KR101758269B1 - A control method of a ventilating device - Google Patents

Abstract

The present invention relates to a control method of a ventilator, and more particularly, to a ventilator control method of ventilating a ventilator which is installed in an indoor space to perform ventilation of each indoor space, And a control method of the apparatus.

Description

[0001] The present invention relates to a control method of a ventilating device,

The present invention relates to a control method of a ventilator, and more particularly, to a ventilator control method of ventilating a ventilator which is installed in an indoor space to perform ventilation of each indoor space, And a control method of the apparatus.

Electric power for operating electrical appliances such as household appliances used at home or office equipment used in offices is generally supplied through a power plant operated by KEPCO, a transmission line, and a wiring line in this order Feature.

It is a central power source rather than a distributed power source. It has a radial structure spreading from the center to the periphery, and is characterized by a one-way supplier center rather than a consumer center.

In addition, the technology base is analog or electro-mechanical, has to be manually restored in case of an accident, and the equipment must also be manually restored.

The price information of electricity can not be known in real time, but it can be seen only through the power exchange, and because the price system is also a fixed price system, incentives such as incentives for consumers through price changes can not be used There was also a problem.

In order to solve these problems and improve energy efficiency, researches on smart grids (smart grids) are actively underway.

Smart grid refers to the next generation power system and its management system implemented through the fusion and combination of modernized power technology and information and communication technology.

As mentioned above, while the current grid is a centralized, producer-controlled vertical, centralized network, the Smart Grid is less focused on suppliers and has horizontal, collaborative It is a distributed, distributed network.

In the smart grid, the Smart Grid is sometimes referred to as the "energy Internet," because all electrical equipment, power storage, and distributed power are networked to enable interaction between the consumer and the supplier.

In order for such a smart grid to be implemented in the position of a power user such as a home or a building, a network in which individual appliances and a plurality of household appliances are connected should be bi-directionally communicated with the power source and the power information And the need for new devices for such two-way communication.

The present invention relates to a control method of a ventilation apparatus which is installed in an indoor space and performs temperature control and ventilation of each indoor space, and which can save power charges by flexibly controlling power consumption according to the environment of the indoor space and the level of electric power charges The purpose is to provide.

In order to achieve the above object, the present invention provides a method comprising: recognizing electric power charge information; Determining whether a current power charge is greater than a predetermined criterion; Determining whether a cooling operation or a heating operation is performed by a separate air conditioner; And intermittently operating the air supply fan or the exhaust fan based on the difference between the room temperature and the outdoor temperature when the current electric power charge is equal to or higher than a predetermined standard and the cooling or heating operation is performed.

The air supply fan of the ventilator performs an intermittent operation to alternately perform operation and stop when the cooling operation is performed by the separate air conditioner and the indoor temperature is higher than the outdoor temperature, So as to be operated.

And the operation time of the air supply fan is shorter than the stop time.

Wherein the cooling fan is operated by the separate air conditioner and the air supply fan and the exhaust fan of the ventilator are stopped when the indoor temperature is lower than the outdoor temperature.

Wherein the exhaust fan of the ventilator performs an intermittent operation for alternately performing the operation and the stop when the indoor operation is performed by the separate air conditioner and the indoor temperature is lower than the outdoor temperature, So as to be operated.

And the operation time of the exhaust fan is shorter than the stop time.

Wherein the cooling fan is operated by the separate air conditioner and the air supply fan and the exhaust fan of the ventilator are stopped when the indoor temperature is lower than the outdoor temperature.

In addition, the present invention provides a method comprising: recognizing power charge information; And intermittently operating the air supply fan or the exhaust fan while operating the heat transfer unit when the current electric power charge is equal to or higher than a predetermined standard.

Further comprising the step of determining whether the room temperature is below a predetermined reference temperature,

The air supply fan of the ventilating apparatus performs the intermittent operation for alternately performing the operation and the stop, and the exhaust fan performs the continuous operation when the indoor temperature is the predetermined reference temperature or less.

When the indoor temperature is equal to or higher than a predetermined reference temperature, the exhaust fan of the ventilator performs intermittent operation for alternately performing operation and stop, and the air supply fan performs continuous operation.

Further comprising the step of determining whether the number of the ventilating apparatuses is plural, and when the number of the ventilating apparatuses is plural, the ventilating apparatuses are kept in the operating state and the other ventilating apparatuses are in the stopped state.

Further comprising the step of: determining whether a predetermined time has elapsed. When the predetermined time has elapsed, the ventilator in operation is stopped and the ventilator in stop is operated.

The operation time of the exhaust fan or the supply fan during intermittent operation is shorter than the stop time.

According to the present invention, the ventilation device can be flexibly adjusted in consideration of the room temperature condition and the electric power charge, and the electric power charge can be saved.

Since the control of the ventilation device is not performed manually but automatically, it is possible to increase the convenience of the user in the power saving operation.

Specifically, when the indoor air temperature is higher than the outdoor air temperature in the cooling mode of the air conditioner, the indoor air can be quickly lowered to a desired temperature by discharging outdoor air and discharging indoor air.

