KR20100128956A - Air conditioner - Google Patents

Abstract

PURPOSE: An air conditioner is provided to reduce power consumption by powering parts of compressors when a load is low and by simultaneously powering compressors when a load is high. CONSTITUTION: An air conditioner comprises air handling units(1,2) and multiple chillers(3). Each air handling unit has a chilled water coil and a ventilation fan. The ventilation fan discharges indoor air inside through the chilled water coil. An evaporator supplies chilled water to the chilled water coil. The chillers are connected to each other in a raw.

Description

Air Conditioner

The present invention relates to an air conditioner, and more particularly, to an air conditioner in which a plurality of compressors are driven alone / simultaneously according to a load.

In general, an air conditioner is a device for cooling and cooling an indoor room by using a refrigeration cycle of refrigerant consisting of a compressor, a condenser, an expansion device, and an evaporator to create a more comfortable indoor environment for a user.

The air conditioner is configured such that the evaporator heat exchanges the water and the refrigerant, and is provided with a separate cold water coil through which the heat exchanged with the refrigerant passes, and when the blower circulates the indoor air to the cold water coil, Can cool the room.

When the compressor is turned on during its operation and the compressor is turned off when the compressor is stopped, the air conditioner cools the room while cooling the air when the compressor is turned on. When a plurality of compressors are installed, efficient operation is required according to the load.

The present invention is to provide an air conditioner that minimizes the number of operation of the compressor when the load is small, and drives the compressor with the same capacity when the load is large.

According to an aspect of the present invention, there is provided an air conditioner including: an air handling unit having a cold water coil and a blowing fan configured to discharge indoor air after passing indoor air through the cold water coil; A chiller having a refrigeration cycle of a compressor, a condenser, an expansion mechanism, and an evaporator, wherein the evaporator includes a chiller for supplying cold water to the cold water coil, wherein the chillers are connected in parallel, and the chillers are under a set value; Some of the compressors of the plurality of chillers are driven corresponding to the load, and the remaining compressors of the plurality of chillers are stopped, and when the load exceeds the set value, the compressors of the plurality of chillers are driven together at the same capacity.

 The air conditioner determines a load according to an operation unit for setting a set temperature, a load sensor for detecting the load, and a detection result of an operation of the operation unit and a load detection sensor, and the compressor of the plurality of chillers according to the determined load. The chiller control unit for controlling the.

The load sensor includes a water extraction temperature sensor for detecting the water exit temperature of the plurality of chillers.

 The operation unit includes a water extraction temperature setting unit for adjusting the desired water extraction temperature of the plurality of chillers.

The chiller controller determines a load based on a difference between a desired water outlet temperature set by the water outlet temperature setting unit and a temperature detected by the water outlet temperature sensor.

An air conditioner according to the present invention comprises: an air handling unit having a cold water coil and a blowing fan configured to discharge indoor air after passing indoor air through the cold water coil; A plurality of refrigeration cycles of a compressor, a condenser, an expansion mechanism, and an evaporator; wherein the evaporator of the plurality of refrigeration cycles includes a chiller for supplying cold water to the cold water coil; When the compressor of the refrigeration cycle is driven corresponding to the load and the compressor of the remaining refrigeration cycle is stopped, and the load exceeds the set value, the compressors of the plurality of refrigeration cycles are driven together at the same operation capacity.

 The air conditioner includes an operation unit for setting a set temperature, a load sensor for sensing the load, and a control unit for controlling the compressors of the plurality of refrigeration cycles according to a result of the operation of the operation unit and the detection of the load sensor. .

The load sensor includes a water extraction temperature sensor for detecting the water extraction temperature of the chiller.

 The operation unit includes a water extraction temperature setting unit for adjusting the desired water extraction temperature of the chiller.

The controller detects a load by a difference between a desired water outlet temperature set by the water outlet temperature setting unit and a temperature detected by the water outlet temperature sensor.

The operation portion includes a setting value variable portion for varying the set value.

The compressor is a multistage compression screw compressor.

According to the present invention configured as described above, when the load is small, only a part of the plurality of compressors are driven to reduce power consumption, and when the load is large, the plurality of compressors are driven at the same capacity to load the compressor by a refrigeration cycle high / low pressure difference. Minimizing the increase has the advantage that the power consumption is reduced and the efficiency is high.

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

1 is a schematic diagram of an embodiment of an air conditioner according to the present invention.

The air conditioner according to the present embodiment includes an air handling unit (1) (2) and a plurality of chillers (3) (4), the air handling unit (1) (2) and a plurality of chillers (3) ( 4) is connected to the water pipe (6).

The air handling unit (1) (2) is an air conditioning unit that sucks and heats indoor air, and then discharges it into the room.

When the air handling unit (1) (2) is configured as a combined air-conditioning unit, the air handling unit (1) and (2) suck in indoor air (I) and outdoor air (O), and discharge some of the sucked indoor air to the outside, and discharge the remaining indoor air to outdoor air. And the mixture air is heat-exchanged in the cold water coil and then supplied to the room, and when configured as a non-ventilating air conditioning unit, the indoor air (I) is sucked and heat-exchanged in the cold water coil and then supplied to the room.

