KR101952627B1 - Multi integrated freezer system and control method thereof - Google Patents

Abstract

The present invention provides a complex integrated freezer system, including: a room cooling unit formed of a plurality of freezers; a plurality of cooling towers integrally formed at the plurality of freezers respectively; cool water circulation flow paths connected to the plurality of freezers, respectively, to supply and recover cool water between the room cooling unit and a load side; and cooling water circulation flow paths connected to the plurality of freezers and the plurality of cooling towers to supply and recover cooling water between the room cooling unit and the cooling towers, wherein the room cooling unit is formed of a first freezer composed of an electric freezer and a second freezer operated with a power source different from that of the first freezer, and a control unit which actuates or stops the complex integrated freezer system at an initial stage by actuation or stoppage of the first freezer is included. The complex integrated freezer system is controlled in an optimal state according to a needed load to be capable of maximizing energy efficiency.

Description

[0001] MULTI INTEGRATED FREEZER SYSTEM AND CONTROL METHOD THEREOF [0002]

The present invention relates to a combined monolithic refrigerator system for reducing refrigerator operation cost and a control method thereof, and more particularly, to a monolithic integrated refrigerator system and a control method thereof that can reduce energy required in a refrigeration system including a cooling tower and a refrigerator .

The general cooling system is installed at a position where the temperature and humidity of the room are required to be controlled. The cooling system is installed on the load side where the cooling is performed through the heat exchange between the cold water and the room air, and the cooling tower, And a refrigerator for cooling the hot water through heat exchange between the cooling water and the cold water, for transferring the hot water to the load side, and for sending the hot water to the cooling tower.

Here, the cooling water cooled in the cooling tower is supplied to the freezer through the cooling water supply line, and the cooling water warmed through the heat exchange with the cold water in the freezer is recovered to the cooling tower through the cooling water recovery line.

In addition, cold water, which is warmed by heat exchange with indoor air at the load side, is recovered as a refrigerator through a cold water recovery line. Cold water, which is cooled through heat exchange with cooling water in the freezer, is sent to the load side through a cold water supply line.

In this case, in order to provide a large-capacity refrigeration load, a cooling system generally uses a plurality of refrigerators connected together, and a plurality of refrigerators are sequentially controlled according to a required load. As a result, since it is impossible to precisely control the operation cost according to the load, the operation ratio is increased and the energy can not be efficiently managed.

(Patent Document 0001) Korean Patent Publication No. 10-2010-0084358 (published on July 26, 2010)

(Patent Document 0002) Korean Patent Publication No. 10-2013-0120866 (published Nov.

(Patent Document 3) Korean Patent Laid-Open No. 10-2015-0060472 (published on June, 2013)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a combined monolithic refrigerator system and a control method thereof that can reduce operating costs and maintenance and repair costs.

According to an aspect of the present invention, there is provided a refrigerator comprising: a cooling unit including a plurality of refrigerators; A plurality of cooling towers integrally formed in each of the plurality of freezers;

A cold water circulating flow path connected to the plurality of refrigerators so that cold water is supplied and recovered between the cooling part and the load side; And a cooling water circulating flow path connecting the plurality of refrigerators and the plurality of cooling towers so that cooling water is supplied and recovered between the cooling unit and the cooling tower, wherein the cooling unit is formed by an electric refrigerator And a control unit which is formed of a first refrigerator and a second refrigerator operated by a power source different from that of the first refrigerator and controls the hybrid integrated refrigerator system to be initially started or stopped by operating or stopping the first refrigerator Wherein the refrigerator is a refrigerator.

In addition, the first refrigerator and the second refrigerator may be formed in plural, and the controller may check the operation time of each of the plurality of first refrigerator, and may operate or operate one of the first refrigerator designated by alternate control It is preferable to stop or start the operation of the integrated monolithic refrigerator system.

The first refrigerator may be formed by a turbo refrigerator or a screw refrigerator, and the second refrigerator may be formed by an absorption type refrigerator or an absorption type cold / hot water heater.

The cold water circulation flow path is connected to a cold water supply line connected to a first hollow pipe formed on one side of the load side to supply cold water to the plurality of freezers and a second hollow pipe formed on the other side of the load side, And a controller for controlling the operation of the plurality of refrigerators according to the temperature of the cold water discharged from the second hollow pipe.