On the other hand, when the indoor air temperature is lower than the outdoor air temperature in the heating mode of the air conditioner, outdoor air is supplied and room air can be discharged to rapidly increase the room temperature.

The operation of the ventilation device can be controlled so as to reduce the electric power charge while performing the temperature control.

On the other hand, in the case where a plurality of ventilating devices are mounted on a building, not all of the plurality of ventilating devices are operated in the on-peak time period, but only a part of the ventilating devices are operated and some of them are stopped.

In addition, there is an advantage that ventilation can be evenly performed in each indoor space by alternately generating the stop state and the operation state.

Figure 1 is a schematic diagram of a smart grid.
2 is a schematic view showing that the ventilator of the present invention is installed together with an air conditioner in an indoor space.
FIG. 3 is a control block diagram when the ventilator and the air conditioner of the present invention are installed together in an indoor space.
4 is a schematic view showing that the ventilator of the present invention is installed in an indoor space.
5 is a control block diagram of the ventilator of the present invention in an indoor space.
6 is a schematic view showing the operation of the ventilator when the room temperature is higher than the outdoor temperature in the cooling mode.
7 is a schematic view showing the operation of the ventilator when the indoor temperature is lower than the outdoor temperature in the heating mode.
8 is a schematic view showing the operation of the ventilator when the indoor temperature is lower than the outdoor temperature in the cooling mode or the indoor temperature is higher than the outdoor temperature in the heating mode.
9 is a schematic view showing the operation of the ventilator when the room temperature is lower than the reference temperature.
10 is a schematic view showing the operation of the ventilator when the room temperature is higher than the reference temperature.
11 is a control flowchart when the ventilator and the air conditioner are installed together.
12 and 13 are control flow charts when the ventilator is installed.
14 is a schematic view of a ventilator composed of an enthalpy heat exchanger and a ventilator cleaner.
FIG. 15 is a schematic view of a ventilator composed of an enthalpy heat exchanger, a ventilator cleaner, and a distributor.
Fig. 16 is a schematic view of a ventilator composed of an enthalpy heat exchanger, a ventilation cleaner, and a humidifier.
17 is a graph showing a change in electric power charge with time.

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

FIG. 1 is a schematic diagram of a smart grid. The smart grid includes a power plant generating electricity through thermal power generation, nuclear power generation, or hydroelectric power generation, and a photovoltaic power generation plant and a wind power generation plant using solar power or wind power .

The thermal power plant, nuclear power plant or hydroelectric power plant transmits electric power to the electric power plant through a transmission line, and electric power is sent to the substation in the electric power plant so that electric power is distributed to the consumer such as the home or the office.

Electricity generated by renewable energy is also sent to the substation and distributed to each customer. Electricity transmitted from the substation is distributed through the electric power storage device to the office or each household.

Even in the home using a home network (HAN), it is possible to produce electricity by itself through the fuel cell mounted on sunlight or PHEV (Hybrid Electric Vehicle, Plug in Hybrid Electric Vehicle) The remaining electricity can be returned to the outside.

In addition, a smart meter is provided in an office or a home, so that it is possible to grasp real-time electric power and electricity charges used in each customer. Through this, the user can recognize the amount of electric power and electric charge currently used, Can be found.

In addition, since the power plant, power station, storage device, and consumer are two-way communication, it is necessary to notify the storage device, the power station and the power station of the situation of the demanding place separately from the one- Electric distribution can be performed.

Meanwhile, in the above-mentioned smart grid, an energy management system (EMS) and an Advanced Metering infrastructure (AMI), which measure real-time power consumption of demanders and real-time power consumption, It plays a pivotal role. Wherein the smart meter constitutes a part of the metrology infrastructure.

The measurement infrastructure under the Smart Grid is based on an open architecture and is an underlying technology for integrating consumers. It enables consumers to efficiently use electricity, and power suppliers are able to detect system problems and efficiently operate the system. to provide.

Here, open architecture is a standard that allows all electric devices to be connected to each other regardless of which manufacturer manufactures the electric devices in a smart grid system, unlike a general communication network.

Thus, the metrology infrastructure or smart meter used in the Smart Grid enables consumer-friendly efficiency concepts such as "Prices to Devices ".

That is, the real-time price signal of the electric power market is relayed through the energy management device (EMS) installed in each home and the smart meter, and the energy management device (EMS) and the smart meter communicate with each electric product, Energy and cost can be saved by recognizing the electric power information of each electric appliance by the EMS or the smart meter and performing the power information processing such as the setting of the consumed electric power or the electricity rate limit based on the electric power information.

The control of each electric appliance can be performed by communication between the energy management device (EMS) and the smart meter.

Here, the energy management apparatus (EMS) performs bidirectional communication with the local energy management apparatus (Local EMS) and the local energy management apparatus (EMS) used in the office or the home to collect information collected from the local energy management apparatus (Central EMS) that processes the energy.

Since the smart grid enables real-time communication of power information between the supplier and the consumer, it is possible to realize a "real-time power grid reaction ", thereby reducing the high cost required to meet the peak demand.

2 is a structural view of an air conditioner 10 and a ventilator 200 installed in a building connected to a smart grid.