The air handling unit (1) (2) includes a cold water coil having a water passage through which water passes, and a blower fan that circulates and blows a mixture of indoor air and outdoor air or indoor air to the cold water coil.

When the air handling unit (1) (2) is configured as a combined air conditioning unit, the air handling unit (1) or (2) is installed in an air conditioning room or a machine room provided separately from the room to which the air handling unit (1) (2) is air conditioned in a building or a house where an air conditioner is installed. Is installed on.

When the air handling unit (1) (2) is configured as a non-ventilating air conditioning unit, the air handling unit (1) (2) is installed in a room where the air handling unit (1) (2) is air-conditioned, and directly sucks the indoor air to heat exchange in a cold water coil to the room The fan coil unit (FCU: Fan Coil Unit) to discharge directly.

Air handling unit (1) (2) is composed of a plurality, such as chiller (3) (4), the cold water supplied from the plurality of chiller (3) (4) is dispersed into a plurality of air handling unit (1) (2) It is also possible to supply, cold water supplied from a plurality of chillers (3) (4) consisting of a single number can also be supplied by combining a single number of air handling units.

When the air handling unit (1) (2) is made up of a plurality of, each of them can be air-conditioned each room, a plurality can be air-conditioned one room, a plurality of air handling (1) (2) ) Will be described as being connected to a plurality of chillers (3) (4) and the water pipe (6).

The chiller (3) (4) is a kind of cold water supply unit for supplying cold water to the cold water coil of the air handling unit (1) (2) by using a refrigeration cycle consisting of a compressor, a condenser, an expansion mechanism, and an evaporator. If it is installed outdoors, and the outdoor fan to supply the outdoor air to the chiller (3) (4) inside, and the condenser is water-cooled, it is installed in the machine room such as the basement or outdoors, and supply the cold water to the condenser The cooling tower 5 is connected to the cooling water pipe 5 ', and a cooling water pump 5 " is installed in the cooling water pipe 5' to allow the cooling water to circulate the cooling tower 5 and the condenser.

The coolant pump 5 ″ is connected to and controlled by one of the air handling unit control units 13 and 14 and the chiller control unit 16 and 17 which will be described later.

On the other hand, the water pipe (6) connecting the air handling unit (1) (2) and the chiller (3) (4) is a common water pipe (7), a common water pipe (7) and a plurality of chillers (3) ( 4) air handling unit connection pipes 11 and 12 connecting chiller connection water pipes 8 and 9 to connect the common water pipes 6 and at least one air handling unit 1 and 2 to connect the chiller connection water pipes 8 and 9; It includes.

The water pipe (6) is a common water pipe (7), chiller connection water pipe (8) (9) and air handling unit connection pipe (11, 12), respectively, the cold water of the chiller (3) (4) air handling unit (1) (2) and a supply water pipe which the cold water which has passed through the air handling unit (1) (2) is recovered to the chiller (3) (4).

On the other hand, the air handling unit (1) (2) includes an air handling unit control unit (13) and (14) for controlling a blowing fan or the like which is an electric component disposed therein, and the air handling unit (1) (2) In the case of a plurality of air handling units, the air handling unit control units 13 and 14 of each air handling unit 1 and 2 are connected to the communication line 15.

The plurality of chillers (3) (4) includes a chiller control unit (16) (17) for controlling a compressor or the like, one of the plurality of chillers (3) (4), the chiller control unit 16 is an air handling unit (1) (2) is connected to the air handling unit control unit 13 and the communication line 19, each chiller (3) (4) is each chiller control unit so that any one chiller sends a driving command to the other chiller (16) and (17) are connected to the communication line (20).

For example, the air handling unit 1, 2 consists of a first air handling unit 1 and a second air handling unit 2, and the chillers 3, 4 are connected to the first chiller 3. When composed of the second chiller 4, the air handling unit control unit 13, 14 of each of the first air handling unit 1 and the second air handling unit 2 is connected by a communication line 15, The air handling unit control unit 13 of any one of the first air handling unit 1 and the second air handling unit 2 includes the chiller control unit of the first chiller 3 among the first and second chillers 3 and 4. 16 is connected to the communication line 19, the chiller control unit 16 of the first chiller (3) and the chiller control unit 17 of the second chiller (4) is the first chiller (3) is the second chiller (4) It is connected to the communication line 20 to input a driving command to.

2 is a cross-sectional view of the air handling unit shown in FIG. 1.

The air handling unit (1) (2) has a space therein, and the indoor air inlet 22A, the indoor air outlet 22B, the outdoor air inlet 22C, and the air conditioning air outlet 22D The formed air handling unit case 22, the blowing fans 27 and 28 installed inside the air handling unit case 22 to flow outdoor air and indoor air, and the inside of the air handling unit case 22. It includes a cold water coil (40) installed to exchange heat with the cold water air flowing toward the air conditioning air outlet (22D).

