KR20190006339A - Ciller unit and Chiller system including the same - Google Patents

Abstract

The present invention relates to a chiller unit and a chiller system including the same. A chiller unit according to the present invention includes a first compressor, a second compressor, an evaporator, and a condenser. The condenser includes: a condenser main body having a predetermined internal space; a partition wall for partitioning an inner space of the condenser main body; a first condensing plate and a second condensing plate coupled to both ends of the condenser main body; a first condenser defined by the first condenser plate, the partition wall and the condenser main body; and a second condenser defined by the second condenser plate, the partition wall and the condenser may body, wherein the refrigerant compressed by the first compressor flows into the first condenser, and the refrigerant compressed by the second compressor flows into the second condenser.

Description

[0001] The present invention relates to a chiller unit and a chiller system including the chiller unit.

The present invention relates to a chiller unit and a chiller system including the same.

Generally, a chiller system refers to a system that supplies cold water to a customer. Specifically, the chiller system is characterized in that the cold water is cooled by heat exchange between the refrigerant circulating in the refrigerant cycle and the cold water circulating the customer. In addition, the chiller system is a relatively large-capacity facility and can be installed in a large-scale building or the like.

1 shows a conventional chiller system.

Referring to FIG. 1, a conventional chiller system 1 includes a chiller unit and a demander 6. The customer 6 can be understood as an air conditioner using cold water as an example.

The chiller unit is provided with a compressor 2 for compressing refrigerant, a condenser 3 for condensing the refrigerant compressed in the compressor 2, an expansion device 4 for decompressing the refrigerant condensed in the condenser 3, And an evaporator (5) for evaporating the refrigerant decompressed in the expansion device (4).

The refrigerant is heat-exchanged with the outside air in the condenser (3), and can be heat-exchanged with the cold water in the evaporator (5).

The chiller system 1 includes a cold water pipe 8 for guiding the circulation of cold water by connecting the evaporator 5 and the customer 6 and a pump for supplying the cold water to the cold water pipe 8, (7).

When the pump 7 is operated, cold water can flow from the demander 6 to the evaporator 5 and from the evaporator 5 to the consumer 6 via the cold water pipe 8 have.

The evaporator (5) is provided with a refrigerant passage (5a) through which refrigerant flows and a cold water passage (5b) through which cold water flows. The coolant in the coolant channel 5a and the coolant in the coolant channel 5b can be indirectly heat-exchanged with each other.

The chiller unit may be provided in various sizes or capacities. Here, the size or the capacity of the chiller unit may be expressed in units of a freezing tone (RT) as a concept corresponding to the capability of the refrigeration system, that is, the refrigeration capacity.

The chiller unit may be equipped with various refrigeration tones according to the size of a building or the like on which the chiller unit is installed, the capacity of circulating cold water, the air conditioning capacity, or the like. For example, the chiller unit may have a capacity of 200RT, 500RT, 1000RT, 1500RT, 2000RT, 3000RT, or the like.

The chiller unit may be provided with a plurality of compressors. Therefore, the number of compressors can be operated differently if necessary. However, when another compressor is operated while one compressor is operating, there is a problem that a surge due to a pressure difference occurs.

Further, when a plurality of compressors include respective condensers and evaporators to prevent this, there is a problem that the size of the chiller unit is increased and the installation space is limited.

The present invention provides a chiller unit having a plurality of compressors configured to prevent the occurrence of surges, and a chiller system including the same.

It also provides a chiller unit that minimizes the volume by effectively utilizing each configuration and a chiller system including the same.

The chiller unit according to the present invention includes a first compressor, a second compressor, an evaporator, and a condenser. The condenser includes a condenser body having a predetermined internal space, A first condensing plate and a second condensing plate coupled to both ends of the condenser body, a first condensing portion defined by the first condensing plate, the partition wall and the condenser body, A second condensing section defined by the partition wall and the condenser main body, the refrigerant compressed by the first compressor flows into the first condensing section, and the refrigerant compressed by the second compressor flows into the second condensing section, The refrigerant flows.

The condenser may further include a cooling water pipe installed through the first condenser and the second condenser.