 The air conditioner 10 is divided into an indoor unit 100 and an outdoor unit 400. The air conditioner 10 and the ventilator 200 are controlled to operate in conjunction with electric power charge information.

The air conditioner (10) and the ventilator (200) are provided with a smart meter (20) capable of receiving power information such as electric power charge information from the outside and measuring the electric power and the electric power used in the home in real time (EMS) 30 connected to the smart meter 20 for communicating with at least one indoor or ventilator and controlling their operation.

Here, the energy management device (EMS) 30 includes a display unit for displaying the current power consumption state and the external environment (temperature, humidity), and is provided in the form of a terminal having an input unit operable by the user desirable.

In particular, the energy management system (EMS) 30 includes an indoor unit 100 installed in a plurality of indoor spaces S1 through S4 through a network in a building, a ventilator 200, And is connected to the outdoor unit 400 to perform bidirectional communication with the outdoor unit 400 and to control them.

Communication inside the building can be done via wired lines such as wireless or PLC.

The indoor unit 100 and the ventilator 200 disposed in a specific indoor space may be connected to the indoor unit 100 and the ventilator 200 disposed in different indoor spaces so that communication is possible .

The power supply 50 of the building may be a system power supply 51 capable of supplying electric power by general power generation equipment (thermal power, nuclear power, hydro power), renewable energy 52 such as a solar power generation facility or a wind power generation facility ).

 And an auxiliary power source 53 such as a fuel cell provided in the building may be another power source.

Typically, the power source 50 is connected to the smart meter 20 and the energy management device (EMS) 30 to provide power information to the smart meter 20 and the energy management device (EMS) 30, As the basic information.

The indoor unit 100 serves to supply cold air to each indoor space through a heat exchange with the refrigerant, and to supply hot air during the heating operation.

The ventilator 200 exchanges air and outdoor air in each indoor space to ventilate the indoor space.

An air duct 300 connected to the ventilator 100 provided in the indoor spaces S1 to S4 is provided inside the building. The air duct 300 is connected to the first An air duct 310, and a second air duct 320 for guiding air in the room outdoors.

A supply duct 330 for guiding the air inside the first air duct 310 to the ventilator 200 is provided between the first air duct 310 and each ventilator 200.

At the inlet end of the first air duct 310, an inlet adjusting device 311 for selectively blocking the inflow of outdoor air is provided. In addition, the supply duct 330 is also provided with a supply adjusting device 331 for selectively controlling the communication with the first air duct 310.

An exhaust duct 340 is provided between the second air duct 320 and each ventilator 200 to guide the air discharged from the ventilator 200 to the second air duct 320.

An outlet adjusting device 321 is provided at the outlet end of the second air duct 320 to selectively block air outflow to the outside of the room.

In the ventilator 200, a total enthalpy heat exchanger 210, an air supply fan 220 and an exhaust fan 230, an intake valve 240 for selectively controlling the flow of air to be introduced, An exhaust valve 250 is provided to selectively regulate the flow.

When the air supply fan 220 operates, the air passing through the supply duct 330 flows into the ventilator 200, passes through the inside or outside of the total enthalpy heat exchanger 210, To the indoor spaces S1 to S4.

When the exhaust fan 230 operates, the air inside the indoor spaces S1 to S4 flows into the ventilator 200, passes through the inside or outside of the total enthalpy heat exchanger 220 And moves to the outdoor space through the exhaust fan 230. [

3 is a control block diagram showing a connection state between the air conditioner 10 and the power supply source 50 according to the present invention and the smart meter 20 and the energy management device (EMS) 30 .

As described above, the power supply source 50 includes the system power supply 51, the renewable energy 52, and the auxiliary power supply 53. Under the control of the energy management apparatus 30, And supplies power to the indoor unit 100, the ventilator 200, and the outdoor unit 400.

In the indoor unit 100, an indoor fan 120 for guiding the indoor heat exchanger 110 and the heat-exchanged air to the indoor space is provided. Here, it is preferable that the indoor fan 120 is capable of controlling the air flow rate by adjusting its rotational speed.

The ventilator 200 includes the total enthalpy heat exchanger 210, the air supply fan 220, the exhaust fan 230, the intake valve 240, and the exhaust valve 250, as described above .

The outdoor unit 400 includes an outdoor heat exchanger 410 for compressing refrigerant, an outdoor fan 420 for guiding air to the outdoor heat exchanger, and a compressor 430.

In the indoor unit (100), the rotational speed of the indoor fan (120) is adjusted according to the control of the power supply to adjust the air volume.

In the case of the ventilator 200, the air is introduced into each indoor space according to on / off and rotation speed control of the air supply fan 220 and the exhaust fan 230, The amount of air to be supplied is controlled.

In the case of the outdoor unit 400, the supply amount of the refrigerant in the compressor 430 is controlled according to the amount of electric power supplied, and the rotation speed of the outdoor fan 420 is controlled to adjust the condensation degree of the refrigerant in the outdoor heat exchanger 410 .

FIG. 4 is a structural view of a building in which only the ventilation device 200 is installed in each of the indoor spaces S1 to S4, and FIG. 5 is a control block diagram of such a building.