The air handling unit (1) (2) has a ventilation duct (22E) which communicates the indoor and indoor air intakes (22A) so that indoor air is sucked into the air handling unit case (22) through the indoor air intakes (22A). Is connected, and the exhaust duct 22F which communicates the outdoor air outlet 22B and the outside is discharged so that some of the air sucked into the air handling unit case 22 through the indoor air inlet 22A is discharged to the outside. Connected to the outside air duct 22G, which communicates the outdoor and outdoor air intakes 22C so that outdoor air is sucked into the air handling unit case 22 through the outdoor air intakes 22C, and the air handling is connected. The air-conditioning air discharge part 22D and the air supply duct 22H which communicate with the room are connected so that the air-conditioned air inside the unit case 22 may be supplied to the room.

The ventilation duct 22E is connected to the indoor air intake 22A, the exhaust duct 22F is connected to the indoor air outlet 22B, the outdoor air duct 22G is connected to the outdoor air intake 22C, , The air supply duct 22H is connected to the air conditioning air outlet 22D.

In the air handling unit (1) (2), some of the indoor air sucked into the indoor air intake unit 22A is exhausted to the outside through the indoor air outlet 22B, and the other is sucked into the outside air intake unit 22C. And the mixed air is heat-exchanged with the cold water coil 40 and then supplied to the room through the air conditioning air outlet 22D and the air supply duct 22H. 40) A mixing chamber (26) in which indoor air and outdoor air are mixed is located.

The blowing fans 27 and 28 are positioned between the indoor air inlet 22A and the indoor air outlet 22B in the direction of the flow of the indoor air, and blow the indoor air into the air handling unit case 22 for blowing. Air conditioner air outlet 22D after being located between the cold water coil 40 and the air-conditioning air outlet 22D in the flow direction of the mixed air, and returning the mixed air to the cold water coil 40 ) And a supply fan 28 for blowing air toward ().

Blowing fan (27, 28) is a flow rate variable blowing fan to adjust the flow rate, the housing 32 is formed with an air inlet 30 and the air outlet 31 surrounding the blower 29, the blower 29 And a blower drive source 33 for rotating the blower 29.

The blower drive source 33 may be made of a motor having a rotational shaft connected to the rotational center of the blower 29. The blower driving source 33 may be a shaft 34 connected to the rotational center of the blower 29 and a motor installed to be located outside the housing 32. And a power transmission member including a drive pulley 36 for connecting the driving force of the motor 35 to the shaft, and a belt 37 and a driven pulley 38.

The motor 35 is composed of an inverter motor whose wind speed is variable.

The cold water coil 40 is a kind of cooling coil in which the mixed air and the cold water exchange heat to cool the mixed air. The cold water coil 40 has a cold water coil having a flow path through which the cold water passes, and is provided between the mixing chamber 26 and the supply fan 27. It is installed to be located.

The cold water coil 40 is connected to a water pipe 6, in particular an air handling unit connection pipe 11, 12.

The air handling unit 1 includes dampers 43, 44, 45 for adjusting the ratio of indoor air and outdoor air in the mixed air.

The dampers 43, 44, and 45 are installed at the indoor air outlet 22B to control the indoor air exhaust amount, and the outdoor air intake 22C to adjust the outdoor air intake. The outdoor air damper 44 and the mixing damper 45 installed in the mixing chamber 26 to adjust the amount of air sucked into the mixing chamber 26 in the indoor air.

3 is a schematic configuration diagram of a chiller illustrated in FIG. 1.

The chillers 3 and 4 have a compressor 51 for compressing the refrigerant, a condenser 52 for condensing the refrigerant compressed by the compressor 51, and an expansion mechanism 53 for expanding the refrigerant condensed in the condenser 52. And an evaporator 54 in which the refrigerant expanded in the expansion mechanism 53 exchanges heat with water and evaporates. The compressor 51, the condenser 52, the expansion mechanism 53, and the evaporator 54 include refrigerant piping. Connected to form a refrigeration cycle.

In the chiller, a compressor 51, a condenser 52, an expansion mechanism 53, and an evaporator 54 are installed in a case (not shown) and are integrated into one unit.

Compressor 51 is composed of a variable capacity compressor that can vary the operating capacity, consisting of a plurality of compressors that are partially or fully driven in accordance with the load, or consists of an inverter compressor whose capacity is variable according to the input frequency, or refrigerant by It consists of a screw compressor etc. whose capacity is changed by a pass, and it demonstrates that it consists of a screw compressor below.

The screw compressor is a rotary displacement compressor which is provided with a bypass flow path through which a gas refrigerant is compressed between a pair of male and female screw rotors engaged with each other, a bearing supports the rotor shaft of the screw rotor, and the refrigerant is bypassed. The capacity is adjusted by the bypass amount.

The screw compressor consists of a screw compressor in multistage compression, which is multi-stage compressed to 25%, 50% and 75% and 100%.

The screw compressor is provided with a bypass valve in the bypass flow path, so that the bypass valve regulates the amount of refrigerant bypassed through the bypass flow path, and thus the compression capacity is determined.

The condenser 52 allows the refrigerant to be condensed by the cooling water supplied from the cooling tower 5 shown in FIG. 1, and is formed outside the plurality of inner tubes and a plurality of inner tubes through which water passes and has a water flow path. A coolant pipe 5 'shown in FIG. 1 is connected to the inner tube, the shell including a shell having a coolant passage through which a coolant passes.

