KR20190128306A - Air-conditioner for building - Google Patents

Abstract

The present invention relates to an air conditioning apparatus for a building, which comprises: a housing (10) including an outside air suction port (11) which introduces outside air (OA), an indoor air supply port (12) supplying heat exchange air (SA) indoors, a ventilation port (13) introducing indoor circulating air (RA), and an exhaust port (14) exhausting exhaust air (EA) outdoors; a supply fan (20) pumping the outside air introduced through the outside air suction port (11) to the indoor air supply portion (12); a return fan (30) pumping the air introduced into the ventilation port (13) to the exhaust port (14); a heat exchanger (40) provided between the outside air suction port (11) and the indoor air supply port (12) in the housing (10), and having main inlet and outlet (41, 42) through which a heat medium passing through an outdoor unit (not shown) flows in and out; a bypass line (50) connecting sub inlet and outlet (43, 44) formed in one side and the other side of the heat exchanger (40); and a circulation pump (60) circulating the heat medium in the heat exchanger (40) through the sub inlet and outlet (43, 44) and the bypass line (50).

Description

Air Conditioning Unit for Large Buildings {AIR-CONDITIONER FOR BUILDING}

The present invention relates to an air conditioning apparatus installed in a large building to harmonize a large amount of air, and more particularly, to an air conditioning apparatus for a large building which can prevent freezing even in winter and enable simple cooling as needed. will be.

In general, the ceilings of large buildings, where many people live for office work, are provided with ducts to supply and intake cooling or heated air. An air conditioning room, which is a separate space, is provided with an air conditioner that cools or heats outside air to supply air to the duct and intakes indoor air circulated through the building.

Such an air conditioner basically includes an outdoor air intake port for sucking outside air (OA), an indoor air supply for supplying heat exchange air (SA) to the interior, a ventilation hole for sucking indoor circulation air (RA), and an exhaust air (EA) outdoors. A supply fan and a return fan are installed in a housing in which an exhaust port for exhausting air is formed, and a heat exchanger in which a heat medium such as water is circulated for cooling and heating is installed between the outside air intake port and the indoor air supply. In this case, the heat exchanger has a structure in which a coil passing through the heated or cooled heating medium is arranged in a zigzag form, and a plurality of heat dissipation fins are installed in the coil to increase heat exchange efficiency with air. Related prior art is disclosed in the name of the building air conditioning system in Patent Publication No. 10-2010-0137715.

On the other hand, when the working hours are over or on weekends or holidays, the air conditioner is stopped to save energy, and in this state, the heat medium does not circulate the heat exchanger.

However, when the air temperature is lowered to subzero weather in the state where the air conditioner is stopped for several days, the heat medium gradually freezes inside the heat exchanger and expands in volume, thereby causing the coil of the heat exchanger to freeze. In this case, the air conditioner is not able to operate normally until the frozen coil is repaired. Heating of the entire building is no longer possible.

The present invention was created in order to meet the necessity as described above, and an object of the present invention is to provide an air conditioning apparatus for a large building which can prevent the heat exchanger from freezing by preventing the heat medium from freezing even when the operation of the outdoor unit is stopped in winter. do.

Another object of the present invention is to provide an air conditioning apparatus for a large building which can cool the heat exchanger even when the outdoor unit is not operated to enable simple cooling.

In order to achieve the above object, the building air conditioner according to the present invention, which is installed in the air conditioning room, the air inlet 11, the air inlet 11, the heat exchange air (SA) to suck the outside air (OA) indoors A housing 10 having an air supply port 12, a ventilation port 13 for sucking the indoor circulation air RA, and an exhaust port 14 for exhausting the exhaust air EA outdoors; A supply fan 20 for pumping outside air introduced through the outside air inlet 11 into the indoor air supply 12; A return fan (30) for pumping air introduced into the ventilation port (13) to the exhaust port (14); The heat exchanger is installed between the outside air intake port 11 and the indoor air supply unit 12 in the housing 10, and the main outlet inlets 41 and 42 are formed to flow in and out of the heat medium via an outdoor unit (not shown). 40; A bypass line 50 connecting the sub outlet ports 43 and 44 formed at one side and the other side of the heat exchanger 40; And a circulation pump 60 for circulating the heat medium in the heat exchanger 40 through the sub outlet ports 43 and 44 and the bypass line 50.