The first condensing plate, the second condensing plate, and the partition wall may be provided with coupling holes into which the cooling water pipes are inserted.

A sealing member may be provided between the cooling water pipe and the fitting hole to block the flow of the refrigerant.

The first condensing plate, the second condensing plate and the partition wall may be installed to block axial flow of the refrigerant received in the interior of the condenser body have.

The partition wall may be arranged to extend in a radial direction of the condenser main body so as to be in contact with an inner surface of the condenser main body.

The partition wall may have a disc shape corresponding to an end surface of the condenser body to block the flow of the refrigerant.

The condenser includes a first cooling water accommodating portion and a second cooling water accommodating portion in which predetermined cooling water is accommodated, the first cooling water accommodating portion is coupled to the first condensing plate, and the second cooling water accommodating portion is accommodated in the second condensation plate. The first condensing plate, the condenser main body, the second condensing plate, and the second cooling water accommodating portion may be sequentially arranged and coupled.

Wherein the first cooling water accommodating portion is provided with a first cooling water engaging portion into which cooling water flows and a second cooling water engaging portion into which cooling water is discharged so that the cooling water flowing into the first cooling water engaging portion is discharged from the first cooling water accommodating portion, And flows into the second cooling water accommodating portion along the pipe and flows back to the first cooling water accommodating portion along the cooling water pipe in the second cooling water accommodating portion to be discharged to the second cooling water engaging portion.

The first compressor and the second compressor may be provided with a multi-stage compression centrifugal compressor.

The first compressor and the second compressor may include a pair of impellers which are sequentially disposed in the flow direction of the refrigerant.

The first compressor and the second compressor may be driven such that the other one is operable while one of the first compressor and the second compressor is operated.

A first condenser for separating the refrigerant flowing in the first condenser and flowing the gaseous refrigerant to the first compressor and the remaining refrigerant to the evaporator and the refrigerant flowing in the second condenser, 2 compressor and the remainder to the evaporator.

The refrigerant flowing in the first economizer and the second economizer flows together and flows to the evaporator, and the refrigerant evaporated in the evaporator can be branched and flowed to the first compressor and the second compressor.

Further, in the chiller system according to the present invention, in the chiller system including the chiller unit, a cooling tower for supplying cooling water to the chiller unit, a cold water consumer circulating the cold water exchanged with the chiller unit, And a cold water circulation channel for connecting the chiller unit and the cold water consumer so that the cooling water circulation channel connecting the chiller unit and the cooling tower and the cold water are circulated.

According to the present invention, there is an advantage that a plurality of compressors are provided and can be driven at the same time as necessary, or only one of them can be driven effectively.

Further, there is an advantage that a condenser can be divided and operated stably so that the occurrence of surge can be prevented by driving another compressor while driving one compressor.

In addition, since the condenser is not separately provided, the inner space of one condenser is divided and provided, and there is no increase in volume.

In addition, since the cooling water pipe is installed so as to penetrate all the inner space of the condenser, there is an advantage that the cooling water can flow regardless of the operation of the chiller unit.

In addition, since a plurality of compressors are provided by a multi-stage compressor, refrigerant can be compressed more effectively.

Further, it is possible to provide a chiller unit having a plurality of compressors and a chiller system including the chiller unit without adding a separate device.

1 shows a conventional chiller system.
2 is a diagram illustrating a chiller system according to an embodiment of the present invention.
FIG. 3 is a view schematically showing a configuration of a chiller unit according to an embodiment of the present invention.
4 is a view schematically showing the chiller unit of FIG. 3 together with the flow of the fluid.
5 is a view illustrating a chiller unit according to an embodiment of the present invention.
FIG. 6 is a front view of the chiller unit shown in FIG. 5. FIG.
7 is a view illustrating a condenser of a chiller unit according to an embodiment of the present invention.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In the following description of the embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the difference that the embodiments of the present invention are not conclusive.

In describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected or connected to the other component, Quot; may be "connected," "coupled," or "connected. &Quot;

2 is a diagram illustrating a chiller system according to an embodiment of the present invention.