4 and 5 are the same as those of FIG. 2 and FIG. 3 except for the indoor unit 100 and the outdoor unit 200, so that a detailed description thereof will be omitted.

 6 shows the control operation of the ventilator 200 when the air conditioner 10 operates in the cooling mode and the indoor temperature is higher than the outdoor temperature.

The operation of the ventilator 200 is changed according to the on-peak time interval in which the electric power charge is equal to or greater than the predetermined reference value and the off-peak time interval in which the electric power charge is equal to or less than the predetermined reference value.

The air supply valve 240 and the exhaust valve 250 are opened in the ventilator 200 while the air conditioner 10 is operating in the cooling mode when the current time is in the off- The air supply fan 220 and the exhaust fan 230 provided in the ventilator 200 are turned on to perform the rotary operation to draw in the outside air and discharge the air in the indoor space to the outside.

However, in the case where the current time is included in the on-peak time period in which the electric power charge is equal to or higher than a predetermined reference, it is necessary to save electric power charges.

Accordingly, in this case, the outputs of the air supply fan 220 and the exhaust fan 230 are reduced to a minimum level. That is, when the outputs of the air supply fan 220 and the exhaust fan 230 are divided into strong wind, strong wind, and weak wind, it is necessary to control them to operate as a weak wind.

Also, the exhaust fan 230 is controlled to continuously operate, and in the case of the air supply fan 220, the intermittent operation, that is, the operation state (on) and the stop state (off) are alternately performed.

The reason why the exhaust fan 230 is continuously operated and the air supply fan 220 is intermittently operated is that the indoor air having a temperature higher than that of the outdoor air is continuously discharged to the outside, In order to reduce it.

By intermittently operating the air supply fan 220, it is possible to reduce the amount of electric power consumption compared with the case where the air supply fan 220 is continuously operated, which is also helpful in reducing the electric power charges.

Meanwhile, in order to maximize the effect of reducing the electric power charge, it is preferable that the operation time of the air supply fan 220 is shorter than the stop time within the on-peak time interval.

As shown in FIG. 7, the air conditioner 10 is driven in the heating mode. However, when the room temperature is lower than the outdoor temperature, it is necessary to introduce the outside air into the room.

When the current time is in the off-peak time period, the air supply valve 240 and the exhaust valve 250 are opened in the ventilator 200, the air supply fan 220 provided in the ventilator 200, The exhaust fan 230 is turned on to perform the rotating operation to draw in the outside air and to discharge the air in the indoor space to the outside.

However, in the case where the present time belongs to the on-peak time period in which the electric power charge becomes the predetermined reference or more, it is necessary to save electric power charges.

Accordingly, in this case, the outputs of the air supply fan 220 and the exhaust fan 230 are reduced to a minimum level.

That is, when the outputs of the air supply fan 220 and the exhaust fan 230 are divided into strong wind, strong wind, and weak wind, it is necessary to control them to operate as a weak wind.

In the case of the exhaust fan 230, the intermittent operation, that is, the operation state (on) and the stop state (off) are alternately performed, while the air supply fan 220 is controlled to continuously operate.

The reason why the air supply fan 220 is continuously operated and the exhaust fan 230 is intermittently operated is as follows. That is, the outdoor air having a temperature higher than the indoor air is continuously supplied to the indoor space, It is to raise.

By intermittently operating the exhaust fan 230, it is possible to reduce the amount of power consumption compared to the case where the exhaust fan 230 is continuously operated, which is also helpful in reducing the electric power charges.

Meanwhile, in order to maximize the effect of reducing electric power charges, it is preferable that the operation time of the exhaust fan 230 is shorter than the stop time within the on-peak time period.

In FIGS. 6 and 7, the cooling mode and the heating mode are performed for all the indoor spaces. However, the cooling mode may be performed in some indoor spaces and the heating mode may be performed in some indoor spaces.

At this time, the ventilator can be independently driven in consideration of each mode and temperature condition. That is, the operation of the ventilator shown in Figs. 6 and 7 may occur at the same time.

That is, in some indoor spaces operated in the cooling mode, the air supply fan performs intermittent operation and the exhaust fan continuously operates, while in the other indoor space operated in the heating mode, the air supply fan continuously operates and the exhaust fan operates intermittently can do.

FIG. 8 shows a state in which the indoor temperature is higher than the outdoor temperature when the outdoor temperature is low or when the air conditioner operates in the heating mode when the air conditioner operates in the cooling mode.

Since the purpose of the cooling mode itself is to make the room temperature lower than the outdoor temperature, it is necessary to suppress the rise of the room air temperature due to the large inflow of the outdoor air.

Accordingly, the operation of the air supply fan 220 and the exhaust fan 230 is turned off, thereby preventing the outdoor air from flowing into the indoor space in a large amount and the indoor air from flowing out to the outdoor space.

It is preferable that the air supply valve 220 and the exhaust fan 230 are in a closed state when natural ventilation is not necessary. It is preferable that the air supply valve 240 and the exhaust valve 250 are opened.

Fig. 9 shows the flow of air in a state where only a ventilator is disposed in a building.

First, it is determined whether the current time belongs to the on-peak time period. If the current off-peak time period is present, the current operation mode is maintained.