In the present invention, as installed in the bypass line 50, the heat medium further includes a check valve 70 to flow in only one direction in the bypass line (50). At this time, the sub outflow openings 43 and 44 are air vents V and drain lines D installed in the heat exchanger 40.

In the present invention, it is provided in the bypass line 50, and further includes a heat medium temperature variable portion 80 for varying the temperature of the heat medium passing through the bypass line (50).

In the present invention, the heat medium temperature variable part 80 is installed outside the housing 10 and connected to the bypass line 50, and a flow path 81a through which the heat medium passes through is formed. A conduction bracket 81; A plurality of thermoelectric elements 82 having one side in close contact with the conductive bracket 81; A heat dissipation block (83) having a plurality of heat dissipation fins (83a) formed to be in close contact with the other side of the plurality of thermoelectric elements (82); And a heat dissipation fan 84 installed in the heat dissipation block 83 to circulate outside air for heat dissipation between the heat dissipation fins 83a.

In the present invention, it further comprises an operation control unit 90 for generating an operation signal for operating the circulation pump 60 and the heat medium temperature variable portion 80. At this time, the operation control unit 90, which is installed in the main inlet 41, the heat medium temperature sensor 91 for measuring the temperature of the heat medium to generate a corresponding heat medium temperature signal; It is installed in the main outlet 42, the heat medium flow sensor 92 for detecting the flow of the heat medium circulating to the outdoor unit and generates a flow signal corresponding thereto; It is installed on the outside of the housing 10, the outside temperature measuring sensor 93 for measuring the outside temperature to generate a corresponding outside temperature signal; includes.

According to the present invention, by adopting the bypass line 50, the circulation pump 60 and the check valve 70, the heat medium in the heat exchanger 40 in the state in which the operation of the outdoor unit is stopped in winter, the heat medium The freezing of the heat exchanger can be prevented.

In addition, since the heat medium temperature variable part 80 can apply thermal energy to the heat medium, even if a cold wave of 10 to 20 kPa occurs suddenly, the heat medium circulating in the heat exchanger 40 can be prevented from freezing, and any cold environment In this case, it is possible to prevent freezing of the heat exchanger 40.

In addition, the heat medium temperature variable part 80 can enable simple cooling even when the outdoor unit is not in operation, and furthermore, can further cool the heat exchanger 40 when the outdoor unit is in operation to enable so-called turbo cooling. can do.

And, by the operation control unit 90, there is an action and effect that the outdoor pump can be stopped and the heat medium freezes, and the circulation pump 60 and the heat medium temperature variable part 80 can be operated correctly.

1 is a view for explaining the configuration of a large building air conditioning apparatus according to the present invention,
2 is a view showing an extract of a bypass line, a circulation pump and a check valve connected to the heat exchanger of FIG. 1;
3 is a front view of FIG. 2;
4 is a view for explaining that the heat medium temperature variable part and the operation control part are installed in the air conditioner of FIG. 1;
5 is a view for explaining the configuration of the heat medium temperature variable part of FIG.
6 is a block diagram illustrating a configuration of an operation control unit of FIG. 4.

Hereinafter, an air conditioning apparatus for a large building according to the present invention will be described in detail with reference to the accompanying drawings.

1 is a view for explaining the configuration of the air conditioner for a large building according to the present invention, Figure 2 is a view showing a bypass line, a circulation pump and a check valve connected to the heat exchanger of Figure 1, Figure 3 Is a front view of FIG. 2.