2, the chiller system 10 according to the present invention includes a chiller unit 100 in which a refrigeration cycle is formed, a cooling tower 20 for supplying cooling water to the chiller unit 100, And a cold water consumer 30 through which cold water to be heat-exchanged with the chiller unit 100 circulates.

At this time, the cold water consumer 30 may be understood as a device or a space for performing air conditioning using cold water.

Between the chiller unit (100) and the cooling tower (20), a cooling water circulating flow path (40) is provided. The cooling water circulating passage 40 is a pipe for guiding cooling water circulating between the cooling tower 20 and the chiller unit 100.

The cooling water circulating flow path 40 is provided with a cooling water intake flow path 42 for guiding the cooling water to flow into the chiller unit 100 and a cooling water supply path 42 for guiding the cooling water heated by the chiller unit 100 to the cooling tower 20 And a cooling water outflow channel 44 may be included.

A cooling water pump 46 driven for the cooling water may be provided in at least one of the cooling water intake flow path 42 and the cooling water outflow flow path 44. For example, in FIG. 2, the cooling water inlet passage 42 is provided with the cooling water pump 46.

The cooling water outflow channel 44 may be provided with an outflow temperature sensor 47 for sensing the temperature of the cooling water flowing into the cooling tower 20. The cooling water intake flow path 42 may be provided with an intake temperature sensor 48 for sensing the temperature of the cooling water discharged from the cooling tower 20.

A cold water circulating passage (50) is provided between the chiller unit (100) and the cold water consumer (30). The cold water circulating passage 50 is a pipe for guiding the cold water to circulate the cold water consumer 30 and the chiller unit 100.

The cold water circulation flow path 50 is provided with a cold water intake flow path 52 for guiding the cold water into the chiller unit 100 and a cold water supply flow path 52 for guiding the cold water cooled in the chiller unit 100 to the cold water consumer 30 A cold water outflow channel 54 may be included.

A cold water pump (56) driven for the flow of cold water may be provided in at least one of the cold water inlet flow path (52) and the cold water outlet flow path (54). For example, in FIG. 2, the cold water supply passage 52 is provided with the cold water pump 56.

At this time, the cold water consumer 30 may be a water-cooled air conditioner for exchanging air with cold water.

For example, the cold water consumer 30 may include an air handling unit (AHU) that mixes indoor air and outdoor air and then discharges the mixed air into the indoor space by exchanging heat with cold water, A fan coil unit (FCU) that discharges heat into the room after exchanging heat with cold water, and a bottom piping unit embedded in the floor of the room.

2, the cold water consumer 30 is shown as an air handling unit.

The cold water consumer 30 constituted by the air handling unit is provided with a casing 61 and a cold water coil 62 provided inside the casing 61 through which cold water passes and provided on both sides of the cold water coil 62 And air blowers 63 and 64 for blowing indoor air and outdoor air into the room.

The blowers 63 and 64 are provided with a first blower 63 for allowing indoor air and outdoor air to be sucked into the casing 61 and a second blower 63 for blowing out air to the outside of the casing 61 A blower 64 may be included.

The indoor air suction unit 65, the indoor air discharge unit 66, the ambient air suction unit 67, and the air conditioning air discharge unit 68 may be formed in the casing 61.

When the blowers 63 and 64 are driven, a part of the air sucked into the indoor air suction unit 65 from the room is discharged to the indoor air discharge unit 66 and discharged to the indoor air discharge unit 66 And is mixed with the outdoor air sucked into the outside air suction part (67) and exchanges heat with the cold water coil (62).

The mixed air that has been exchanged (cooled) with the cold water coil 62 can be discharged to the room through the air conditioning air discharge unit 68. Through this process, the indoor space can be cooled by supplying conditioned air.

Further, the cold water consumer 30 may correspond to a facility that uses cold water directly. For example, the cold water consumer 30 may provide cold water for lowering the temperature of the semiconductor component.

In addition, the chiller system 10 according to the present invention can supply cooling water to a hot water consumer other than the cooling tower 20.