However, if the indoor temperature is lower than the predetermined reference temperature, it is determined that the outdoor air belongs to the off-peak time period. In this case, the outdoor air is introduced into the indoor space and the indoor air is discharged to the outdoor space.

Here, the reference temperature may be an outdoor temperature, or may be a predetermined temperature.

In this case, if there is only one ventilator to be controlled, the exhaust fan 230 performs the continuous operation in order to positively discharge the room air, and the air supply fan 220 performs the intermittent operation.

That is, the air supply fan 220 alternately operates and stops during the on-peak time period. It is preferable that the stopping time is longer than the operation time for power saving.

However, if there are a plurality of ventilators to be controlled and are arranged in a plurality of indoor spaces (S1 to S4), the ventilator arranged in a certain indoor space is in the operating state, and the ventilator arranged in the other indoor space is in the stopped state .

The air supply fan 220 and the exhaust fan 230 stop rotating. When natural ventilation is required, the air supply valve 240 and the exhaust valve 250 are opened, but they are closed when not required.

At this time, as described above, the air supply fan 220 performs the intermittent operation and the exhaust fan 230 performs the continuous operation.

Then, when a predetermined time elapses, the ventilator in operation is stopped, and the ventilator, which has been stopped, is in the operating state.

As described above, the air supply fan 220 performs the intermittent operation and the exhaust fan 230 performs the continuous operation.

9, the ventilation operation is first performed on the indoor spaces S1 and S3, and when the predetermined time has elapsed, the ventilation operation to S1 and S3 is stopped and the ventilation operation is performed on the indoor spaces S2 and S4 will be.

FIG. 10 also shows the flow of air in a state where only a ventilation device is disposed in a building, and the temperature condition is different from that of FIG. 9 only.

Even in this state, first, it is determined whether the current time belongs to the on-peak time period, and if it is the current off-peak time period, the current operation mode is maintained.

It is determined that the current time belongs to the on-peak time period. In this case, when the room temperature is higher than the predetermined reference temperature, outdoor air is introduced into the indoor space to lower the room temperature and indoor air is discharged to the outside.

Here, the reference temperature may be a set specific temperature or an outdoor temperature.

In this case, if there is only one ventilator to be controlled, the air supply fan 220 performs continuous operation and the exhaust fan 230 performs intermittent operation in order to positively discharge indoor air.

That is, the exhaust fan 230 alternately operates and stops during the on-peak time period. It is preferable that the stopping time is longer than the operation time for power saving.

However, if there are a plurality of ventilators to be controlled and are arranged in a plurality of indoor spaces (S1 to S4), the ventilator arranged in a certain indoor space is in the operating state, and the ventilator arranged in the other indoor space is in the stopped state .

The air supply fan 220 and the exhaust fan 230 stop rotating. When natural ventilation is required, the air supply valve 240 and the exhaust valve 250 are opened, but they are closed when not required.

At this time, as described above, the exhaust fan 230 performs the intermittent operation, and the air supply fan 220 performs the continuous operation.

Then, when a predetermined time elapses, the ventilator in operation is stopped, and the ventilator, which has been stopped, is in the operating state.

As described above, the air supply fan 220 performs continuous operation and the exhaust fan 230 performs intermittent operation.

That is, in FIG. 10, the ventilation operation is performed for the indoor spaces S1 and S3 at first, and when the predetermined time has elapsed, the ventilation operation for S1 and S3 is stopped and the ventilation operation is performed for the indoor spaces S2 and S4 will be.

11 is a control flowchart when an air conditioner and a ventilator are simultaneously installed in a building.

First, when the air conditioner and the ventilator operate (S1101), it is determined whether the current on-peak time period is present (S1102). That is, whether the current power charge is equal to or greater than a predetermined criterion.

If it is determined that the current time is the on-peak time period, it is determined whether the current air conditioner is set to the cooling mode (S1102).

If it is determined as the off peak time period, the current operation mode is maintained (S1103). If it is determined that the on-peak time period is the on-peak time period, it is determined whether the air conditioner is set to the cooling mode (S1104).

When the air conditioner is set to the cooling mode, it is determined whether or not the room temperature is higher than the outdoor temperature. If the indoor temperature is higher than the outdoor temperature, the cool air is introduced into the room, In order to save power, the air supply fan is intermittently operated and the exhaust fan is continuously operated (S1106).

However, if the room temperature is lower than the outdoor temperature, the air supply fan and the exhaust fan are stopped (S1107) because no active ventilation is required.

On the other hand, if it is determined in step S1104 that the air conditioner is not set to the heating mode, it is recognized as a heating mode (S1108).

In this heating mode, it is determined whether the room temperature is lower than the outdoor temperature (S1109). As a result of the judgment, when the room temperature is lower than the outdoor temperature, it is necessary to introduce outdoor air having a high temperature and to discharge indoor air having a low temperature.

However, in order to save power, the ventilator continuously operates the air supply fan and intermittently operates the exhaust fan (S1110).

However, if the room temperature is higher than the outdoor temperature, active ventilation is unnecessary, so that the air supply fan and the exhaust fan in the ventilator are stopped (S1111).