As shown, the large building air conditioner according to the present invention, which is installed in the air conditioning room, the outdoor air inlet 11, the air inlet 11 to suck the outside air (OA), the indoor air supply for supplying the heat exchange air (SA) to the room ( 12) a housing 10 in which a vent port 13 for sucking indoor circulating air RA and an exhaust port 14 for exhausting the exhaust air EA are formed; A supply fan 20 installed between the outside air inlet 11 and the indoor air supply 12 in the housing 10 and for feeding air air introduced through the outside air intake 11 into the indoor air supply 12; ; A return fan 30 installed between the ventilation port 13 and the exhaust port 14 in the housing 10 to pump air introduced into the ventilation port 13 into the exhaust port 14; The heat exchanger is installed between the outside air intake port 11 and the indoor air supply unit 12 in the housing 10, and includes a main outlet inlet 41 and 42 through which an outdoor medium (not shown) flows in and out. 40); A bypass line 50 connecting the sub outlet ports 43 and 44 formed at one side and the other side of the heat exchanger 40; A circulation pump (60) installed in the bypass line (50) for circulating the heat medium in the heat exchanger (40) through the sub outlet (43) (44) and the bypass line (50); It is installed in the bypass line 50, the heat medium is a check valve 70 to flow in only one direction in the bypass line 50; includes.

The housing 10, the supply fan 20, the return fan 30, and the heat exchanger 40 are basic components of an air conditioner installed and operated in a building air conditioning room.

The main outlet inlets 41 and 42 of the heat exchanger 40 are connected to a heat medium line (not shown) connected to an outdoor unit (not shown) installed outside, and the heat medium is a main outlet inlet 41 and 42. Through the circulation between the outdoor unit and the heat exchanger (40). The outdoor unit cools or heats the air passing through the heat exchanger 40 by heating or cooling the heat medium, and uses water as the heat medium that enables this.

The bypass line 50 is for causing the heat medium to circulate in the heat exchanger 40 when the operation of the outdoor unit is stopped, and as illustrated in FIGS. 2 and 3, the sub outlet ports 43 and 44. The bypass line is formed so that the heat medium flows in and out.

Here, the sub outflow openings 43 and 44 may be formed separately in the heat exchanger 40, but may be an air vent V and a drain line D installed in the heat exchanger. In this case, the heat exchanger 40 does not have to be structurally changed in order to connect the bypass line 50.

The circulation pump 60 is installed in the bypass line 50 to pressurize the heat medium in one direction so that the heat medium circulates in the heat exchanger 40.

The check valve 70 is installed in the bypass line 50 to flow the heat medium only in one direction. When the heat medium circulates between the outdoor unit and the main outlet inlets 41 and 42, the heat medium circulated is bypassed. Do not enter the line 50. By this check valve 70, when the heat medium circulates between the outdoor unit and the heat exchanger 40, a part of the heat medium is prevented from being diverted to the bypass line 50.

By adopting the bypass line 50, the circulation pump 60 and the check valve 70, the heat medium is circulated in the heat exchanger 40 in the state in which the operation of the outdoor unit is stopped in winter so that the heat medium does not freeze, As a result, freezing of the heat exchanger can be prevented.

FIG. 4 is a view for explaining that the heat medium temperature variable part and the operation control part are installed in the air conditioner of FIG. 1, FIG. 5 is a view for explaining the configuration of the heat medium temperature variable part of FIG. 4, and FIG. It is a figure for demonstrating the structure of an operation control part.

 The air conditioning apparatus for building according to the present invention, which is installed in the bypass line 50, heat medium temperature variable portion 80 for varying the temperature of the heat medium passing through the bypass line 50; And an operation control unit 90 generating an operation signal for operating the circulation pump 60 and the heat medium temperature variable unit 80.

The heat medium temperature variable part 80 applies thermal energy to the heat medium via the bypass line 50 when the outside temperature is lowered to below zero, thereby bringing the temperature of the heat medium close to the room temperature or room temperature. The heat medium temperature variable part 80 applies heat energy so that the heat medium does not freeze when the outdoor unit stops operating and the heat medium does not circulate between the outdoor unit and the heat exchanger 40, and when the outdoor temperature is lowered to below zero. .

On the other hand, the heat medium temperature variable portion 80, when the outdoor air temperature suddenly rises in the season when the outdoor unit does not operate the formal, can be made simple heating by cooling the heat medium circulating inside the heat exchanger 40 as needed. have.