The cold water supply line may be connected to each of the plurality of refrigeration units and may include a plurality of cold water valves. The plurality of cold water supply lines may be individually opened and closed by the control unit, They can be operated individually.

According to another aspect of the present invention, there is provided a refrigerator including a cooling unit for performing heat exchange through a load side, a load side and a cold water circulation channel, and a cooling tower for exchanging heat with the cooling unit through a cooling water circulation channel, wherein the cooling unit is formed by an electric refrigerator and an absorption type refrigerator Wherein the operation of each of the plurality of electric freezers is compared with the operation of each of the plurality of electric freezers to operate the electric freezer having the least operation time to start the operation of the integrated monolithic type freezer system; Determining an operation mode by measuring a temperature of cold water discharged from the cooling unit; A load increasing step of increasing the load of the cooling unit when the cold water temperature is higher than a predetermined set temperature in the operation step determining step; And a load reducing step of reducing a load of the cooling unit when the cold water temperature is lower than a predetermined set temperature in the operation step determining step.

Wherein the load increasing step includes a first load increasing step of increasing a load of the moving refrigerator, and a second load increasing step of calculating an operating ratio of the refrigerator not operating when the moving refrigerator is operating at a maximum load, And a second load increasing step of comparing the operating time of each of the plurality of selected freezers when the plurality of freezers are selected and operating the freezer with the least operating time when the plurality of freezers are selected have.

Wherein when the plurality of refrigerators are in operation, the first load increasing step calculates an operating ratio per each freezing capacity of each of the plurality of refrigerating machines operating to increase the load by selecting the refrigerator with the lowest operating ratio, A first load reducing step of calculating an operation ratio per each freezing capacity of each of the plurality of movable refrigerators to select the refrigerator having the highest operation ratio to reduce the load; The control unit calculates the operation ratio of each of the plurality of refrigerators that are in operation and determines the operation ratio of each of the plurality of refrigerators to select the refrigerator having the highest operation ratio to stop the operation of the refrigerator, And the second load reduction for stopping the refrigerator having the greatest operation time Step.

If the electric refrigerator is one of the plurality of refrigerators to be operated, the second load reduction step may stop the operation by selecting the absorption type refrigerator having the highest operation ratio among the moving absorption refrigerators.

As described above, according to the present invention, various effects including the following can be expected. However, the present invention does not necessarily achieve the following effects.

First, the combined monolithic refrigerator system and the control method of the present invention are provided with a refrigerator that operates with different power sources, and can be controlled in an optimal state according to various environments, thereby improving energy efficiency.

By using alternate control, the same kind of refrigerator can be used equally, and the life of the refrigerator and each component can be minimized to prolong the service life. Therefore, it has an effect of reducing the maintenance and repair cost of the combined monolithic refrigerator system.

In addition, the control unit can automatically control all the processes and can control the system by reflecting the real time operation cost. Therefore, it is possible to minimize the management manpower, thereby remarkably reducing the management cost, and at the same time, maximizing the energy efficiency due to the reduction of the operating cost.

1 is a conceptual diagram of a combined monolithic refrigerator system according to an embodiment of the present invention;
Figure 2 is a schematic view of Figure 1;
3 is a flowchart of a control method of a combined monolithic refrigerator system according to an embodiment of the present invention.
4 is a flowchart of a control method of the load increasing step of FIG.
5 is a flowchart of a control method of the load reduction step of FIG.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted so as to avoid obscuring the subject matter of the present invention.

FIG. 1 is a conceptual view of a combined monolithic refrigerator system according to an embodiment of the present invention, and FIG. 2 is a schematic view of FIG.

1 and 2, a single integrated type refrigerator system 100 according to an embodiment of the present invention includes a cooling unit 20 formed of a plurality of freezers 21 and 22, a plurality of freezers 21 and 22 A plurality of cooling towers 30 formed integrally with the plurality of refrigerators 21 and 22 so as to supply and recover cold water between the cooling unit 20 and the load side 10, A cooling water circulation passage 50 connecting the plurality of refrigeration units 21 and 22 and the plurality of cooling towers 30 so that cooling water is supplied and recovered between the cooling unit 20 and the cooling tower 30, Wherein the cooling unit 20 includes a first refrigerator 21 formed by an electric refrigerator and a second refrigerator 22 operated by a power source different from the first refrigerator 21, (100) is initially operated by operating or stopping the compressor (21) It characterized in that it further comprises a control unit 60 for controlling to stop.