That is, the condenser 52 condenses the refrigerant compressed in the compressor 51 when the cooling water cooled in the cooling tower 5 flows into the condenser 52 when the cooling water pump 5 ″ of FIG. 1 is driven. After circulating to the cooling tower 5, the refrigerant is moved to the expansion mechanism 53 in a condensed state.

The expansion mechanism 53 consists of a capillary tube or electronic expansion valves (EEV).

The evaporator 54 is a cooler that cools water as the refrigerant expanded in the expansion mechanism 53 evaporates. The evaporator 54 is formed with a refrigerant passage through which the refrigerant passes and a water passage through which the water passes.

The evaporator 54 includes a inner tube having a plurality of inner tubes through which water passes and having a water passage, and a shell having a refrigerant passage formed outside the plurality of inner tubes and through which the refrigerant passes. 1 is connected to the water pipe 6, in particular the chiller connection water pipe 8, 9.

That is, the evaporator 54 is supplied to the air handling units 1 and 2 through the water pipe 6 shown in FIG. 1 by cold water cooled by the refrigerant to circulate the evaporator 54 after cooling the indoor air. The refrigerant is moved to the compressor 51 in the evaporated state.

Evaporator 54 is a refrigerant is filled between the inner tube and the shell, the oil is located on the upper surface of the liquid refrigerant, the oil through the oil return flow path 56 connecting the evaporator 54 and the compressor 51 Recovered to (51).

The oil return flow path 56 is provided with a capillary tube and an electromagnetic expansion valve.

The air conditioner according to the present embodiment is provided with a cold water pump 58 for pumping cold water circulated in the water pipe (6).

The cold water pump 58 may be installed at a portion of the water pipe 6 located inside the air handling unit 1, 2, or may be installed at a portion located inside the chiller 3, 4. It is also possible to be installed in the portion located between the air handling unit (1) (2) and the chiller (3) (4), the air handling unit (1) (2) to facilitate the control or wire connection, etc. It is preferably installed to be located inside or inside the chiller (3) (4).

On the other hand, the plurality of chillers (3) (4) is determined by the number of operation of the bar, if the load is less than the set value, the part (3) is operated in correspondence to the load and the rest is stopped, the load is more than the set value In this case, the plurality of chillers 3 and 4 are driven together at the same operating capacity.

4 is a control block diagram of an embodiment of an air conditioner according to the present invention.

The air conditioner according to the present embodiment is a load detection for sensing the load of the operation unit 60 and the air conditioner, in particular the chiller (3) (4) for setting the set temperature by the consumer or manager (hereinafter referred to as a consumer, etc.) Sensor 62. And a chiller control part installed in a part 3 of the plurality of chillers 3 and 4 is part of the plurality of chillers 3 and 4 according to the operation of the operation unit 60 and the detection result of the load sensing sensor 14. The chiller control unit which functions as the main control unit 16 for controlling (3) and which is installed in the remaining 4 of the plurality of chillers 3 and 4 is controlled by the main control unit 16. It functions as the sub control part 17 which controls).

The operation unit 60 is installed in one of the plurality of air handling units 1, 2 and the plurality of chillers 3, 4, or the plurality of air handling units 1, 2, and the plurality of chillers 3. Apart from (4), it is installed indoors.

The operation unit 60 has a desired temperature setting unit for adjusting a desired temperature of the room by a consumer or the like, or has a discharge water temperature setting unit for adjusting a desired discharge water temperature of cold water.

The operation unit 60 further includes a set value varying unit for varying a set value for determining the driving of the compressor according to the load.

The load sensor 62 is installed in the air handling units 1 and 2 to detect a temperature of the indoor air I sucked in the room, and a cooling tower 5 and a chiller 3 and 4. It is installed in the cooling water pipe (5 ') between the cooling water temperature sensor for detecting the temperature of the cooling water, and the water pipe (6) connecting the air handling unit (1) (2) and chiller (3) (4) The chiller (3) (4) is made of at least one of the exit temperature sensor for sensing the temperature of the cold water exited.

The water exit temperature sensor is connected to at least one of the air handling unit control unit 13, 14 and the chiller control unit 16, 17 by a signal line and outputs the detected temperature value.

The water exit temperature sensor detects the temperature of the cold water supplied to the air handling units 1 and 2 after flowing out of the chiller 3 and 4, and the water supply pipe of the water supply pipe 6 shown in FIG. Installed in the common water pipe 7 or installed in the chiller connection water pipes 8 and 9, respectively, and will be described below in the common water pipe 7.

The main controller 16 detects the load by the difference between the temperature set by the operation unit 60 and the temperature detected by the water extraction temperature sensor.

For example, if the temperature difference detected from the temperature set in the operation unit 60 and the water output temperature sensor is 10 ℃ or more, 100% load detection, if less than 10 ℃ 7 ℃ or less, 75% load, less than 7 ℃ If it is 4 ℃ or more, it is sensed as a 50 ℃ load, and if it is less than 4 ℃, it is sensed as a 25% load.

