KR101475498B1 - Energy saving type air conditioner and supply air control method thereof - Google Patents

Abstract

The present invention relates to an air conditioner having an energy saving effect relative to the related art, and a control method for air supply using the same. The air conditioner controls supply air (SA) in such a way that in ventilation are (RA) fed to the indoor, some parts of exhaust are (EA) are discharged to the outdoor, and circulation air (CA) except for the exhaust air (EA) and outer air (OA) fed from the outdoor is heat-exchanged, and then is supplied to the indoor. A first heat exchanger (200) is installed at a downstream side of the circulation air (CA), and a second heat exchanger (300) is installed at a downstream side of the outer air (OA). The circulation air (CA″) heat-exchanged by the first heat exchanger (200) and the outer air (OA″) heat-exchanged by the second heat exchanger (300) are mixed and supplied to the indoor.

Description

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

The present invention relates to an air conditioner, and it is an object of the present invention to provide an air conditioner that performs individual harmonization of circulating air and outdoor air using a separate heat exchanger having different heat recovery rates for temperature and humidity, The present invention relates to an air conditioner and an air supply control method using the air conditioner.

Generally, the air conditioner is equipped with an air filter, a cooling and heating heat exchanger, a humidifier, and a blower so that the indoor space is cooled using a heat exchanger for cooling in summer and the heating is performed using a heat exchanger in winter.

1 is an exemplary view showing a configuration of a conventional air conditioner.

Generally, the air conditioner 1 has a ventilation unit 7 having a ventilation inlet part 2, an exhaust part 3, an outside air inlet part 4, and an air supply part 6, An air blowing unit 8 for air, and a heat exchanger 5 for air conditioning. In addition, a harmonic unit such as a filter 51 and a humidifier 53 may be additionally provided.

Specifically, the ventilating blower 7 is installed at the boundary between the ventilation inlet portion 2 and the ventilator 3, and allows indoor air to flow into the ventilating inlet portion 2 through the inlet 21 (ventilation RA: (EA) is exhausted through the exhaust damper 31 provided in the exhaust part 3, and the remaining ventilation (exhaust air) except the exhaust EA RA, that is, circulation air (CA: Circulation Air) to the outside air introduction portion 4 through the bypass damper 35.

The outside fresh air flows into the inside of the outside-air introducing portion 4 (outside air OA) through the outside-air damper 41 provided in the outside-air introducing portion 4 by the internal pressure by the operation of the air supply blower 8, The outside air OA flowing into the inside is mixed with the circulating air CA flowing into the outside air introducing portion 4 through the bypass damper 35.

The mixed air MA in which the circulating air CA and the outside air OA are combined is harmonized while passing through the heat exchanger 5 via the filter 51 and is supplied to the air supply unit 6 via the air supply blower 8, (Supply air SA) through the discharge port 61 to the room again.

On the other hand, as a heat exchanger 5 for maintaining a constant temperature with respect to the mixed air MA in which the circulating air CA and the outside air OA are combined, a metallic sensible heat exchanger for controlling the heat (sensible heat) But it is common to use a pulp (paper) total heat exchanger to control the heat (latent heat) of moisture in the air as well as the sensible heat in order to maintain proper humidity.

The mixed air MA, in which the circulating air CA and the outside air OA are combined, is supplied to the room while being kept at a predetermined temperature and humidity while passing through the heat transfer heat exchanger 5.

On the other hand, conceptually, a heat exchanger is a heat exchanger that controls the amount of heat (sensible heat) and the amount of water (latent heat) in the air, and the sensible heat exchanger is a heat exchanger , And the latent heat exchanger refers to controlling only the heat (latent heat) of moisture in the air, i.e., humidity.

The total heat recovery rate of the total heat exchanger is about 2.5 times greater than that of the sensible heat exchanger. The difference is that the sensible heat exchanger does not have latent heat recovery ability due to the transfer of moisture (latent heat) Because.

Also, in general, the total heat exchanger controls the temperature and humidity of the air through the high moisture permeable element to provide comfort to the occupants, while the sensible heat exchanger controls the temperature only, which causes the room to be dried. However, Even when energy is saved by heat recovery, the pressure loss is large, so that the energy consumption of the blower is more consumed and the energy saving effect is reduced. In order to reduce the pressure loss during the installation of the total heat exchanger, It is common to set it low around 2.0 m / s.

