KR20150059830A - Air conditioning system - Google Patents

Abstract

An air conditioning system according to an embodiment of the present disclosure includes an air supply blower for introducing outdoor air as room air to a room side; An exhaust blower for discharging indoor air as outdoor air to the outdoor side; A supply air flow path through which the supply air flows and an exhaust flow path through which the discharge air flows, the supply air flowing through the supply air blower and the exhaust air blower An exhaust heat exchanger for exchanging heat with the exhaust air flowing by the exhaust heat exchanger; An enthalpy operation unit for measuring temperature and humidity of the supply air, temperature and humidity of the discharge air, and calculating outdoor enthalpy and indoor enthalpy; A first operation for continuously operating the air supply fan and the exhaust air blower on the basis of the outdoor enthalpy and the indoor enthalpy; and a second operation for operating the air supply fan and the exhaust air blower, And a control unit for selectively switching a second operation for intermittently operating the air supply blower and the air discharge blower at a high rotation speed.

Description

[0001] AIR CONDITIONING SYSTEM [0002]

Disclosure relates to an air conditioning system and more specifically to a system and method for controlling the rate of heat exchange between the outside air and the exhaust air based on a difference in enthalpy of indoor air and outdoor air, To an air conditioning system in which a flow rate is controlled.

Generally, a building in which a person lives, such as a residential space, an office, a business place, and a factory, is provided with an air conditioning system for discharging contaminated air from the room to the outside and for introducing pleasant outdoor air.

The window is the basis of the air conditioning system, and it was a means to connect the indoor space and the outdoor space directly and to be able to drink comfortable air in the room indoors.

However, in recent years, ventilation of the ventilator or purifier by the air purifier has been performed rather than the ventilation through the window due to the air pollution and noise of the city, crime prevention, insulation, structural characteristics of the building, convenience of living and the like.

In the indoor space, facilities are installed for cooling in summer and heating in winter in order to keep people's activities from hindering.

However, in the process of ventilating the indoor air in order to provide a pleasant air for the person to operate, the temperature of the indoor air controlled by the air conditioner is lost to the outside together with the air, and the outdoor air flows into the room The air in the room is suddenly changed by the outdoor air.

That is, in the case of summer cooling, hot air outdoors is introduced into the room, resulting in a decrease in cooling efficiency of the room. In the case of heating in winter, cold air outside the room flows into the room, .

In order to improve this, Applicant has disclosed the control of the flow rate of the outside air using the enthalpy difference between the outdoor air and the indoor air (Korean Patent No. 10-1221393).

Specifically, the above patent is to control the mixing ratio of the outside air and the ventilation (air in which a part of the exhaust gas returns to the room again) based on the difference of enthalpy of outdoor air and indoor air.

However, since unnecessary outside air still flows into the room, unnecessary increase in the heating and cooling load is caused. Therefore, energy saving by enthalpy control is limited.

The present disclosure aims at providing an air conditioning system that minimizes an increase in the heating and cooling load due to the inflow of outside air more than necessary.

According to an aspect of an air conditioning system according to the present disclosure, an air supply blower for introducing outdoor air into the room as supply air; An exhaust blower for discharging indoor air as outdoor air to the outdoor side; A supply air flow path through which the supply air flows and an exhaust flow path through which the discharge air flows, the supply air flowing through the supply air blower and the exhaust air blower An exhaust heat exchanger for exchanging heat with the exhaust air flowing by the exhaust heat exchanger; An enthalpy operation unit for measuring temperature and humidity of the supply air, temperature and humidity of the discharge air, and calculating outdoor enthalpy and indoor enthalpy; A first operation for continuously operating the air supply fan and the exhaust air blower on the basis of the outdoor enthalpy and the indoor enthalpy; and a second operation for operating the air supply fan and the exhaust air blower, And a controller for selectively switching a second operation for intermittently operating the air supply blower and the air exhaust blower at a high rotation speed.

In the air conditioning system according to one aspect of the present disclosure, the control unit controls the first operation when the outdoor enthalpy is equal to or higher than a first reference and the outdoor enthalpy is greater than the indoor enthalpy, And controlling the second operation when the outdoor enthalpy is smaller than the indoor enthalpy.

The air conditioning system according to one aspect of the present invention controls the first operation when the outdoor enthalpy is lower than a first reference and the outdoor enthalpy is lower than the indoor enthalpy, And controlling the second operation when the outdoor enthalpy is larger than the indoor enthalpy.