The cooling unit 20 is formed of a first refrigerator 21 and a second refrigerator 22 formed by an electric refrigerator and is formed in a plurality of units so that the number of operations is controlled according to a required cooling load. At this time, the freezers 21 and 22 heat-exchange the cooling water supplied through the cooling water supply line 52 and the cold water recovered through the cold water recovery line 43 to cool the cold water and cool the cooling water through the cooling water recovery line 51 To the cooling tower (30), and supplies cold water to the load side (10) through the cold water supply line (41).

The first refrigerator (21) is formed by an electric refrigerator. Electric chillers can be quickly replaced with the required cooling load changes to quickly meet user demand. Examples include turbo chillers, screw chillers, and reciprocating chillers.

The second refrigerator (22) is a refrigerator that operates as a power source different from the first refrigerator (21). Examples thereof include an absorption type refrigerator and an absorption type cold water heater. In case of absorption type, there is a disadvantage that initial start time is slower than that of electronic type. However, it can reduce installation cost because power consumption is less than electric type, maximum electric power consumption is reduced and smaller electric equipment can be utilized, There is an advantage that it can cope with power.

The present invention includes a cooling unit (20) capable of individually operating a first refrigerator (21) and a second refrigerator (22) with different power sources, Can be provided. Accordingly, it is preferable that the plurality of refrigerators 21 and 22 are connected in parallel, and the specific gravity of the electric freezer 21 is preferably less than about half.

The cooling tower 30 is formed integrally with each of the plurality of freezers 21 and 22, and is formed with a heat exchanger for cooling high-temperature cooling water and a fan for supplying wind to the heat exchanger. At this time, a cooling water pump is installed in the cooling water supply line for smooth circulation of the cooling water.

Specifically, the heat exchanger communicates with the cooling water circulating flow path 50 to cool the cooling water heated by the refrigerators 21 and 22 to be warmed. Generally, the cooling tower 30 is installed outside, It is cooled by circulation.

The cold water circulating passage 40 is provided with a cold water supply line 41 for supplying cold water from the load side 10 to the cooling unit 20 and a cold water recovery line 41 for sending the cold water cooled in the cooling unit 20 to the load side 10 again. (43). Therefore, the cold water circulation passage 40 is connected to the cooling section 20 and the load side 10, respectively, and serves as a path through which the cold water for cooling the air on the load side 10 moves. At this time, cold water means a refrigerant circulating between the cooling unit 20 and the load side 10.

Therefore, the cold water supply line 41 and the cold water recovery line 43 are formed in plural to be connected to the plurality of freezers 21 and 22, respectively. At this time, the plurality of cold water supply lines 41 are connected to the first common piping 42 formed on one side of the load side 10 to distribute and supply cold water to the plurality of freezers 21 and 22, 43 are connected to a second common pipe 44 formed on the other side of the load side 10 to collect and collect cold water cooled by each of the plurality of freezers 21,

Therefore, the cold water supply line 41 is provided with the cold water valve 411 and the cold water pump 412, respectively, so that a part or all of the plurality of freezers 21 and 22 can be operated if necessary. The cold water valve 411 is opened and closed by the control unit 60 to open the connected cold water supply line 41 and the cold water pump 412 allows the cold water to circulate smoothly.

Further, the second hollow pipe 44 is further provided with a temperature sensor 441 for measuring the temperature of the cold water discharged from the cooling unit 20 to the load side 10. This is for providing a more optimized cooling by measuring the temperature of the cold water supplied from the cooling unit 20 to the load side 10 and the temperature sensor 441 transmits information about the measured cold water temperature to the controller 60 . Specifically, the control unit 60 compares the cold water temperature measured by the temperature sensor 441 with a predetermined set temperature to control the cooling load provided to the load side 10.

The cooling water circulating flow path 50 includes a cooling water supply line 52 for supplying cooling water from the cooling tower 30 to the cooling unit 20 and a cooling water recovery line 51 for sending cooling water from the cooling unit 20 to the cooling tower 30, . Therefore, the cooling water circulation flow path 50 is formed so as to circulate the cooling tower 30 integrally formed with the freezers 21 and 22, and the cooling water for cooling the cold water in the cooling tower 30 moves. At this time, a cooling water pump is installed in the cooling water circulation flow path 50 for smooth circulation of the cooling water.