Further, when the mixed air in which the ventilation and the outside air are mixed, such as the conventional air conditioner, is uniformly exchanged through the total enthalpy heat exchanger, there is a problem that the heat exchange load is large and the heat exchange efficiency is lowered. In order to perform batch heat exchange with respect to the mixed air, Since the passing wind speed of the wind turbine is set to be low, there is a problem of cost increase due to the inevitably large size in order to compensate it.

The sensible heat exchanger or the latent heat exchanger can be classified as a type of total heat exchanger. In this case, the heat exchanger that mainly controls the heat (sensible heat) of the air in the air is referred to as a sensible heat exchanger, ) Can be referred to as a latent heat exchanger.

Accordingly, it is an object of the present invention to provide a method and apparatus for performing independent heat exchange with circulating air and outdoor air excluding air before and after air supply by using separate heat exchangers, and then mixing air mixed with circulated air and ambient air The present invention provides an air conditioner and a supply control method using the same, which can reduce power consumption due to an increase in efficiency compared to the prior art, and can reduce cost due to size reduction of parts.

Particularly, in the present invention, the circulating air is controlled by using a heat exchanger having a high sensible heat capacity, and in the case of the outside air, the circulated air circulated through each heat exchanger is mixed with the outside air, The present invention provides an air conditioner having excellent energy saving effect by inducing re-compensation action of temperature (sensible heat) and humidity (latent heat), and a supply control method using the same.

According to an aspect of the present invention, there is provided an exhaust gas recirculation system for an internal combustion engine, the exhaust system including: CA), and then supplies a conditioned air supply (SA) to the indoor air. A first heat exchanger (200) installed downstream of the circulating air (CA) to harmonize the circulating air (CA); A second heat exchanger (300) installed downstream of the outside air (OA) to harmonize the outside air (OA); And an air supply chamber (150) provided between the first heat exchanger (200) and the second heat exchanger (300) to supply a mixed supply of circulated air (CA ") and outside air (OA" And a blower 180 for supplying air to the room.

In this case, the first heat exchanger 200 is a sensible heat exchanger having a large amount of heat recovery from the gas contained in the air and the gas contained in the air. The second heat exchanger 300 is applied to a latent heat exchanger having a large amount of heat recovery from moisture contained in the air and moisture contained in the air.

On the other hand, in the ventilation (RA) introduced from the room, some of the exhaust air (EA) is discharged to the outside of the room, and heat exchange is performed with respect to the outside air OA flowing from the outside and the remaining circulating air CA excluding the exhaust air In controlling the supply air (SA) supplied to the room, A first heat exchanger 200 is disposed downstream of the circulating air CA and a second heat exchanger 300 is disposed downstream of the outside air OA. The first heat exchanger 200 and the second heat exchanger The circulation air CA and the outside air OA which are heat-exchanged individually by using the air supply chamber 300 are mixed in the air supply chamber 150 and supplied to the room.

In the indoor cooling mode, the circulating air (CA ") passing through the first heat exchanger (200) is cooled to a temperature lower than the set indoor temperature, The ambient air OA "passing through the room humidity is humidified to a humidity lower than the set room humidity, and the temperature at least higher than the set room temperature is maintained; It is preferable that the individual conditioned circulating air (CA '') and the outside air (OA ') are mixed in the air supply chamber (150) and are heat exchanged to reach the set room temperature and room humidity,

During the indoor heating, the circulating air (CA ") passing through the first heat exchanger (200) is overheated to a temperature higher than the set indoor temperature, the humidity lower than the set indoor humidity is maintained, and the second heat exchanger The passed outside air OA "is humidified to a humidity higher than the set room humidity, and the temperature is kept lower than the set room temperature; It is preferable that the individual conditioned circulating air (CA '') and the outside air (OA ') are mixed in the air supply chamber (150) and are heat exchanged to reach the set room temperature and room humidity.