In the air conditioning system according to one aspect of the present disclosure, the enthalpy calculation unit calculates the outdoor enthalpy using the temperature and humidity at the inlet air inlet side of the total enthalpy heat exchanger, and calculates the temperature And to calculate the indoor enthalpy by measuring the humidity.

The air conditioning system according to one aspect of the present disclosure includes a cooling mechanism for cooling the room so that the room air has a predetermined cooling enthalpy, And controlling the second operation when the outdoor enthalpy is smaller than the cooling enthalpy while the cooling mechanism is in operation.

The air conditioning system according to one aspect of the present disclosure includes a heating mechanism for heating the room so that the room air has a predetermined heating enthalpy, And controlling the second operation when the outdoor enthalpy is greater than the cooling enthalpy while the heating mechanism is in operation.

In the air conditioning system according to an aspect of the present disclosure, the supply blower and the exhaust blower may be provided such that the rotational speed thereof is variable by an inverter motor.

According to the air conditioning system of the present disclosure, unnecessary increase of the cooling / heating load due to the introduction of the unnecessary outside air can be minimized by controlling the air supply blower and the exhaust blower based on the outdoor enthalpy and the indoor enthalpy by the first operation and the second operation , And the power consumption can be minimized due to the control of the first operation and the second operation.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram showing the configuration of an air conditioning system according to an embodiment of the present disclosure;
FIG. 2 is a graph showing the relationship between the blower air volume and the startup time when the air supply fan and the air discharge fan are set to continuous operation or intermittent operation in the air conditioning system according to the embodiment of the present disclosure,
3 is a control flow diagram of an air conditioning system according to an embodiment of the present disclosure;
4 is a control flowchart of an air conditioning system according to another embodiment of the present disclosure.

Hereinafter, an air conditioning system according to an embodiment of the present disclosure will be described in detail with reference to the accompanying drawings.

Prior to this, the inventor could properly define the term concept to describe its invention in the best possible way, so that the terms and words used in the specification and claims are to be construed as limited to a conventional or dictionary meaning And should be construed as meaning and concept consistent with the technical idea of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a configuration of an air conditioning system according to an embodiment of the present disclosure; FIG.

Referring to FIG. 1, an air conditioning system 100 according to the present embodiment includes an air supply blower 110, an exhaust blower 120, an overall heat exchanger 130, an enthalpy calculation unit 140, and a control unit c.

The air blower 110 is provided to introduce outdoor air into the room as supply air and the exhaust blower 120 is provided to discharge indoor air as outdoor air to the outdoor side.

Both the air supply fan 110 and the exhaust fan 120 are constituted by a fan body and a fan motor for driving the fan body. The fan motor is provided with a rotation number switching mechanism for stepwise changing the rotation number of the fan motor, and the rotation speed of the fan can be adjusted by the rotation number switching mechanism. In the present embodiment, the fan motor is provided with an inverter motor and can be continuously rotated.

The total enthalpy heat exchanger 130 includes a supply air flow path through which the supply air flows and an exhaust flow path through which the discharge air flows. The supply air flowing by the supply air blower 110 and the exhaust air To exchange heat with the air.

In the total enthalpy heat exchanger (130), heat and moisture move from one side of the outdoor air flowing through the air supply duct to the other side of the air flowing through the exhaust duct. That is, in the total enthalpy heat exchanger 130, the enthalpy is exchanged between humidified air.

The enthalpy calculation unit 140 measures the temperature and humidity of the supplied air, the temperature and the humidity of the discharged air, and calculates the outdoor enthalpy and the indoor enthalpy.

To this end, the enthalpy calculation unit 140 includes an air supply side temperature and humidity inspection port for measuring the temperature and humidity of the supply air, and an exhaust side temperature and humidity inspection port for measuring the temperature and humidity of the discharge air. The enthalpy calculation unit 140 calculates the outdoor enthalpy using the temperature and humidity at the inlet air inlet side of the total enthalpy heat exchanger 130 and measures the temperature and humidity at the inlet air inlet side of the total enthalpy heat exchanger 130, To calculate an output signal.

The control unit (c) includes a first operation (continuous operation) for continuously operating the air supply fan (110) and the exhaust air blower (120) based on the outdoor enthalpy and the indoor enthalpy, (Intermittent operation) for intermittently operating the air supply blower 110 and the exhaust blower 120 at a rotational speed higher than that in the first operation so as to be equal to each other.