The control unit 60 automatically controls the respective components so as to control the integrated monolithic refrigerator system 100 in accordance with the environment. Therefore, the combined monolithic refrigerator system 100 according to the present invention has an effect of minimizing the manpower of maintenance by reducing the maintenance cost by automatically performing all the processes of the control.

Specifically, the controller 60 uses a first refrigerator 21 formed of an electric refrigerator whose startup is quick at the time of initial cooling and at the end of the entire cooling of the integrated monolithic refrigerator system 100, and a plurality of first refrigerator 21 The operation time of each of the plurality of first refrigerators 21 is calculated to operate the first freezer 21 having the least operation time to start the operation of the integrated monolithic type freezer system 100 for the first time, The operation of the first refrigerator (21) is stopped and the entire cooling of the integrated monolithic refrigerator system (100) is terminated.

The control unit 60 calculates the operation ratios of all the refrigerators 21 and 22 constituting the cooling unit 20 so that the operation ratio is minimized even when the refrigerant load of the integrated monolithic refrigerator system 100 is increased or decreased. The operation time of each of the plurality of refrigerators 21 and 22 is considered.

At this time, the control unit 60 may control the combined monolithic refrigerator system 100 according to the real-time environment without any additional operation of the user by increasing or decreasing the cooling load according to the temperature of the cold water discharged from the load side. Therefore, the controller 60 is connected to the temperature sensor 441 installed in the second hollow pipe 44.

In other words, the combined monolithic refrigerator system 100 of the present invention selects the refrigerators 21 and 22 whose operation or operation is interrupted in consideration of the load amount, the operation cost, and the operation time of each of the plurality of freezers 21 and 22 The present invention has an effect that the operation ratio is reduced and the service life of each configuration is extended to reduce the maintenance cost. In addition, the cooling load is automatically controlled without any special operation, thereby providing improved convenience to the user.

Hereinafter, a control method of the integrated monolithic refrigerator system according to the control unit will be described in detail. However, the functions and effects of the respective components of the combined monolithic refrigerator system are the same as those described above, and will be omitted.

FIG. 3 is a flowchart illustrating a control method of the combined monolithic refrigerator system according to an embodiment of the present invention. FIG. 4 is a flowchart of a control method of the load increasing step of FIG. 3, and FIG. 5 is a flowchart of a control method of the load reducing step of FIG.

3 to 5, there are shown a cooling unit for performing heat exchange through a load side, a load side, and a cold water circulation channel according to an embodiment of the present invention, and a cooling tower for performing heat exchange through the cooling unit and a cooling water circulation channel, The control method of the combined type freezer system formed by the electric refrigerator and the absorption type refrigerator is characterized in that the operation time of each of the plurality of electric freezers is compared and the initial operation (S20) for determining the operation mode by measuring the temperature of the cold water discharged from the cooling unit, and a step (S20) for determining whether the cold water temperature is higher than a predetermined set temperature , A load increasing step (S21) for raising a load of the cooling unit, and an operating step determining step (S20) When the water temperature preset set lower than the temperature, it characterized in that it includes a load reduction step (S22) of reducing the load on the cooling portion.

The initial operation step S10 starts the operation of the integrated monolithic refrigerator system, and starts the cooling by operating the electric refrigerator. At this time, since the electric refrigerator is formed by a plurality of electric refrigerators, the operation time of each of the plurality of electric refrigerators is compared and the electric refrigerator having the least operation time is selected and operated to start the cooling.

The electric refrigerator is advantageous in that it is quicker to start than the absorption type refrigerator, thereby reducing the total operation time of the combined type freezer system.

The operation step determination step S20 is a step of determining the operation mode by measuring the temperature of the cold water discharged from the cooling unit and judging whether the cooling load provided by the integrated integrated type freezer system is appropriate.

Specifically, the cooling load is increased or decreased according to the difference between the cold water temperature that is discharged and the predetermined set temperature. When the present cooling load is low, the temperature of the cold water, which is discharged from the circulating cold water, is measured higher than the set temperature. If the present cooling load is large, the amount of heat transferred to the circulating cold water is low The cold water temperature is measured to be lower than the set temperature.

Therefore, the control method of the combined monolithic refrigerator system of the present invention controls the cooling load according to the temperature of the cold water discharged from the cooling unit. In other words, it can automatically control the complex integrated type freezer system according to the real-time environment, minimizing the management manpower and quickly meeting the cooling demand.