12 and 13 are control flow charts when only a ventilation system is installed in a building.

First, when the ventilator is operated (S1201), it is determined whether the current time belongs to the on-peak time period (S1202). That is, it is determined whether the current electric power charge is equal to or higher than a predetermined criterion.

If it is determined that the current time belongs to the off-peak time period, the current operation mode is maintained (S1203).

However, if the current time falls within the on-peak time period, it is determined whether the room temperature is lower than the reference temperature (S1204). As described above, the reference temperature may be a predetermined temperature value or an outdoor temperature.

If it is determined that the current room temperature is lower than the reference temperature, it is determined whether there are two or more units to be controlled (S1205).

If there is only one ventilator to be controlled, the air supply fan of the ventilator is intermittently operated and the exhaust fan is continuously operated (S1206).

However, if there are two or more ventilators to be controlled, some of the ventilating apparatuses are in the operating state and the remaining ventilating apparatuses are in the stopped state (S1207).

At this time, in the operating ventilator, the supply fan performs intermittent operation and the exhaust fan performs continuous operation (S1208).

In this case, it is determined whether a predetermined time has elapsed (S1209). If the predetermined time has elapsed, the ventilator in operation is stopped and the ventilator is stopped (S1210).

This is because the ventilation is alternately performed in each indoor space, so that the power consumption can be reduced and the ventilation can be uniformly performed in each indoor space.

In this state, it is determined whether a stop command has been input to each ventilator (S1211). If the stop command is input, the ventilator to be the command is stopped (S1212). If there is no clear stop command, The fan is operated intermittently, and the exhaust fan is continuously operated.

On the other hand, if it is determined in step S1204 that the room temperature is higher than the reference temperature (S1301), it is determined whether there are two or more control target ventilators (S1302), as shown in FIG.

If there is only one ventilator to be controlled, the exhaust fan of the ventilator is intermittently operated and the air supply fan is continuously operated (S1303).

However, if there are two or more ventilators to be controlled, some of the ventilating apparatuses are in the operating state and the remaining ventilating apparatuses are in the stopped state (S1304).

At this time, in the operating ventilator, the exhaust fan performs intermittent operation and the air supply fan performs continuous operation (S1305).

In this case, it is determined whether a predetermined time has elapsed (S1306). If the predetermined time has elapsed, the ventilator in operation is stopped and the ventilator is stopped (S1307).

This is because the ventilation is alternately performed in each indoor space, so that the power consumption can be reduced and the ventilation can be uniformly performed in each indoor space.

In this state, it is determined whether a stop command has been input to each ventilator (S1308). When the stop command is input, the ventilator to be commanded is stopped (S1309). If there is no clear stop command, Intermittent operation of the fan and continuous operation of the air supply fan.

In the above-described control method, when the air supply fan or the exhaust fan is intermittently operated, it is preferable that the time of the stop state is shorter than the time of the operation state.

FIG. 14 shows another embodiment of the ventilator according to the present invention. In the ventilator shown in FIG. 14, a plurality of ventilator cleaners 600 are connected to one total heat-exchanging apparatus 500, And is preferably disposed in each indoor space

The total enthalpy heat exchanger 500 and the ventilator cleaner 600 are connected by an air duct 510 or by a branched duct 520 branching from the air duct 500.

(Not shown) for supplying outside air, an exhaust fan (not shown) for discharging the air in the indoor space to the outside, a room air cleaner And an total heat exchanger (not shown) for exchanging heat with air.

The ventilation cleaner 600 includes a discharge port (not shown) for discharging air outside the room, a suction port (not shown) for sucking indoor air, (Not shown) for discharging the refrigerant to the total heat-exchanging device 500 is provided.

Here, the blower fan may be constituted by one fan for both intake and exhaust, or may be divided into an air supply fan or an exhaust fan.

In addition, a filter member (not shown) is provided in the ventilation cleaner 600 to remove foreign substances or odors contained in the outdoor air discharged into the indoor space.

Here, the ventilation cleaner 600 may be operated in a ventilation mode and an air cleaning mode.

That is, when operating in the air cleaning mode, air is not exchanged between the ventilation cleaner 600 and the total heat-exchanging device 500, and the indoor air is filtered by the air circulation function of the ventilation cleaner 600 do.

That is, the indoor air can be sucked into the air cleaning mode through the indoor air sucking operation by the air blowing fan, the filtering of the sucked air, and the discharge of the filtered air.

Meanwhile, in the ventilation mode, the indoor air sucked by the ventilator cleaner 600 is moved to the total heat-exchanging device 500 by air exchange between the ventilator cleaner 600 and the total heat-exchanging device 500, The outdoor air sucked in the total enthalpy heat exchanger 500 moves to the ventilator cleaner 600.

When the ventilation mode is performed, it is preferable that the above-described air cleaning mode is also performed simultaneously.

That is, when air exchange is not performed between the ventilation cleaner 600 and the total heat-exchanging device 500, only the air cleaning mode is performed, and when the air exchange is performed, the air cleaning mode and the ventilation mode are performed at the same time.

The air duct 510 for exchanging air includes a first air duct 511 for guiding outdoor air from the total heat-exchanging apparatus 500 toward the ventilator cleaner 600, And a second air duct 512 for guiding indoor air toward the total heat-exchanging device 500.

