when the normal or negative pressure operation mode is performed in the heat exchanger 200, and the measured outside temperature is lower than a predetermined temperature (for example, For example, in winter or cold conditions where the outdoor temperature is significantly lower, the damper motor driver 330 is controlled to prevent the air that is significantly colder than the indoor air, such as a cold draft, flowing into the room and causing discomfort to the user. 360 to open the damper 300. When the damper 300 is opened, indoor air flows to the branch duct 500 through the damper 300, and the indoor air flowing to the branch duct 500 is supplied with an air supply fan together with the outdoor air flowing from the outdoor air duct 400. By the rotation of the 240 is supplied to the interior through the air supply inlet 211, the air supply passage 270 and the air supply outlet 2120 of the heat exchanger (200).

Hereinafter, a brief description of a control method of a ventilation system according to an embodiment of the present invention.

When the user inputs an operation command through the total heat exchanger input unit 290, the total heat exchanger control unit 250 analyzes the signal input from the pollution sensor 252 to analyze the indoor pollution level.

When the indoor pollution degree exceeds the set value, the heat exchanger controller 250 determines that the ventilation of the indoor air is necessary, and the hood controller 150 determines the operation mode of any one of the two types of operation modes. Receiving the operation of the hood 100 is input through.

If the hood 100 is in operation, the heat exchanger controller 250 exhausts the rotational speed of the air supply fan 240 in order to prevent the pressure of the indoors caused by the indoor air being exhausted to the outside by the operation of the hood 100. At a speed higher than the rotational speed of 230, the air supply to the indoor air is made larger than that of the indoor air to be exhausted to the outside, thereby performing a negative pressure operation mode to compensate for the insufficient indoor air.

At this time, if the temperature of the outdoor air is significantly lower than the temperature of the indoor air, a cold draft phenomenon occurs, causing inconvenience to the user. Therefore, the total heat exchanger control unit 250 analyzes the outdoor temperature transmitted from the outdoor air temperature sensor 251, and if the outdoor temperature is lower than the set temperature, the damper 300 is opened to warm indoor air. Mixed with and flows to the air supply inlet 211 of the total heat exchanger.

The air mixed with indoor air and outdoor air is supplied into the room through the air supply passage 270 of the total heat exchanger.

On the other hand, if the hood 100 is not in operation, the heat exchanger controller 250 rotates the air supply fan 240 and the exhaust fan 230 at the same speed so that the amount of air supplied and exhausted is the same. In this case, the total heat exchanger controller 250 controls the opening and closing of the damper 300 by comparing whether the temperature of the outdoor air is lower than the set temperature.

1 is a schematic structural diagram of a ventilation system according to an embodiment of the present invention.

2 is a structural diagram showing in detail the structural diagram briefly shown in FIG.

3 is a control block diagram of a ventilation system according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

100: hood 150: hood control unit

200: total heat exchanger 250: total heat exchanger control unit

251: outside temperature sensor 252: pollution sensor

300: damper 330: damper motor drive unit

Claims (5)

A hood to exhaust contaminated air from the kitchen; Ventilation system including a total heat exchanger for ventilating the indoor air by adjusting the amount of air supplied to the room and the amount of air discharged to the outside according to whether the hood is operating. The method of claim 1, A branch duct branched from the outdoor air supply duct connected to the air supply inlet of the heat exchanger and connected to the ceiling of the room; And a damper connected to the branch duct to allow indoor air to flow or to be blocked by the branch duct. The method of claim 2, The heat exchanger is a ventilation system for opening the damper when the outdoor temperature is lower than the preset temperature. The method of claim 1, The electrothermal heat exchanger when the hood is operated, Ventilation system that makes the amount of air supplied to the room more than the amount of air discharged to the outside. The method of claim 1, The electrothermal heat exchanger when the hood is not running, Ventilation system that equals the amount of air supplied indoors and the amount of air released outdoor.

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