That is, the chiller system 10 according to an embodiment of the present invention is not limited to the configuration shown in FIG. 2, and may have various configurations. Hereinafter, the chiller unit 100 connected to the cooling water circulation passage 40 and the cold water circulation passage 50 will be described in detail.

FIG. 3 is a view schematically showing a configuration of a chiller unit according to an embodiment of the present invention, and FIG. 4 is a view conceptually showing a chiller unit of FIG. 3 together with a flow of a fluid.

3 and 4, the chiller unit 100 includes compressors 110 and 120, a condenser 140, expansion devices 131, 132, 134 and 136, an evaporator 150 and an economizer Economizers 130 and 135 are included.

The compressors 110 and 120 are components for compressing the refrigerant. The compressors 110 and 120 according to the present invention may be equipped with a centrifugal compressor. The centrifugal compressor is understood to be a compressor in which a refrigerant is compressed and discharged by converting the kinetic energy of the refrigerant into a constant-pressure energy through a rotating body such as an impeller or a blade.

The condenser 140 is a means for condensing the compressed refrigerant by heat-exchanging the refrigerant compressed from the compressors 110 and 120 with the cooling water flowing inside. That is, the refrigerant compressed from the compressors 110 and 120 may be introduced into the condenser 140.

The cooling water circulating passage 40 is connected to the condenser 140. In the inside of the condenser 140, a plurality of cooling water pipes 46 (see FIG. 7) through which cooling water flows are provided. The refrigerant flowing through the condenser 140 may be heat exchanged with the outer surfaces of the plurality of cooling water pipes 46 while being in contact with each other.

The refrigerant condensed from the condenser 140 may flow to the economizers 130 and 135 through the expansion devices 131 and 134. In detail, the expansion device is provided with suction expansion devices 131 and 134 provided on the suction side of the economizers 130 and 135 and discharge expansion devices 132 and 136 provided on the discharge side of the economizers 130 and 135 ),

Therefore, the refrigerant condensed from the condenser 140 passes through the suction expansion devices 131 and 134 and flows to the economizers 130 and 135.

The economizers 130 and 135 are means for separating the refrigerant gas generated from the refrigerant flowing through the suction expansion devices 131 and 134. Accordingly, the refrigerant gas separated from the economizers 130 and 135 flows into the compressors 110 and 120, and the refrigerant liquid flows to the evaporator 150.

The evaporator 150 is a component for evaporating the refrigerant introduced from the economizers 130 and 135.

In addition, the evaporator 150 is connected to the cold water circulation passage 50. In the evaporator 150, a plurality of cold water pipes (not shown) through which cold water flows are provided. The refrigerant flowing through the evaporator (150) may be heat exchanged with the outer surfaces of the plurality of cold water pipes while being in contact with each other.

As described above, the chiller unit 100 according to the present invention can supply cold water having a predetermined temperature to the cold water consumer 30 by exchanging the refrigerant circulating in the refrigerant cycle with the cold water.

At this time, the chiller unit 100 according to the present invention is provided with a plurality of compressors. The plurality of compressors include a first compressor (110) and a second compressor (120) which are formed in different configurations from each other.

The first economizer 130 and the second economizer 135 may be provided corresponding to the first compressor 110 and the second compressor 120. In addition, a first suction expansion device 131 is provided on the suction side of the first economizer 130, and a first discharge expansion device 132 is provided on the discharge side. A second suction expansion device (134) is installed on the suction side of the second economizer (135), and a second discharge expansion device (136) is provided on the discharge side.

However, the economizers 130 and 135 and the expansion devices 131, 132, 134 and 136 may be connected to the first compressor 110 and the second compressor 120, . That is, the configurations of the economizer and the expansion device are merely illustrative.

In addition, the first compressor 110 and the second compressor 120 may be provided with a multi-stage compression centrifugal compressor including a plurality of impellers. As shown in FIG. 4, the first compressor 110 and the second compressor 120 are provided with a pair of impellers 112 and 122, which are sequentially disposed in the flow direction of the refrigerant.

The first compressor 110 and the second compressor 120 are provided with motor assemblies 114 and 124 for providing a driving force to the impellers 112 and 122 and the motor assemblies 114 and 124, (116, 126) connecting the first and second rotating bodies (112, 122).