FIG. 2 is a graph showing the relationship between the blower air volume and the startup time when the air supply fan and the air discharge fan are set to continuous operation or intermittent operation in the air conditioning system according to the embodiment of the present disclosure.

 Here, the intermittent operation has a larger amount of air than the continuous operation, but the operation time of the intermittent operation is set shorter than the continuous operation so that the ventilation amount of both is set to the same value.

When the air supply fan 110 and the exhaust air blower 120 are set to the continuous operation mode, the air supply fan 110 and the exhaust air blower 120 are rotated by the inverter motor at a rotational speed slower than the minimum rotational speed at the time of the arbitrary ventilation operation .

On the other hand, when the air supply fan 110 and the exhaust air blower 120 are set to intermittent operation, the number of revolutions of the inverter motor of the air supply fan 110 and the exhaust air blower 120 is increased and intermittent operation is performed.

Therefore, the air flow rate B of the continuous operation is smaller than the air flow rate A of the intermittent operation, and the heat exchange efficiency by the total enthalpy heat exchanger 130 is lowered in the case of the intermittent operation in which the air flow rate is large.

As a result, in the total enthalpy heat exchanger 130 that discharges indoor air and heat exchanged outside air to the room, intermittent operation is performed when the temperature of the air to be discharged into the room is made not to approach the room temperature. Conversely, when the temperature of the air to be discharged into the room approaches the room temperature, the continuous operation is performed.

Fig. 3 is a control flow chart of an air conditioning system according to one embodiment of the present disclosure, and Fig. 4 is a control flow chart of an air conditioning system according to another embodiment of the present disclosure.

3, the control unit (c) controls the first operation when the outdoor enthalpy is equal to or greater than the first reference and the outdoor enthalpy is greater than the indoor enthalpy. When the outdoor enthalpy is equal to or greater than the first reference and the outdoor enthalpy is smaller than the indoor enthalpy The second operation can be provided.

The control unit (c) controls the first operation when the outdoor enthalpy is lower than the first reference and the outdoor enthalpy is lower than the indoor enthalpy. When the outdoor enthalpy is lower than the first standard and the outdoor enthalpy is larger than the indoor enthalpy, .

Specifically, in ST1, it is determined whether or not the outdoor enthalpy H1 is equal to or higher than a predetermined set enthalpy (Hset). Here, the set enthalpy (Hset) can be calculated by the temperature and humidity input by the user.

ST1 is for determining the season outdoors. Since the outdoor enthalpy H1 in ST1 is the inlet enthalpy on the air supply side of the total enthalpy heat exchanger 130, it is almost the same as the outdoor enthalpy. If the outdoor enthalpy H1 is equal to or higher than the set enthalpy (Hset), it is determined to be summer. If the outdoor enthalpy H1 is less than the set enthalpy (Hset), it is determined to be winter. If the condition of ST1 is satisfied, it is judged as summer and it moves to ST2. Otherwise, it is judged as winter and it moves to ST3.

In ST2, it is determined whether or not the outdoor enthalpy H1 is lower than the indoor enthalpy H2. If the condition of ST2 is satisfied, the routine proceeds to ST4 where the air supply fan 110 and the exhaust air blower 120 are intermittently operated.

On the other hand, if the condition of ST2 is not satisfied, the operation goes to ST5 and the fans 20 and 21 are continuously operated.

Since the indoor enthalpy H2 is the exhaust-side enthalpy of the total enthalpy heat exchanger 130, it is almost the same as the indoor enthalpy.

In ST2, in the case of summer, when the outdoor enthalpy H1 is lower than the indoor enthalpy H2, it is preferable to discharge the outdoor air temperature to the room without increasing the outdoor air temperature as much as possible in the total heat exchanger 130. [

Therefore, in this case, the air supply blower 110 and the exhaust blower 120 are intermittently operated (ST4).

As described above, since the temperature exchange efficiency of the total enthalpy heat exchanger 130 is lowered as described above, it is possible to discharge the air outside the room without increasing the temperature of the outdoor air as much as possible in the total enthalpy heat exchanger 130.

Conversely, when the outdoor enthalpy H1 is equal to or higher than the indoor enthalpy H2, it is preferable that the outdoor air temperature is lowered by the total enthalpy heat exchanger 130 as much as possible, and then the air is discharged into the room.