The main control unit 16 compares the size of the load with the set value, and operates only the chiller 3 on which the main control unit 16 is installed, or the chiller 3 and the auxiliary control unit 17 on which the main control unit 16 is installed. It is determined whether the chillers 4 will be operated together at the same capacity.

When the size of the load is less than or equal to the set value, the main controller 16 drives the compressor 51 of the chiller 3 in which the main controller 16 is installed to correspond to the load so as to reduce power consumption. , The compressor 51 and the auxiliary control unit 17 of the chiller 3 in which the main control unit 16 is installed so that the load increase of the compressor 51 due to the refrigeration cycle high / low pressure difference of each of the chiller 3 and 4 is minimized. The compressor 51 of the chiller 4 is installed together to drive the same capacity.

For example, the set value may be set to 50%, may be set to 75%, and will be described below as set to 50%.

Table 1 shows an example in which the set value is set to 50% and a plurality of chillers are operated according to the detected load.

Sensing Load  Compressor of the first chiller  2nd chiller compressor 100% 100% 100% 75% 75% 75% 50% 100% 0% 25% 50% 0%

That is, when the set value is 50% and the detected load is 50%, the main control unit 16 drives the compressor 51 of the chiller 3 (first chiller) in which the main control unit 16 is installed and the auxiliary control unit. (17) does not output the operation signal to the other chiller (4, the second chiller), at this time, the compressor 51 of the chiller (3) in which the main control unit 16 is installed 100 so as to correspond to all the detected load alone 100 Driven at% capacity.

If the sensing load is less than or equal to the set value of 50%, the compressor of one of the chillers 3 and 4 is driven at 75% while all of the chillers 3 and 4 are operated together. When the compressor of the chiller 4 is driven at 25%, or when the compressor of one chiller 3 is driven at 50% and the compressor of the other chiller 4 is driven at 50%, a plurality of chillers 3, 4 ) Can respond to the sense load. However, in this case, since the refrigerant is bypassed in all the compressors 51 installed in the chillers 3 and 4, power consumption is supplied to the compressors 51 of the chillers 3 and 4, respectively. The power consumption is increased when the compressor 51 installed in the chiller 3 is driven at 100%.

That is, when the sensing load is less than or equal to the set value, only one chiller 3 of the plurality of chillers 3 and 4 is operated, and power consumption is reduced than when all the chillers 3 and 4 are operated. The efficiency is high.

On the other hand, when the detected load is 75% when the set value is 50%, the main control unit 16 drives the compressor 51 of the chiller 3 (first chiller) in which the main control unit 16 is installed and the auxiliary control unit. The sub-controller 17 outputs the operation signal to the other chillers 4 and the second chiller so that the compressor 51 of the chiller 4 and the second chiller 4 with the installed 17 is driven, and at this time, the main controller 16 Compressor 51 of chiller 3 in which main control unit 16 is installed so that compressor 51 of chiller 3 in which cooler 3 is installed and compressor 51 of other chiller 4 in which sub control unit 16 is installed are driven at the same capacity. ) And the compressor 51 of the chiller 3 provided with the sub controller 17 are driven at 75% capacity.

If the sensing load is 75% which is greater than the set value of 50%, the compressor 51 of the chiller 3 in which the main control unit 16 is installed and the compressor 51 of the chiller 4 in which the sub control unit 17 is installed When driven at different capacities (for example, the compressor of the first chiller is driven at 100% and the compressor of the second chiller is driven at 50%), the compressor 51 of the plurality of chillers 3 and 4 is driven. The refrigeration cycle high / low pressure difference of the chiller (first chiller) with large operating capacity becomes too high, and the load increase of the compressor having a large operating capacity is increased by the refrigeration cycle high / low pressure difference, and the efficiency is low by the increased load increase. Power consumption is increased.

In other words, when the sensing load exceeds the set value, when the compressors of the plurality of chillers 3 and 4 are driven at the same operating capacity, the compressors of the plurality of chillers 3 and 4 are consumed more than when the compressors are driven at different capacities. Power is reduced and efficiency is high.

5 is a flowchart illustrating a method of operation of an embodiment of an air conditioner according to the present invention.

First, during operation of the air conditioner, the main control unit 16 drives the compressor 51 of the first chiller 3, drives the cold water pump 58, and drives the coolant pump 5 ″. (S1)

When driving the compressor 51 installed in the first chiller 3, the refrigerant is compressed by the compressor 51, and then sequentially passes through the condenser 52, the expansion mechanism 53, and the evaporator 54, and then the compressor 51. Is cycled to

When the cooling water pump 5 ″ is driven, the cooling water of the cooling tower 5 cools the condenser 52 while circulating the cooling tower 5 and the condenser 52 of the first chiller 3.

When the cold water pump 58 is driven, it is cooled by the evaporator 54 while circulating the cold water coil 40 of the air handling units 1 and 2 and the evaporator 54 of the first chiller 3.

In the operation of the first chiller 3, the air handling units 1 and 2 are driven by the air handling unit controls 13 and 14, and the blower fans 27 and 28 are partially driven. Is discharged to the outside, the remainder is mixed with the outdoor air and then cooled while passing through the cold water coil 40, and then discharged to the room.