4, a pair of impellers 112 and 122 are disposed on one side of the rotating shafts 116 and 126, respectively. However, a pair of impellers 112 and 122 are provided on both sides of the rotating shafts 116 and 126, May be disposed, respectively.

The first compressor 110 and the second compressor 120 may have the same capacity or different capacities. Also, only one of the compressors can be provided as a multi-stage compression centrifugal compressor. That is, the first compressor 110 and the second compressor 120 may have different configurations and may have various shapes and configurations.

The chiller unit 100 according to an embodiment of the present invention may be operated to drive at least one of the first compressor 110 and the second compressor 120. [ That is, only the first compressor 110 or the second compressor 120 may be driven, or both the first compressor 110 and the second compressor 120 may be driven.

3 and 4, the first compressor 110 and the second compressor 120 are connected in parallel to the refrigerant cycle. That is, the first compressor 110 and the second compressor 120 form refrigerant cycles with the condenser 140 and the evaporator 150, respectively, and the refrigerant flows.

For example, when only the first compressor 110 is driven, the refrigerant may flow to the second compressor 120 without flowing or even if it is flowing.

However, when one of the first compressor 110 and the second compressor 120 is driven, a surge may be generated due to a pressure difference. In detail, since the non-driven compressor is formed at the same low pressure as that of the evaporator 150, the flow of the refrigerant becomes unstable due to a sudden change in pressure and reverse flow may occur.

The condenser 140 of the chiller unit 100 according to an embodiment of the present invention includes a first condenser 141 connected to the first compressor 110 and a second condenser 141 connected to the second compressor 120, The second condenser 146 is provided.

Unlike the first compressor 110 and the second compressor 120, which are provided separately from the first condenser 141 and the second condenser 146, the first condenser 141 and the second condenser 146 are separated from each other by the partition wall 145 It corresponds to the separated space. That is, the first condenser 141 and the second condenser 146 are understood as the inner space of the condenser 140 in which the flow of the refrigerant is separated by the partition wall 145.

Referring to FIG. 7, which will be described later, the cooling water pipe 46 is installed in the first condensing part 141 and the second condensing part 146. That is, the cooling water pipe 46 may be installed through the partition wall 145.

The flow of refrigerant, cold water and cooling water through such a structure will be described with reference to FIG. 4 shows a state in which both the first compressor 110 and the second compressor 120 are operated.

The refrigerant compressed in the first compressor (110) and the second compressor (120) flows to the condenser (140). In detail, the refrigerant compressed in the first compressor 110 flows to the first condenser 141, and the refrigerant compressed in the second compressor 120 flows to the second condenser 146 .

The refrigerant flowing through the condenser (140) is heat-exchanged with the cooling water flowing through the cooling water pipe (46) and condensed. At this time, since the cooling water pipe 46 is installed through the partition wall 145, the cooling water can be heat-exchanged with the refrigerant flowing through the first condensing part 141 and the second condensing part 146 have.

The refrigerant condensed in the condenser 140 flows to the expansion devices 131, 132, 134, 136 and the economizers 130, 135. As described above, the expansion devices 131, 132, 134 and 136 and the economizers 130 and 135 are illustratively provided to correspond to the first compressor 110 and the second compressor 120, respectively.

Therefore, the refrigerant discharged from the first condenser 141 passes through the first suction expansion device 131 and flows into the first economizer 130. The gaseous refrigerant separated from the first economizer 130 flows to the first compressor 110 and the remaining refrigerant flows to the evaporator 150 through the first discharge expansion device 132.

The refrigerant discharged from the second condenser 146 flows into the second economizer 135 through the second suction expansion device 134. The gaseous refrigerant separated from the second economizer 135 flows to the second compressor 120 and the remaining refrigerant flows to the evaporator 150 through the second discharge expansion device 136.

That is, the refrigerant having passed through the first discharge expansion device 132 and the second discharge expansion device 136 is connected to the evaporator 150. And may be respectively connected to the evaporator 150 and flowed to the evaporator 150, respectively. The refrigerant flowing through the evaporator 150 is heat-exchanged with the cold water flowing in the cold water pipe and evaporated.