Accordingly, in this case, the air supply blower 110 and the exhaust blower 120 are continuously operated (ST5).

As described above, since the temperature exchange efficiency of the total enthalpy heat exchanger 130 is increased as described above, the outdoor air temperature can be increased by the total enthalpy heat exchanger 130 as much as possible, and then the air can be discharged into the room.

On the other hand, in ST3, it is determined whether or not the outdoor enthalpy H1 is higher than the indoor enthalpy H2.

If the condition of ST3 is satisfied, the routine goes to ST6 to cause the fans 20 and 21 to perform intermittent operation.

On the other hand, if the condition of ST3 is not satisfied, the routine proceeds to ST7 where the air supply fan 110 and the exhaust air blower 120 are operated continuously.

If the outdoor enthalpy H1 is lower than the indoor enthalpy H2 in the case of winter in ST3, as opposed to the summer, the outdoor air temperature is increased as much as possible in the total enthalpy heat exchanger 130 and then the air is discharged into the room good.

Therefore, in this case, the air supply blower 110 and the exhaust blower 120 are continuously operated (ST7).

As described above, since the temperature exchange efficiency of the total enthalpy heat exchanger 130 is increased as described above, the outdoor air temperature can be increased by the total enthalpy heat exchanger 130 as much as possible, and then the air can be discharged into the room.

When the outdoor enthalpy H1 is higher than the indoor enthalpy H2, it is preferable to discharge the outdoor air temperature to the room without lowering the outdoor air temperature by the total enthalpy heat exchanger 130 as much as possible.

Therefore, in this case, the air supply blower 110 and the exhaust blower 120 are intermittently operated (ST6).

As described above, since the temperature exchange efficiency of the total enthalpy heat exchanger 130 is lowered as described above, it is possible to discharge the air outside the room without lowering the outdoor air temperature as much as possible by the total enthalpy heat exchanger 130.

The temperature of the air supplied to the room can be controlled by intermittently or continuously operating the air supply fan 110 and the exhaust air blower 120 based on the outdoor enthalpy H1 and the indoor enthalpy H2.

4, the controller c further includes a cooling unit 150 for cooling the room so that the indoor air has a predetermined cooling enthalpy. The control unit c may be configured to control the indoor enthalpy If the outdoor enthalpy is larger than the enthalpy, the control is performed to the first operation. If the outdoor enthalpy is smaller than the cooling enthalpy in the state where the cooling mechanism 150 is operated, the control is performed to the second operation.

Alternatively, when the indoor air further includes a heating device 160 for heating the indoor space so that the indoor air has a predetermined heating enthalpy, when the outdoor enthalpy is smaller than the heating enthalpy in a state where the heating device is in operation, And controls the second operation when the outdoor enthalpy is greater than the cooling enthalpy in a state where the heating device 160 is operating.

Specifically, the total enthalpy heat exchanger 130 is operated while being interlocked with the cooling mechanism and the heating mechanism.

In ST11, it is determined whether or not the operation mode of the air conditioning system 100 is the cooling operation. If the cooling operation is determined, the operation proceeds to ST12. If it is not cooling operation, the heating operation is determined and the operation proceeds to ST13. That is, if the operation mode of the air conditioning system 100 is cooling, it is determined to be summer, and if it is heating, it is determined to be winter.

In ST12, it is determined whether the outdoor enthalpy H1 is lower than the cooling enthalpy of the air conditioning system 100 or not.

When the outdoor enthalpy H1 is lower than the cooling enthalpy, it is preferable that the outdoor air temperature is discharged to the room without increasing the temperature of the outdoor air by the total enthalpy heat exchanger 130 as much as possible.

Therefore, in this case, the air supply blower 110 and the exhaust blower 120 are intermittently operated.

As described above, since the temperature exchange efficiency of the total enthalpy heat exchanger 130 is lowered as described above, it is possible to discharge the air outside the room without increasing the temperature of the outdoor air as much as possible in the total enthalpy heat exchanger 130.

Conversely, when the outdoor enthalpy H1 is equal to or higher than the cooling enthalpy, it is preferable that the outdoor air temperature is lowered by the total enthalpy heat exchanger 130 as much as possible, and then the air is discharged into the living room.

Therefore, in this case, the air supply blower 110 and the exhaust blower 120 are continuously operated.

As described above, since the temperature exchange efficiency of the total enthalpy heat exchanger 130 is increased as described above, the outdoor air temperature can be lowered by the total enthalpy heat exchanger 130 as much as possible, and then the air can be discharged into the room.