In the present invention, the second heat exchanger is controlled by using a first heat exchanger having a large sensible heat capacity in the case of circulating air in which ventilation is excluded from the ventilation, and a second heat exchanger having a large latent heat capability in the case of the outside air. The circulation air and the outside air which have undergone the individual heat exchange are mixed in the air supply chamber to perform the thermal compensation again and then the air supply is supplied to the room so that the power consumption due to the increase in efficiency is increased compared with the air conditioner using the conventional one total air heat exchanger It is possible to remarkably reduce the cost, and it is possible to reduce the cost by reducing the size of the heat exchanger parts.

1 is a side view showing a configuration of a conventional air conditioner.
2 is a side view showing the configuration of an air conditioner according to the present invention.
3 is an exemplary view showing the load state of the total enthalpy heat exchanger according to the temperature / humidity change of the conditioned air passing through the conventional total enthalpy heat exchanger.
4 is a view illustrating a load state of the first and second heat exchangers according to temperature / humidity changes of the conditioned air passing through the first and second heat exchangers of the present invention.

The features and advantages of the present invention described above or not described above will be more apparent from the following description of embodiments of the present invention with reference to the accompanying drawings.

2 is a side view showing a configuration of an air conditioner according to the present invention.

The air conditioner 100 according to the present invention includes the ventilation inlet portion 120, the exhaust portion 130, the outside air inlet portion 160, and the air supply portion 140 as in the conventional art.

As shown in the drawing, the ventilation inlet part 120 and the ventilation part 130 are sequentially connected to the air supply part 140 on one side (left side) with the air supply part 140 therebetween, and on the other side (right side) (160) is connected to the supply unit (140).

The ventilation unit 170 is mounted between the ventilation inlet part 120 and the exhaust part 130 and the air supply unit 180 is installed in the air supply part 140.

A first heat exchanger 200 is installed between the exhaust unit 130 and the air supply unit 140 and a second heat exchanger 300 is installed between the outer unit 160 and the air supply unit 140 .

The first filter 201 may be mounted on the upstream side of the first heat exchanger 200 and the second filter 301 may be mounted on the upstream side of the second heat exchanger 300 . In addition, a humidifier 303 for controlling the humidity of the winter can be installed downstream (behind) the second heat exchanger 300.

According to a preferred embodiment of the present invention, the first heat exchanger 200 is equipped with a sensible heat exchanger having a sensible heat sensation capability with respect to the circulating air CA, and the second heat exchanger 300 is equipped with a latent heat A latent heat exchanger with a high capacity is installed.

The first and second heat exchangers 200 and 300 may be structurally diverse heat exchangers. However, it is preferable to use a coil-tube heat exchanger having hot and cold water as a heating medium that can expect a high passing wind speed.

Hereinafter, the operation of the air conditioner according to the present invention will be described.

The ventilation RA of the room is introduced through the ventilation damper 121 according to the pressure difference caused by the driving force of the ventilation unit 170 and the ventilation RA is distributed through the ventilation unit 170 for ventilation, The exhaust EA is discharged to the outside through the exhaust damper 131 and the remaining vent except for the exhaust EA, that is, the circulating air CA is transferred to the supply unit 140.

At this time, the circulating air CA is transferred to the air supply chamber 150 of the air supply unit 140 while passing pollutants through the first filter 201 and then heat-exchanged through the first heat exchanger 200.

The outdoor air OA flows through the outside air damper 161 in accordance with the pressure difference caused by the driving force of the air supply blowing unit 180 operating in conjunction with the ventilation unit 170 to be fed to the air supply unit 140 do.

At this time, the outside air OA is transferred to the air supply chamber 150 of the air supply unit 140 while passing pollutants through the second filter 301, then exchanging heat through the second heat exchanger 300. In winter, the outside air OA is conveyed to the air supply unit 140 after passing through the humidifier 303 included in the downstream (rear) of the second heat exchanger 300.

On the other hand, the circulating air (CA) generally requires a relatively low calorie amount in comparison with the outside air (OA) in order to reach the set room temperature and humidity of the air conditioner. On the contrary, the outside air (OA) To reach the set room temperature and humidity, a relatively large amount of heat is required.

In consideration of this, the present invention is characterized by using a first heat exchanger 200 designed to mainly recover sensible heat and a second heat exchanger 300 designed to mainly recover latent heat, (CA) and the outside air (OA) are mixed with the air supply chamber (150), and then the thermal compensation is performed again (SA) is supplied to the room, thereby minimizing the total energy consumption through the first and second heat exchangers (200, 300).