Hereinafter, the shape and arrangement of the chiller unit will be described in detail based on the above description.

FIG. 5 is a view showing a chiller unit according to an embodiment of the present invention, and FIG. 6 is a front view of the chiller unit shown in FIG.

5 and 6, the chiller unit 100 according to an embodiment of the present invention includes the first compressor 110, the second compressor 120, the economizers 130 and 135, the evaporator 150 and the condenser 140 are included.

The condenser 140 is installed on the bottom surface of the condenser 140 and the evaporator 150 is installed on the condenser 140. The first compressor 110 and the second compressor 110 are installed on the evaporator 150, A compressor 120 is installed. The equalizers 130 and 135 may be provided on one side of the evaporator 150.

The condenser 140 and the evaporator 150 are provided with a condenser main body 170 and an evaporator main body 180 which are provided in a cylindrical shape extending in the axial direction. The condenser main body 170 and the evaporator main body 180 are provided to have the same axial length and may be installed to be spaced apart from each other by a predetermined distance in the vertical direction. In particular, the condenser main body 170 and the evaporator main body 180 may be installed so that the bottom surface and the axial direction are parallel to each other.

Plates 172, 173, 182, and 183 are attached to both ends of the condenser main body 170 and the evaporator main body 180, respectively. The plates 172, 173, 182, and 183 may have a rectangular shape and may be installed perpendicular to the bottom surface. Condensation plates 172 and 173 installed in the condenser main body 170 and evaporation plates 182 and 183 installed in the evaporator main body 180 are included in the plates 172, 173, 182 and 183 do.

The condensing plates 172 and 173 may be combined with legs 171 provided on the bottom surface so as to be stably installed on the bottom surface. The lower ends of the evaporation plates 182 and 183 can be engaged with the upper ends of the condensation plates 172 and 173. At this time, each of the joints may be coupled through a coupling member such as a bolt, or may be coupled by welding or the like.

Cooling water receiving portions 174 and 175 and cold water receiving portions 184 and 185 are provided on the other side of the condensing plates 172 and 173 and the evaporation plates 182 and 183 to receive cooling water and cold water. The condenser 140 is coupled to both ends of the condenser main body 170 and the condenser plates 172 and 173 are connected to the outside of the condenser plates 172 and 173, And 175, respectively. Also, the evaporator 150 is provided in the same form.

At this time, the condensation plate and the evaporation plate, which are respectively coupled to both ends of the condenser main body 170 and the evaporator body 180, are connected to the first condensation plate 172, the second condensation plate 173, (182) and a second evaporation plate (183).

The cooling water accommodating portion is divided into a first cooling water accommodating portion 174 coupled to the first condensing plate 172 and a second cooling water accommodating portion 175 coupled to the second condensing plate 173, The cold water receiving portion is divided into a first cold water receiving portion 184 coupled to the first evaporation plate 182 and a second cold water receiving portion 185 coupled to the second evaporation plate 183.

That is, the condenser 140 includes the first cooling water accommodating portion 174, the first condensing plate 172, the condenser main body 170, the second condensing plate 173, (175) are sequentially arranged in the axial direction and coupled to each other.

In addition, the evaporator 150 may include the first cold water receiver 184, the first evaporator plate 182, the evaporator body 180, the second evaporator plate 183, and the second cold water receiver 185 are sequentially arranged in the axial direction and coupled to each other.

The first cooling water accommodating portion 174 and the first cold water accommodating portion 184 are provided with cooling water coupling portions 176 and 177 coupled to the cooling water circulation passage 40 and the cold water circulation passage 50, (186, 187) are provided.

The first cooling water accommodating portion 174 is provided with a first cooling water engaging portion 176 coupled to the cooling water intake flow passage 42 and a second cooling water engaging portion 177 May be provided. The first cold water receiver 184 includes a first cold water receiver 186 coupled to the cold water receiver 52 and a second cold receiver 187 coupled to the cold water receiver 54, May be provided

5 and 6, the first cold water coupling unit 186, the second cold water coupling unit 187, the first cooling water coupling unit 176, and the second cooling water coupling unit 187 are sequentially arranged in the vertical direction . However, such an arrangement is understood to be illustrative.