On the other hand, during operation of the first chiller 3 as described above, the discharge water temperature sensor, which is the load sensing sensor 62, measures the temperature of the cold water supplied from the first chiller 3 toward the air handling units 1 and 2. After measuring and outputting to the main control unit 16, the main control unit 16 performs a load sensing step of detecting the load by the difference between the temperature set by the operation unit 60 and the temperature detected by the water output temperature sensor (S2).

The main controller 16 determines driving of the compressor 51 of the first chiller 3 and the compressor 51 of the second chiller 4 according to the detected load.

The main controller 16 drives the compressor 51 of the first chiller 3 to correspond to the sensed load if the detected load is less than or equal to a set value, and the compressor alone does not output a driving signal to the second chiller 4. Driving steps S3 and S4 are performed.

The main controller 16 drives the compressor 51 of the first chiller 3 and the sub-controller 17 to drive the compressor 51 of the second chiller 4 when the detected load exceeds the set value. A signal is output and the compressor joint drive step S3 (S5) which controls the compressor 51 of the 1st chiller 3 and the compressor 51 of the 2nd chiller 4 to the same operation capacity is performed.

FIG. 6 is a schematic structural diagram of an embodiment of an air conditioner according to the present invention, and FIG. 7 is a schematic structural diagram of a chiller shown in FIG. 6.

As shown in FIG. 6, the air conditioner according to the present embodiment includes an air handling unit 1 and a chiller 3, and the air handling unit 1 and the chiller 3 are connected to the water pipe 6. Chiller (3) and cooling tower (5) are connected to the cooling water pipe (5 '), chiller (3), as shown in Figure 7, the refrigeration cycle (A) of the compressor, condenser, expansion mechanism and evaporator A plurality of (B) is provided.

Since the air handling unit 1 is the same as or similar to an embodiment of the present invention, the same reference numerals are used and detailed description thereof will be omitted.

The air handling unit 1 includes an air handling unit control unit 13 for controlling a blowing fan or the like which is an electric component disposed therein.

The chiller 3 includes a chiller control unit 16 for controlling the compressors 51A, 51B, and the like, which will be described later, and the chiller control unit 16 communicates with the air handling unit control unit 13 of the air handling unit 1. 19).

The chiller 3 independently controls a plurality of compressors 51A and 51B, a plurality of condensers 52A and 52B, a plurality of expansion mechanisms 53A and 54B, and a plurality of evaporators 54A ( 54B).

Hereinafter, the chiller 3 is not limited to the number of refrigeration cycles, but for convenience of description, the first and second refrigeration freezing cycles (A) and (B) will be described.

 The first refrigeration cycle (A) includes a first compressor (51A), a first condenser (52A), a first expansion mechanism (53A) and a first evaporator (54A), the refrigerant is first compressor (51A) and the first The condenser 52A, the first expansion mechanism 53A, and the first evaporator 54A are circulated, compressed, condensed, expanded, and evaporated, and the coolant cools the first evaporator 54A.

The second refrigeration cycle (B) includes a second compressor (51B), a second condenser (52B), a second expansion mechanism (53B) and a second evaporator (54B), the refrigerant is the second compressor (51B) and the second The condenser 52B, the second expansion mechanism 53B, and the second evaporator 54B are circulated, compressed, condensed, expanded, and evaporated, and the refrigerant of the second refrigeration cycle B cools the second evaporator 54B. .

The chiller 3 condenses the refrigerant while the cooling water supplied from the cooling tower 5 passes through both the first condenser 52A and the second condenser 52B, and is supplied from the cold water coil 40 of the air handling unit 1. The cooled cold water is evaporated while passing through both the first evaporator 54A and the second evaporator 54B.

The first compressor 51A is connected to the first condenser 52A and the first evaporator 54A by a first refrigerant passage, and the second compressor 51B is connected to the second condenser 52B and the second evaporator 54B. It is connected to the second refrigerant passage.

The first condenser 52A and the second condenser 52B are integrated into one condenser unit 52, and the partition plate 52C which prevents the refrigerant of the first condenser 52A and the second condenser 52B from mixing. ).

In the condenser unit 52, a plurality of inner tubes are disposed inside the shell, and after the coolant passes through either one of the first condenser 52A and the second condenser 52B, 52B of the coolant, the other one ( The heat of the refrigerant is taken away while passing through 52A, and then the heat of the refrigerant is taken away while passing through any one 52B.

The condenser unit 52 is arranged such that a plurality of inner tubes pass through the partition plate 52C.

Cooling water pipe 5 ″ is connected to the condenser unit 52 so as to be in communication with the plurality of inner tubes.

The first expansion mechanism 53A is connected to the first condenser 52A and the first evaporator 54A by the first refrigerant passage, and the second expansion mechanism 53B is the second condenser 52B and the second evaporator 54B. ) And a second refrigerant passage.

The first evaporator 54A and the second evaporator 54B are integrated into one evaporator unit 54, and partition plate 54C which prevents the refrigerant of the first and second evaporators 54A and 54B from mixing. ).