Hereinafter, the embodiment will be described in detail.

<Indoor cooling in summer>

The circulating air CA from which the exhaust EA is removed from the ventilation RA passes through the first heat exchanger 200 designed to mainly recover the sensible heat and the circulated air CA passing through the first heat exchanger 200 CA ") is supercooled to a temperature lower than the set room temperature, and is supplied to the air supply chamber 150 while maintaining a humidity at least higher than the set indoor humidity.

On the other hand, the outside air OA passes through a second heat exchanger 300 designed to mainly recover latent heat, and the outside air OA "passing through the second heat exchanger 300 is humidified at a humidity lower than the set indoor humidity, And is supplied to the supply chamber 150 while maintaining a temperature at least higher than the set room temperature.

In this state, when the individual conditioned circulating air CA '' and the outside air OA 'are mixed in the air supply chamber 150 through the first and second heat exchangers 200 and 300 and heat exchanged, And the structure supplied to the room is satisfied.

In other words, the circulated air (CA ") and the outside air (OA") introduced into the separate after-air supply chamber (150) through the first and second heat exchangers (200, 300) The outside air OA "is subjected to the cooling process again. On the other hand, the circulating air CA" is again subjected to a humming process by the relatively humid ambient air OA " .

FIG. 3 shows the load state of the total enthalpy heat exchanger according to the temperature / humidity change of the conditioned air passing through the conventional total enthalpy heat exchanger during the summer indoor cooling. FIG. 4 shows the state of the indoor heat exchanger, FIG. 5 is a view showing a comparison of the load states of the first and second heat exchangers according to the temperature / humidity change of the conditioned air passing through the unit. 3 and FIG. 4,

3B and 4B, the horizontal axis represents humidity (RH) and the vertical axis represents temperature (DB: dry bulb temperature), and the common conditions for comparison are as follows.

- Outdoor (OA) temperature: 30 degrees

- Outdoor (OA) Humidity: 63%

- Circulating air (CA) temperature: 28 degrees

- Circulating air (CA) Humidity: 45%

- Supply (SA) temperature: 20 degrees

- Supply air (SA) Humidity: 68%

Consequently, as shown in FIG. 3 (b) and FIG. 4 (b), in order to maintain the set air temperature SA (20 degrees) / humidity (68% When the first and second heat exchangers 200 and 300 according to the present invention are applied, the power consumption corresponding to a total of 28.4 kW (22 kW + 6.4 kW) is consumed, whereas the power consumption corresponding to a total of 30.4 kW is consumed .

This results in independent heat exchange between the circulating air CA and the outside air OA by the first and second heat exchangers 200 and 300 according to the present invention and the circulation air CA ' It is confirmed that the power consumption of 2 kW is reduced compared with the conventional case by supplying the final room with the mutually thermally compensated state in the supply chamber 150 while mixing in the heat exchanger 150.

The outside air OA passing through the second heat exchanger 300 is supplied to the indoor heat exchanger 300 through the indoor heat exchanger The cooling is performed only to the temperature region higher than the temperature and then the supply air (SA) of the set room temperature is formed as it is mixed in the air supply chamber 150, so that the relative energy saving is expected.

In addition, the outside air OA passing through the second heat exchanger 300 requires additional energy for performing the overdamping so as to maintain the humidity lower than the set indoor humidity. However, the circulating air OA passing through the first heat exchanger Since the air CA is caused to humidify to maintain a humidity higher than the set room humidity and then to form the set air humidity (SA) of the room humidity as it is mixed in the air supply chamber 150, this results in a relative energy saving .

The total amount of energy consumed by the first and second heat exchangers 200 and 300 is reduced while the circulation air CA "passing through the first heat exchanger 200 and the outside air OA passing through the second heat exchanger 300 "Can compensate for the heat quantity by the mutual thermal compensation according to the mixing in the air supply chamber 150, so that the supply air (SA) having reached the set room temperature and room humidity can be supplied to the room, So that it is possible to provide a comfortable supply air (SA).