In addition, the chiller unit 100 according to an embodiment of the present invention may include a control box 160 provided with a device capable of controlling each configuration. The control box may be attached to one side of the condenser 140 and the evaporator 150 in a box shape.

7 is a view illustrating a condenser of a chiller unit according to an embodiment of the present invention.

7, the condenser 140 includes the condenser main body 170, the condensing plates 172 and 173, and the cooling water receiving portions 174 and 175.

The condenser main body 170 is provided in a cylindrical shape having a predetermined space therein. The inner space of the condenser main body 170 may be partitioned in the axial direction by the partition wall 145. In detail, the inner space of the condenser main body 170 is partitioned into the first condenser 141 and the second condenser 146 by the partition wall 145.

The partition wall 145 extends in the radial direction of the condenser main body 170 and is disposed in contact with the inner surface of the condenser main body 170. The partition wall 145 is formed in a shape corresponding to the cross section of the condenser body 170 to block the flow of the refrigerant. That is, the partition wall 145 may be formed as a circular plate.

Inside the condenser main body 170, a plurality of cooling water pipes 46 through which cooling water flows are disposed. The condensing plates 172 and 173 and the partition wall 145 are formed with a plurality of coupling holes 145a, 172a, and 173a through which the plurality of cooling water pipes 46 are inserted. Although one cooling water pipe 46 is shown in FIG. 7 for convenience of explanation, a cooling water pipe 46 corresponding to the plurality of coupling holes 145a, 172a, and 173a may be disposed.

The plurality of coupling holes 145a, 172a and 173a may be formed only on the upper side of the condensing plates 172 and 173 and the partition wall 145. This is to increase the heat exchange efficiency of cooling water with the gaseous refrigerant, and the plurality of coupling holes 145a, 172a, and 173a may be disposed at various positions.

Further, a sealing member (not shown) may be further provided between the plurality of coupling holes 145a, 172a, 173a and the cooling water pipe 46 to block the flow of the refrigerant. A coupling plate (not shown) for stably installing the cooling water pipe 46 may be installed in the condenser main body 170, but the coupling plate is not installed to block the flow of the refrigerant.

That is, the refrigerant flows only between the condensing plates 172 and 173 and the partition wall 145. That is, a space formed by the first condensing plate 172, the partition wall 145, and the condenser body 170 is defined as the first condenser 141, and the second condenser plate 173, The space defined by the partition wall 145 and the condenser body 170 may be defined as the second condenser 146.

In detail, the first condensing plate 172 is provided with a plurality of first plate coupling holes 172a, the second condensing plate 173 is provided with a plurality of second plate coupling holes 173a, The partition wall 145 is provided with a plurality of partitioning holes 145a. At this time, the first plate coupling hole 172a, the second plate coupling hole 173a, and the partitioning hole 145a are provided in the same number and arrangement.

Cooling water flows into the first cooling water accommodating portion 174 through the first cooling water engaging portion 176. The cooling water flows to the second cooling water accommodating portion 175 along the cooling water pipe 46. The second cooling water accommodating portion 177 flows through the second cooling water accommodating portion 175 to the first cooling water accommodating portion 174 along the cooling water pipe 46 and is discharged through the second cooling water engaging portion 177.

At this time, heat exchange between the cooling water and the refrigerant may not occur in any one of the first condensing section 141 and the second condensing section 146.

For example, when the first compressor 110 is operated and the second compressor 120 is not operated, the refrigerant of the first condenser 141 corresponds to a state of relatively high temperature and pressure, The refrigerant in the portion 146 corresponds to a state of relatively low temperature and low pressure.

Therefore, the cooling water absorbs the heat of the refrigerant flowing through the first condensing part 141 through the heat exchange between the refrigerant and the cooling water only in the first condensing part 141, and the heat exchange in the second condensing part 146 is almost Is not generated. At this time, no heat exchange occurs, and the cooling water passes through the second condenser 146.