In the evaporator unit 54, a plurality of inner tubes are disposed inside the shell, in which cold water passes heat to the refrigerant while passing through one of the first evaporator 54A and the second evaporator 54B, and then the other. It is arranged to release heat to the refrigerant while passing through 54A, and then to release heat to the refrigerant while passing through any one 54B again.

The evaporator unit 54 is arranged such that a plurality of inner tubes pass through the partition plate 54C.

The evaporator unit 54 is connected to the water pipe 6 in communication with the plurality of inner tubes.

The water pipe 6 is provided with a cold water pump 58 for circulating water through the evaporator unit 54 of the chiller 3 and the cold water coil 40 of the air handling unit 1. A load sensor 62, which is a water extraction temperature sensor for detecting a temperature, is installed.

8 is a control block diagram of another embodiment of an air conditioner according to the present invention.

The air conditioner according to the present embodiment, as in the embodiment of the present invention, includes an operation unit 60, the chiller control unit 16 is a plurality of in accordance with the operation of the operation unit 50 and the detection result of the load detection sensor 62 The compressor 51A, 51B of a refrigeration cycle (A) (B) is controlled. When the load is less than or equal to the set value, the chiller control unit 16 operates the compressor 51A of one of the plurality of refrigeration cycles (A) and (B) to correspond to the load and reduces the remaining refrigeration cycle ( When the compressor 51B of B) is stopped and the load exceeds the set value, the plurality of refrigeration cycles is minimized so that the load increase of the compressor 51A due to the high / low pressure difference of any of the refrigeration cycles of the chiller 3 is minimized. The compressors 51A and 51B of the plurality of refrigeration cycles A and B are controlled so that the compressors 51A and 51B of (A) (B) are operated together at the same operation capacity.

Here, the load detection of the chiller control unit 16 is the same as or similar to the embodiment of the present invention and a detailed description thereof will be omitted.

That is, in the chiller 3, when the load is less than or equal to the set value, the refrigerant flows only in one of the plurality of refrigeration cycles (A) and (B), and the refrigerant does not flow in the other refrigeration cycle (B). The refrigerant flows through all of the plurality of refrigeration cycles (A) and (B).

Table 1 shows an example in which the set value is set to 50% and the compressors 51A and 51B of the plurality of refrigeration cycles A and B are operated according to the detected load.

Sensing load  First compressor  Second compressor 100% 100% 100% 75% 75% 75% 50% 100% 0% 25% 50% 0%

That is, when the set value is 50% and the detected load is 50%, the chiller control unit 16 drives one of 51A of the first compressor 51A and the second compressor 51B, and the other 51B. In this case, the compressor 51A driven at this time is driven at 100% capacity so as to correspond to all the detected loads alone.

If the sensing load is less than or equal to the set value of 50%, both the compressors 51A and 51B of the chiller 3 are driven together, driving the first compressor 51A to 75%, and the second compressor 51B to 25. When the first compressor 51A is driven at 50% and the second compressor 51B is driven at 50%, the chiller 3 can cope with the sensing load. However, in this case, since the power consumption is supplied to each of the compressors 51A and 51B while the refrigerant is bypassed in each of the compressors 51A and 51B, either compressor 51A is driven at 100%. If the power consumption is increased.

That is, when the sensing load is less than or equal to the set value, the case where only the compressor 51A of any of the plurality of refrigeration cycles (A) (B) of the chiller 3 is operated is operated by the plurality of refrigeration cycles (A) (B). The power consumption is reduced and the efficiency is higher than when the compressors 51A and 51B are all operated together.

On the other hand, the chiller control unit 16, when the set value is 50%, if the detected load is 75%, the plurality of refrigeration cycle so that the compressor (51A) 51B of all the plurality of refrigeration cycle (A) (B) is driven with the same capacity The compressors 51A and 51B of both (A) and (B) are respectively driven at 75% capacity.

If the sensing load is 75% which is greater than the set value 50%, the chiller control unit 16 drives the compressors 51A and 51B of the plurality of refrigeration cycles (A) and (B) with different capacities (first compressor 51A). ) Is driven at 100% and the second compressor 51B is driven at 50%,

 Among the plurality of chillers 3 and 4, the refrigeration cycle high / low pressure difference of the chiller (first chiller) having a large operating capacity is too high, and the load of the compressor having a large operating capacity is caused by the refrigeration cycle high / low pressure difference. The increase is increased, and the increase in load increases the efficiency and power consumption.

In other words, when the sensing load exceeds the set value, the plurality of chillers 3 and 4 are operated at the same compressor operating capacity than when the plurality of chillers 3 and 4 are operated at different compressor operating capacities. Power is reduced and efficiency is high.

9 is a flowchart illustrating a method of operating another embodiment of the air conditioner according to the present invention.

First, during operation of the air conditioner, the chiller control unit 16 drives the first compressor 51A, drives the cold water pump 58, and executes the operation step of driving the cooling water pump 5 ″. S1 ′)

When the first compressor 51A is driven, the refrigerant is compressed by the first compressor 51A, and subsequently passes through the first condenser 52A, the first expansion mechanism 53A, and the first evaporator 54A, and then the first refrigerant. Circulated to the compressor 51A.