The branch duct 520 includes a first branch duct 521 connected to the first air duct 511 and guiding outdoor air toward a ventilation cleaner of a plurality of the ventilator cleaners 600, And a second branch duct 522 for guiding air in the room sucked in the purifier 600 toward the second air duct 512.

The power source 50 supplies power to the system power supply 51, the renewable energy 52 and the auxiliary power supply 53. The power supply 50 supplies power to the smart meter 20 and the energy management device 30. [

The power of the electric power supply source 50 is supplied to the total heat-exchanging apparatus 500 and the ventilator cleaner 600. The power consumed by the total heat-exchanging apparatus 500 and the ventilator cleaner 600 is supplied to the smart meter 20 ) Or in the energy management device (30).

The operation of the total heat-exchanging device 500 or the ventilator cleaner 600 can be controlled by the energy management device 30 according to the level of the electric power charge because the electric power charge varies with time.

15 shows a distributor 700 disposed between the total heat-exchanging apparatus 500 and a plurality of ventilator cleaners 600.

The distributor 700 is connected to the first air duct 511 connected to the total heat-exchanging apparatus 500 and the second air duct 512.

The first air duct 511 and the second air duct 512 are also connected between the distributor 700 and each ventilator cleaner 600.

In the distributor 700, an opening / closing device (not shown) is provided to selectively block the flow of air to / from each ventilator cleaner 600.

Thus, the ventilator cleaner 600 installed in the indoor space to be ventilated is communicated with the total heat-exchanging device 500 by the mediating operation of the distributor 700 according to the circumstances, Outdoor air can be introduced into the corresponding indoor space.

The rest of the configuration is the same as that of FIG. 14 except that the distributor 700 is added, so that detailed description of other parts will be omitted.

16 shows an embodiment in which a humidifier 800 disposed between the total heat-exchanging apparatus 500 and the ventilation cleaner 600 is disposed.

The humidifier 800 is installed in the first air duct 511 so that the outdoor air flowing from the total heat-exchanging apparatus 500 to the ventilator cleaner 600 is introduced into the indoor space .

In particular, when it is necessary to increase the indoor humidity by drying air such as spring or winter, the humidifier 800 is operated to maintain the humidity of the air in an appropriate state.

Except for the addition of the humidifier 800, the rest of the configuration is the same as that described with reference to FIG. 14, so a detailed description of other parts will be omitted.

Hereinafter, the operation of the embodiment shown in Figs. 14 to 16 will be described.

First, it is determined whether the current time belongs to the on-peak time period. If the current off-peak time period is present, the current operation mode is maintained.

However, if it is determined that the current time belongs to the on-peak time period, outdoor air is introduced into the indoor space and the indoor air is discharged to the outside in order to raise the indoor temperature when the indoor temperature is lower than the predetermined reference temperature.

Here, the reference temperature may be an outdoor temperature, or may be a predetermined temperature.

In this case, if there is only one control target air purifier 600 or the total heat-exchanging device 500, the exhaust fan of the ventilator cleaner 600 performs continuous operation in order to positively discharge indoor air, Intermittent operation is performed.

However, if the ventilation fan of the ventilation cleaner 600 is composed of one fan instead of the air supply fan and the exhaust fan, the intermittent operation may be performed in the on-peak time interval.

Meanwhile, the supply fan and the exhaust fan of the total enthalpy heat exchanger 500 are continuously operated for normal flow of air.

The operation of the air supply fan and the air exhaust fan in the ventilation cleaner 600 is similar to that of the air supply fan and the exhaust fan of the ventilator in each indoor space shown in FIG.

The control flow in the ventilation cleaner 600 is similar to that shown in FIG.

 The air supply fan of the ventilator cleaner 600 alternately operates and stops during the on-peak time period. It is preferable that the stopping time is longer than the operation time for power saving.

However, if there are a plurality of control subject air purifiers and are arranged in a plurality of indoor spaces, the ventilator cleaners disposed in some indoor spaces are in an operating state, and the ventilator cleaners disposed in other indoor spaces are in a stopped state.

However, in the total enthalpy heat exchanger 500, the air supply fan and the exhaust fan normally operate for normal indoor / outdoor air flow.

The air supply fan and the exhaust fan stop rotating in the ventilation cleaner in a stopped state.

At this time, in the air cleaner in operation, the air supply fan performs intermittent operation and the exhaust fan performs continuous operation.

Then, when a predetermined time elapses, the ventilation cleaner in operation is stopped, and the ventilator, which has been stopped, is in the operating state.

As described above, the air supply fan performs the intermittent operation and the exhaust fan performs the continuous operation in the ventilation cleaner in the operating state.

That is, the ventilating operation is first performed for a specific indoor space, and when a predetermined time elapses, the ventilating operation in the specific indoor space is stopped and the ventilating operation is performed for the other indoor space.

On the other hand, when it is determined that the current time belongs to the on-peak time period, outdoor air is introduced into the indoor space to lower the indoor temperature and the indoor air is discharged to the outdoor when the indoor temperature is higher than the predetermined reference temperature.