To this end, the heat medium temperature variable portion 80, as shown in Figure 5, is installed on the outside of the housing 10 is connected to the bypass line 50, the flow path 81a through the heat medium therein Is formed conduction bracket 81; A plurality of thermoelectric elements 82, one side of which is in close contact with the conduction bracket 81; The other side of the plurality of thermoelectric elements 82 is in close contact, the heat dissipation block 83 is formed with a plurality of heat dissipation fins (83a); And a heat dissipation fan 84 installed in the heat dissipation block 83 to circulate outside air for heat dissipation between the heat dissipation fins 83a.

The flow path 81a formed inside the conduction bracket has a plurality of branches in the conduction bracket 81 so that heat of the heat medium flowing in and out through the bypass pine 50 is effectively conducted to the conduction bracket 81. .

The thermoelectric element 82 is heated on one side while the other side is heated by the direction of the applied current. The thermoelectric element 82 heats or cools the conductive bracket 81 in close contact with one side, and cools or heats the heat dissipation block 83 in close contact with the other side.

The heat dissipation block 83 heats the heat applied through the conductive bracket 81 to the outside, thereby allowing the conductive bracket 81 to be cooled.

The heat dissipation fan 84 circulates the outside air with the heat dissipation fins 83a to increase the heat dissipation efficiency of the heat dissipation block 83.

By the heat medium temperature variable part 80, thermal energy can be applied to the heat medium via the flow path 81a of the conduction bracket 81, so that even if a cold wave of 10 to 20 kPa is generated suddenly, The circulating heat medium can be prevented from freezing, and freezing of the heat exchanger 40 can be prevented in any cold environment.

In addition, since the heat exchanger 40 can be cooled independently of the outdoor unit in the summer season, the air conditioner can be simply cooled while the outdoor unit is not operating, and further, the heat exchanger 40 can be further cooled when the outdoor unit is operated. It is possible to enable so-called turbo cooling.

The operation control unit 90 generates an operation signal for operating the circulation pump 60 and the heat medium temperature variable unit 80. The operation control unit 90, which is installed at the main inlet 41, measures the temperature of the heat medium and generates a heat medium temperature signal corresponding to the heat medium temperature sensor 91; It is installed in the main outlet 42, the heat medium flow sensor 92 for detecting the flow of the heat medium circulating to the outdoor unit and generates a flow signal corresponding thereto; It is installed on the outside of the housing 10, the outside temperature measuring sensor 93 for measuring the outside temperature to generate a corresponding outside temperature signal; includes.

The heat medium temperature sensor 91 detects the heat medium temperature at the main inlet 41 according to the heat medium temperature signal generated; The heat medium flow sensor 92 detects whether the heat medium is circulated between the heat exchanger 40 and the outdoor unit according to the generated flow signal, that is, whether the air conditioner is in operation; The outside temperature sensor 93 detects whether the outside temperature of the housing 10 is the temperature of the heat medium, that is, the temperature below zero according to the generated outside temperature signal.

By this operation control unit 90, the heat medium flow sensor 92 detects that the heat medium is not circulated between the heat exchanger 40 and the outdoor unit (A condition), and the outside temperature measuring sensor 93 is Detects below zero (B condition), when the thermal medium temperature sensor 91 detects that the temperature of the thermal medium is below zero (C condition), generates an operation signal for operating the circulation pump (60).

And when any of the conditions A, B, C deviate from the condition, that is, when the heat medium is circulated between the heat exchanger 40 and the outdoor unit, the heat medium does not freeze, so it is out of the A condition. When the ambient temperature is room temperature, the heat medium does not freeze, so it is out of condition B. When the heat medium temperature is room temperature, it does not freeze.

By this automatic control unit 90, it is possible to operate the circulation pump 60 and the heat medium temperature variable part 80 accurately in an environment in which the outdoor unit is stopped and the heat medium is frozen.

As described above, according to the present invention, by adopting the bypass line 50, the circulation pump 60 and the check valve 70, the heat medium circulates in the heat exchanger 40 in the state in which the operation of the outdoor unit is stopped in winter. It is possible to prevent the heat medium from freezing, thereby preventing freezing of the heat exchanger.

In addition, since the heat medium temperature variable part 80 can apply thermal energy to the heat medium, even if a cold wave of 10 to 20 kPa occurs suddenly, the heat medium circulating in the heat exchanger 40 can be prevented from freezing, and any cold environment In this case, it is possible to prevent freezing of the heat exchanger 40.