When the cooling water pump 5 ″ is driven, the cooling water of the cooling tower 5 cools the first condenser 52A while circulating the cooling tower 5 and the condenser unit 52.

When the cold water pump 58 is driven, the water of the cold water coil 40 of the air handling unit 1 circulates through the cold water coil 40 of the air handling unit 1 and the evaporator unit 54 of the chiller 3. It is cooled by the first evaporator 54A.

When the chiller 3 is operated, the air handling unit 1 is driven by the air handling unit controller 13 to drive the blower fans 27 and 28, and part of the indoor air I is discharged to the outdoors, and the rest is After being mixed with the outdoor air, it is cooled while passing through the cold water coil 40, and then discharged into the room.

On the other hand, during operation of the chiller 3 as described above, the water discharge temperature sensor, which is the load detection sensor 62, measures the temperature of the cold water supplied from the chiller 3 toward the air handling unit 1, the chiller control unit 16 The chiller control unit 16 performs a load sensing step of detecting a load by the difference between the temperature set by the operation unit 60 and the temperature detected by the water extraction temperature sensor. (S2 ′)

The chiller controller 16 determines driving of the first compressor 51A and the second compressor 51B of the chiller 3 according to the sensed load.

The chiller controller 16 drives the first compressor 51A to correspond to the detected load when the sensed load is less than or equal to the set value, and does not output a drive signal to the second compressor 51B (S3 ′). (S4 ').

The chiller controller 16 controls the first compressor 51A and the second compressor 51B to be driven when the detected load exceeds the set value, and the first compressor 51A and the second compressor 51B. Compressor joint drive step S3 '(S5') which controls to the same operation capacity is performed.

1 is a schematic structural diagram of an embodiment of an air conditioner according to the present invention;

2 is a cross-sectional view of the air handling unit shown in FIG.

3 is a schematic configuration diagram of a chiller illustrated in FIG. 1;

4 is a control block diagram of an embodiment of an air conditioner according to the present invention;

5 is a flowchart illustrating a method of operation of an embodiment of an air conditioner according to the present invention;

6 is a schematic structural diagram of an embodiment of an air conditioner according to the present invention;

7 is a schematic configuration diagram of a chiller illustrated in FIG. 6;

8 is a control block diagram of another embodiment of an air conditioner according to the present invention;

9 is a flowchart illustrating a method of operating another embodiment of the air conditioner according to the present invention.

Claims (12)

An air handling unit having a cold water coil and a blowing fan configured to discharge indoor air after passing indoor air through the cold water coil; A chiller having a refrigeration cycle of a compressor, a condenser, an expansion device, and an evaporator, wherein the evaporator supplies chilled water to the cold water coil; The chiller is connected in plurality in parallel, When the load is less than or equal to the set value, the plurality of chillers are driven to correspond to the load, and the remaining compressors of the plurality of chillers are stopped. When the load is greater than the set value, the compressors of the plurality of chillers are together at the same capacity. Driven air conditioner. The method of claim 1,  The air conditioner determines a load according to an operation unit for setting a set temperature, a load sensor for detecting the load, and a detection result of an operation of the operation unit and a load detection sensor, and the compressor of the plurality of chillers according to the determined load. Air conditioner comprising a chiller control unit for controlling. The method of claim 2, The load sensor includes an air outlet temperature sensor for sensing the water outlet temperature of the plurality of chillers. The method of claim 3, wherein  The operation unit includes an air conditioner temperature setting unit for adjusting the desired water outlet temperature of the plurality of chillers. The method of claim 4, wherein The chiller controller is configured to determine the load by the difference between the desired discharge water temperature set by the discharge water temperature setting unit and the temperature detected by the discharge water temperature sensor.  An air handling unit having a cold water coil and a blowing fan configured to discharge indoor air after passing indoor air through the cold water coil; A plurality of refrigeration cycles of a compressor, a condenser, an expansion mechanism, and an evaporator; an evaporator of the plurality of refrigeration cycles includes a chiller for supplying cold water to the cold water coil; When the load is less than or equal to the set value, the compressor of one of the plurality of refrigeration cycles is driven to correspond to the load, and the compressor of the other refrigeration cycle is stopped. When the load is greater than the set value, the compressors of the plurality of refrigeration cycles are the same. Air conditioners driven together at operating capacity. The method of claim 6,  The air conditioner includes an operation unit for setting a set temperature, and a load detection sensor for detecting the load, and a control unit for controlling the compressors of the plurality of refrigeration cycles according to a result of the operation of the operation unit and the detection of the load detection sensor. Air conditioner. The method of claim 7, wherein The load sensor includes an air conditioner temperature sensor for detecting the water outlet temperature of the chiller. The method of claim 8,  The operation unit includes an air conditioner temperature setting unit for adjusting the desired water outlet temperature of the chiller. The method of claim 9, The control unit is an air conditioner for detecting a load by the difference between the desired discharge temperature set by the discharge water temperature setting unit and the temperature detected by the discharge water temperature sensor. The method of claim 7, wherein And the operation unit includes a setting value varying unit configured to vary the set value. The method according to any one of claims 1 to 11, The compressor is a multi-stage compressed screw compressor.

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