On the other hand, in ST13, it is determined whether the outdoor enthalpy H1 is higher than the heating enthalpy of the air conditioning system 100 or not. When the outdoor enthalpy H1 is higher than the heating enthalpy, it is preferable that the outdoor air temperature is not lowered by the total enthalpy heat exchanger 130 as much as possible and the air is discharged into the room.

Therefore, in this case, the air supply blower 110 and the exhaust blower 120 are intermittently operated.

As described above, since the temperature exchange efficiency of the total enthalpy heat exchanger 130 is lowered as described above, it is possible to discharge the air outside the room without lowering the outdoor air temperature as much as possible by the total enthalpy heat exchanger 130.

On the contrary, when the outdoor enthalpy H1 is equal to or lower than the heating enthalpy, it is preferable that the outdoor air temperature is raised by the total enthalpy heat exchanger 130 as much as possible, and then the air is discharged into the room.

Therefore, in this case, the air supply blower 110 and the exhaust blower 120 are continuously operated.

As described above, since the temperature exchange efficiency of the total enthalpy heat exchanger 130 is increased as described above, the outdoor air temperature can be increased by the total enthalpy heat exchanger 130 as much as possible, and then the air can be discharged into the room.

The temperature of the air supplied to the room is controlled by intermittently or continuously operating the air supply fan 110 and the exhaust air blower 120 based on the outdoor enthalpy H1 and the set temperature and the set humidity of the air conditioning system 100 can do.

It is to be understood that both the foregoing general description and the following detailed description of the present invention are exemplary and explanatory and are intended to be illustrative of the present invention only and should not be construed as limiting the scope of the present invention. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (7)

A supply air blower for introducing outdoor air into the room as supply air;
An exhaust blower for discharging indoor air as outdoor air to the outdoor side;
A supply air flow path through which the supply air flows and an exhaust flow path through which the discharge air flows, the supply air flowing through the supply air blower and the exhaust air blower An exhaust heat exchanger for exchanging heat with the exhaust air flowing by the exhaust heat exchanger;
An enthalpy operation unit for measuring temperature and humidity of the supply air, temperature and humidity of the discharge air, and calculating outdoor enthalpy and indoor enthalpy; And
A first operation for continuously operating the air supply fan and the exhaust air blower on the basis of the outdoor enthalpy and the indoor enthalpy, and a second operation for continuously operating the air supply fan and the exhaust air blower when the first operation time is substantially equal to the first operation time And a second operation for selectively intermittently operating the air supply blower and the air exhaust blower at a rotational speed. The method according to claim 1,
Wherein,
Controlling the first operation when the outdoor enthalpy is equal to or greater than a first reference and the outdoor enthalpy is greater than the indoor enthalpy,
And controls the second operation when the outdoor enthalpy is equal to or greater than the first reference and the outdoor enthalpy is smaller than the indoor enthalpy. The method according to claim 1,
And controlling the first operation when the outdoor enthalpy is equal to or lower than the first criterion and the outdoor enthalpy is smaller than the indoor enthalpy,
And controls the second operation when the outdoor enthalpy is lower than a first criterion and the outdoor enthalpy is greater than the indoor enthalpy. The method according to claim 2 or 3,
Wherein the enthalpy calculation unit comprises:
The outdoor enthalpy is calculated using the temperature and humidity at the inlet air inlet side of the total enthalpy heat exchanger,
And the indoor enthalpy is calculated by measuring the temperature and humidity of the exhaust air inlet side of the total enthalpy heat exchanger. The method according to claim 1,
And a cooling mechanism for cooling the room so that the room air has a predetermined cooling enthalpy,
Wherein the controller controls the first operation when the outdoor enthalpy is greater than the cooling enthalpy in a state where the cooling mechanism is in operation and controls the first operation when the outdoor enthalpy is smaller than the cooling enthalpy, 2 < / RTI > operation. The method according to claim 1,
And a heating mechanism for heating the room so that the indoor air has a predetermined heating enthalpy,
Wherein the controller controls the first operation when the outdoor enthalpy is smaller than the heating enthalpy in a state where the heating mechanism is in operation and controls the first operation when the outdoor enthalpy is greater than the heating enthalpy, 2 < / RTI > operation. The method according to claim 1,
Wherein the rotational speeds of the air supply blower and the exhaust blower are varied by an inverter motor.

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