As described above, the second heat exchanger 300 increases the number of latent heat of the moisture contained in the outside air OA and reduces the heat amount of the air to be heated (sensible heat) Wind speed) can be increased. For example, in the case of the conventional total enthalpy heat exchanger, in order to reduce the pressure loss, it was necessary to maintain a passing wind speed (surface wind speed) of about 2.5 m / s, whereas in the case of the first and second heat exchangers 200 and 300 according to the present invention, It is possible to design to maintain the passing wind speed around 4.0 m / s and the efficiency is expected to increase accordingly.

On the contrary, if the same energy efficiency as the conventional one is realized, the design of the supply unit 160 including the second heat exchanger 300 can be reduced and the cost can be reduced accordingly.

This also applies to the case where the humidifier 303 for the winter season installed downstream (rear) of the second heat exchanger 300 and the second filter 301 having the laminated structure of the elementary and intermediate filters installed upstream (forward) Cost reduction is expected due to reduction in specifications.

<Indoor heating in winter>

The circulating air CA from which the exhaust EA is removed from the ventilation RA passes through the first heat exchanger 200 designed to mainly recover the sensible heat and the circulated air CA passing through the first heat exchanger 200 CA ") is heated to a temperature higher than the set room temperature, and is supplied to the supply chamber 150 while maintaining at least a humidity lower than the set room humidity.

On the other hand, the outside air OA passes through a second heat exchanger 300 designed to mainly recover latent heat. The outside air OA "passing through the second heat exchanger 300 is humidified to a humidity higher than the set indoor humidity, And is supplied to the supply chamber 150 while maintaining at least a temperature lower than the set room temperature.

In this state, when the individual conditioned circulating air CA '' and the outside air OA 'are mixed in the air supply chamber 150 through the first and second heat exchangers 200 and 300 and heat exchanged, And the structure supplied to the room is satisfied.

As described above, during the indoor heating, the opposite process to that during the indoor cooling described above is performed. Hereinafter, the duplicated description related to the same operation and effect is omitted.

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 in the appended claims and their equivalents. Of course, such modifications are within the scope of the claims.

100: air conditioner 120: ventilation inlet
130: exhaust part 140:
150: Supply chamber 160: Outer air introduction part
170: ventilation blowing unit 180: air supply blowing unit
200: first heat exchanger 201: first filter
300: second heat exchanger 301: second filter
303: Humidifier

Claims (6)

delete delete In the ventilation (RA) introduced from the room, some of the exhaust air (EA) is discharged to the outside of the room, and heat exchange is performed with respect to the outside air OA flowing from the outside and the remaining circulating air CA excluding the exhaust air (EA) A method of controlling an air supply (SA)
A first heat exchanger 200 is disposed downstream of the circulating air CA and a second heat exchanger 300 is disposed downstream of the outside air OA. The first heat exchanger 200 and the second heat exchanger (CA ") and the outside air (OA"), which are heat-exchanged with each other by using the heat exchanger (300), in the air supply chamber (150)
In the indoor cooling mode, the circulating air (CA) passes through the first heat exchanger (200), is cooled to a temperature lower than the set indoor temperature, and the humidity higher than the set indoor humidity is maintained. ; The outside air OA passes through the second heat exchanger 300, is humidified at a humidity lower than the set room humidity, is maintained at a temperature higher than the set room temperature, and is supplied to the air supply chamber 150; The circulation air CA "and the outside air OA" are mixed in the air supply chamber 150 through the first and second heat exchangers 200, 300 and exchanged with each other, / RTI &gt;
In the indoor heating, the circulating air CA passes through the first heat exchanger 200, is overheated to a temperature higher than the set indoor temperature, is maintained at a humidity lower than the set indoor humidity, and is supplied to the air supply chamber 150 ; The outside air OA passes through the second heat exchanger 300, is humidified to a humidity higher than the set indoor humidity, is maintained at a temperature lower than the set indoor temperature, and is supplied to the air supply chamber 150; The circulation air CA "and the outside air OA" are mixed in the air supply chamber 150 through the first and second heat exchangers 200, 300 and exchanged with each other, Wherein the air-conditioner is supplied with the air-conditioned air. The method of claim 3,
Wherein the first heat exchanger (200) is a sensible heat exchanger having a large amount of heat recovery in the air;
Wherein the second heat exchanger (300) is a latent heat exchanger having a large amount of heat recovery in the air. delete delete

Images