However, if it is the current off-peak time interval, the current operation mode is maintained.

Here, the reference temperature may be a set specific temperature or an outdoor temperature.

In this case, if there is only one ventilation purifier to be controlled, the air supply fan of the ventilation cleaner 600 performs continuous operation for actively discharging indoor air, and the exhaust fan of the ventilation cleaner 600 performs intermittent operation do.

In this situation, if the ventilation fan of the ventilation cleaner 600 is not constituted by the air supply fan and the exhaust fan but is constituted by one ventilation fan, the ventilation fan may perform the intermittent operation in the on peak time period.

However, the supply fan and the exhaust fan of the total enthalpy heat exchanger 500 are continuously operated for normal flow of air.

Here, the operations of the air supply fan and the air discharge fan in the ventilation cleaner 600 are similar to those of the air supply fan and the air discharge fan of the ventilator in each indoor space shown in FIG.

The control flow is similar to that disclosed in Fig.

That is, the exhaust fan of the ventilator cleaner 600 alternately operates and stops during the on-peak time period. It is preferable that the stopping time is longer than the operation time for power saving.

However, if there are a plurality of ventilator purifiers 600 to be controlled and are disposed in a plurality of indoor spaces, the ventilator cleaner 600 disposed in a certain indoor space is in an operating state, and the ventilator cleaners 600 Is in a stopped state.

The air supply fan and the exhaust fan are stopped by the ventilation cleaner 600 which is in a stopped state.

At this time, in the ventilation cleaner 600 in operation, the exhaust fan performs intermittent operation as described above, and the air supply fan performs continuous operation.

Then, when a predetermined time has elapsed, the ventilator cleaner 600 in operation is stopped, and the ventilator cleaner 600 which has been stopped is in the operating state.

Also, in the ventilation cleaner 600 which is in the operating state, the exhaust fan performs the intermittent operation as described above, and the air supply fan performs the continuous operation.

That is, similar to FIG. 10, the ventilating operation is first performed for a specific indoor space, and when a predetermined time has elapsed, the ventilating operation for the specific indoor space is stopped and the ventilating operation is performed for another indoor space.

10: air conditioner 100: indoor unit
200: ventilation device 210: total heat exchanger
220: air supply fan 230: exhaust fan
240: intake valve 250: exhaust valve
400: outdoor unit 500: total heat exchanger
600: Ventilation cleaner 700: Dispenser
800: Humidifier

Claims (13)

Recognizing the electric power charge information;
Determining whether a current power charge is greater than a predetermined criterion;
Determining whether a cooling operation or a heating operation is performed by a separate air conditioner;
And intermittently operating the air supply fan or the exhaust fan based on the difference between the room temperature and the outdoor temperature when the current power charge is equal to or higher than a predetermined criterion and the cooling or heating operation is performed,
The air supply fan of the ventilating apparatus performs the intermittent operation in which the operation and the stop are alternately performed and the exhaust fan continuously performs the operation when the air supply operation is performed by the separate air conditioner and the indoor temperature is higher than the outdoor temperature. Is controlled to be < RTI ID = 0.0 > A method of controlling a ventilator. delete The method according to claim 1,
Wherein the operation time of the air supply fan is shorter than the stop time. The method according to claim 1,
When the cooling operation is performed by the separate air conditioner and the room temperature is lower than the outdoor temperature,
Wherein the air supply fan and the exhaust fan of the ventilator are stopped. The method according to claim 1,
The heating operation is performed by the separate air conditioner, and when the room temperature is lower than the outdoor temperature,
Wherein the exhaust fan of the ventilator performs intermittent operation for alternately performing operation and stop, and controls the air supply fan to continuously operate. 6. The method of claim 5,
Wherein the operation time of the exhaust fan is shorter than the stop time. delete Recognizing the electric power charge information;
Determining a difference between the indoor temperature and the outdoor temperature;
And intermittently operating the air supply fan or the exhaust fan while operating the heat transfer unit based on the difference between the indoor temperature and the outdoor temperature when the current electric power charge is equal to or higher than a predetermined standard,
When the cooling operation is performed by a separate air conditioner and the indoor temperature is higher than the outdoor temperature, the air supply fan of the ventilator performs intermittent operation to alternately perform operation and stop, and the exhaust fan performs continuous operation And a control unit for controlling the ventilation device. delete 9. The method of claim 8,
When the indoor fan is operated at a temperature lower than the outdoor temperature, the exhaust fan of the ventilator performs an intermittent operation for alternately performing the operation and the stop, and the air supply fan performs the continuous operation And a control unit for controlling the ventilation device. 11. The method of claim 10,
Further comprising the step of determining whether the ventilator is plural,
Wherein when the number of the ventilating apparatuses is plural, the ventilating apparatus is kept in the operating state and the other ventilating apparatus is in the stopped state. 12. The method of claim 11,
Further comprising determining whether a predetermined time has elapsed,
Wherein when the predetermined time has elapsed, the ventilator in operation is stopped and the ventilator in stop is operated. 9. The method of claim 8,
Wherein the operation time of the exhaust fan or the air supply fan during intermittent operation is shorter than the stop time.

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