At this time, when the second compressor (120) is driven, the high temperature and high pressure refrigerant flows to the second condenser (146) and heat exchange with the cooling water occurs. With this configuration, the chiller unit 100 can be driven without any problem even if the second compressor 120 is operated while the first compressor 110 is operating.

10: Chiller system 46: Cooling water piping
100: chiller unit 110: first compressor
120: second compressor 140: condenser
141: first condenser 145: partition wall
146: second condenser 150: evaporator

Claims (15)

A chiller unit comprising a first compressor, a second compressor, an evaporator and a condenser,
In the condenser,
A condenser main body having a predetermined inner space;
A partition wall partitioning an inner space of the condenser main body;
A first condensing plate and a second condensing plate coupled to both ends of the condenser body;
A first condenser defined by the first condenser plate, the partition wall and the condenser body; And
And a second condenser defined by the second condenser plate, the partition wall and the condenser body,
The refrigerant compressed by the first compressor flows into the first condenser,
And the refrigerant compressed by the second compressor flows into the second condenser. The method according to claim 1,
Wherein the condenser further comprises a cooling water pipe installed through the first condenser and the second condenser. 3. The method of claim 2,
Wherein the first condensing plate, the second condensing plate, and the partition wall are provided with coupling holes into which the cooling water pipes are inserted. The method of claim 3,
And a sealing member for blocking the flow of the refrigerant is provided between the cooling water pipe and the fitting hole. The method according to claim 1,
The condenser main body is provided in a cylindrical shape extending in the axial direction,
Wherein the first condensing plate, the second condensing plate, and the partition wall are installed to block axial flow of the refrigerant received in the condenser body. 6. The method of claim 5,
Wherein the partition wall extends radially of the condenser body so as to be in contact with an inner surface of the condenser body. The method according to claim 6,
Wherein the partition wall is provided in a disc shape corresponding to an end surface of the condenser main body to block the flow of the refrigerant. The method according to claim 1,
The condenser further includes a first cooling water accommodating portion and a second cooling water accommodating portion in which predetermined cooling water is accommodated,
Wherein the first condensing plate is coupled to the first cooling water accommodating portion and the second condensing plate is coupled to the second cooling water accommodating portion,
Wherein the first cooling water accommodating portion, the first condensing plate, the condenser main body, the second condensing plate, and the second cooling water accommodating portion are arranged in order. 9. The method of claim 8,
Wherein the first cooling water accommodating portion is provided with a first cooling water engaging portion into which cooling water flows and a second cooling water engaging portion into which cooling water is discharged,
The cooling water flowing into the first cooling water coupling portion flows into the second cooling water accommodating portion along the cooling water pipe in the first cooling water accommodating portion and flows into the first cooling water accommodating portion along the cooling water pipe in the second cooling water accommodating portion And is discharged to the second cooling water coupling portion. The method according to claim 1,
Wherein the first compressor and the second compressor are provided with a multi-stage compression centrifugal compressor. 11. The method of claim 10,
Wherein the first compressor and the second compressor include a pair of impellers which are arranged in order in the flow direction of the refrigerant. The method according to claim 1,
Wherein one of the first compressor and the second compressor is operated while the other is operating. The method according to claim 1,
A first economizer for separating the refrigerant flowing in the first condenser to flow the gaseous refrigerant to the first compressor and the remainder to the evaporator; And
And a second economizer for separating the refrigerant flowing in the second condenser to flow the gaseous refrigerant to the second compressor and the remainder to the evaporator. 14. The method of claim 13,
The refrigerant flowing in the first economizer and the second economizer flows together and flows to the evaporator,
Wherein the refrigerant evaporated in the evaporator is branched and flows to the first compressor and the second compressor. A chiller system comprising the chiller unit of any one of claims 1 to 14,
A cooling tower for supplying cooling water to the chiller unit;
A cold water consumer where cold water to be heat-exchanged with the chiller unit circulates;
A cooling water circulation passage for connecting the chiller unit and the cooling tower so that the cooling water is circulated; And
And a cold water circulation channel for connecting the chiller unit and the cold water consumer so that cold water is circulated.

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