In addition, the heat medium temperature variable part 80 can enable simple cooling even when the outdoor unit is not in operation, and furthermore, can further cool the heat exchanger 40 when the outdoor unit is in operation to enable so-called turbo cooling. can do.

And by the automatic control unit 90, it is possible to accurately operate the circulation pump 60 and the heat medium temperature variable part 80 in an environment in which the outdoor unit is stopped and the heat medium is frozen.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible.

10 ... housing 11 ... air intake
12 ... Indoor air supply 13 ... Ventilation openings
14 ... vent 20 ... supply fan
30 ... return fan 40 ... heat exchanger
41, 42 ... main outlet 43,44 ... sub outlet
50 ... bypass line 60 ... circulation pump
70 ... check valve 80 ... heat medium temperature variable part
81 ... conduction bracket 81a ... Euro
82 ... thermoelectric element 83 ... heat dissipation block
83a ... heat sink fins 84 ... heat sink
90 ... operation control part 91 ... heat medium temperature sensor
92 ... thermal fluid flow sensor 93 ... ambient temperature sensor

Claims (7)

As installed in the air conditioning chamber, an outdoor air suction port 11 for sucking outside air (OA), an indoor air supply unit 12 for supplying heat exchange air (SA) to the room, and a ventilation hole (13) for sucking indoor circulation air (RA) And a housing 10 having an exhaust port 14 for exhausting the exhaust air EA to the outside.
A supply fan 20 for pumping outside air introduced through the outside air inlet 11 into the indoor air supply 12;
A return fan (30) for pumping air introduced into the ventilation port (13) to the exhaust port (14);
The heat exchanger is installed between the outside air suction port 11 and the indoor air supply unit 12 in the housing 10, and the main outlet inlets 41 and 42 through which an outdoor medium (not shown) flows in and out. 40;
A bypass line 50 connecting the sub outlet ports 43 and 44 formed at one side and the other side of the heat exchanger 40; And
And a circulation pump (60) for circulating the heat medium in the heat exchanger (40) through the sub outlet (43) (44) and the bypass line (50). . The method of claim 1,
As installed in the bypass line (50), the air conditioning apparatus for a large building, characterized in that it further comprises a check valve (70) for allowing the heat medium to flow only in one direction in the bypass line (50). The method of claim 1,
The sub outflow opening (43) (44) is a large building air conditioning apparatus, characterized in that the air vent (V) and drain line (D) pre-installed in the heat exchanger (40). The method of claim 1,
As installed in the bypass line 50, the air conditioning apparatus for a large building, characterized in that it further comprises a heat medium temperature variable portion 80 for varying the temperature of the heat medium passing through the bypass line (50). The method of claim 4, wherein the heat medium temperature variable portion 80,
A conduction bracket 81 installed outside the housing 10 and connected to the bypass line 50 and having a flow path 81a formed therein through the heat medium;
A plurality of thermoelectric elements 82, one side of which is in close contact with the conductive bracket 81;
A heat dissipation block 83 having a plurality of heat dissipation fins 83a formed to be in close contact with the other side of the plurality of thermoelectric elements 82;
And a heat dissipation fan (84) installed in the heat dissipation block (83) to circulate outside air for heat dissipation between the heat dissipation fins (83a). The method of claim 1,
Air conditioning device for a large building, characterized in that it further comprises an operation control unit (90) for generating an operation signal for operating the circulation pump (60) and the heat medium temperature variable unit (80). The method of claim 6, wherein the operation control unit 90,
A heat medium temperature sensor 91 which is installed at the main inlet 41 and measures a temperature of the heat medium to generate a corresponding heat medium temperature signal;
It is installed in the main outlet 42, the heat medium flow sensor 92 for detecting the flow of the heat medium circulating to the outdoor unit and generates a flow signal corresponding thereto;
It is installed on the outside of the housing 10, the outside air temperature measuring sensor (93) for generating a corresponding outside temperature signal by measuring the outside air temperature; a large building air conditioning apparatus comprising a.

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