The load increasing step S21 is a step of increasing the cooling load provided when the cold water temperature is higher than the set temperature in the operation step determining step S20.

Specifically, the load increasing step S21 includes a first load increasing step for increasing the load of the operating refrigerator, and a second operating speed increasing step for calculating the operating ratio of the non-operating refrigerator when the operating refrigerator is operating at the maximum load, And a second load increasing step of comparing the operating time of each of the plurality of selected refrigerators when the plurality of refrigerators are selected and operating the refrigerator having the least operation time.

Since the integrated monolithic refrigerator system of the present invention is initially operated only by the electric refrigerator, when the operating refrigerator is one, the electric refrigerator operates. Accordingly, when the operating electric refrigerator operates at the maximum refrigerating load (S212), the refrigerator whose operation ratio is minimum is operated (S2122). When the refrigerating load does not operate at the maximum refrigerating load, the cooling load of the operating electric refrigerator is increased ).

In this case, even when the refrigeration load of the electric refrigerator to be operated at the maximum is increased, when the cold water temperature is higher than the set temperature, the refrigerator is operated with the minimum operating ratio.

In the following, a case where a plurality of freezers are operated will be specifically described.

In a case where there are a plurality of refrigerators to be operated, the first load increasing step calculates an operating ratio of each of the plurality of refrigerators to be operated in accordance with the cooling capacity, selects a refrigerator having the minimum operating ratio (S211), and increases the load of the selected refrigerator ). At this time, when there are a plurality of selected refrigerators, the operation times of the plurality of selected refrigerators are compared to increase the load of the refrigerator having the least operation time (S2111, 2112). In the case where all of the plurality of refrigerators to be operated operate at the maximum cooling load, the refrigerator (S211) having the minimum operating ratio is selected and the selected refrigerator is operated (S2122).

The load reducing step S22 is a step of decreasing the cooling load provided when the cold water temperature is lower than the set temperature in the operation step determining step S20 and is performed by a first load reducing step of reducing the load of the operating refrigerator And a second load reducing step of selecting one of the refrigerators to be operated and stopping the operation when all of the refrigerators operating at the minimum cooling load operate.

In the integrated monolithic refrigerator system of the present invention, since the operation is stopped only by the electric refrigerator, the electric refrigerator is operated when there is one refrigerator to be operated. Accordingly, when only one electric refrigerator is operated, the refrigeration load of the electric refrigerator that operates as needed is reduced to reduce the provided cooling load (S2221), or the operation of the operating electric refrigerator is interrupted (S2222) Thereby stopping the operation of the refrigerator system.

Therefore, a plurality of refrigerators to be operated will be described in detail below.

The first load reduction step reduces the cooling load, which reduces the cooling load of some refrigerators of an operating refrigerator. The operation ratio of each of the plurality of freezers operating at this time is calculated to select the refrigerator having the highest operation ratio (S221) to reduce the load. If there are a plurality of predetermined freezers, the operation time of the selected freezer is compared The refrigerator having the largest operation time is selected (S2211), and the load of the selected refrigerator is decreased (S2212).

The second load reduction step is a case where all of the plurality of refrigerators to be operated operate at the minimum cooling load. If there is one electric refrigerator that operates by recognizing that there is a plurality of electric refrigerators to be operated, the operation of the absorption type refrigerators except for the electric refrigerator (S2212) to reduce the cooling load to be provided.

When there are a plurality of absorption refrigerating machines operating at this time, an operation ratio per cooling capacity of each of the operation absorption refrigerators is calculated, and the absorption refrigerating machine having the highest operation ratio is selected (S221), the operation of the selected refrigerator is stopped (S2212) If there are a plurality of absorption type refrigerators, the operation time of the selected absorption type refrigerator is compared to select an absorption type refrigerator having the largest operation time (S2211), and the operation of the selected absorption type refrigerator is stopped (S2212).

In the case where there are a plurality of electric refrigerators to be operated, the operation cost per cooling capacity of all the refrigerators to be operated is calculated, and the operation of the refrigerator having the highest operation ratio is selected (S221) The operation time of the freezer is compared to select a freezer with the largest operation time (S2211), and the operation of the selected freezer is stopped (S2212).

Therefore, the control method of the combined-type freezer system of the present invention can reduce the entire operation time by using the electric type freezer that can be rapidly replaced with the cooling load at the initial cooling and the end of the entire cooling of the combined- It is possible to alternately control the operation time in consideration of the operation time, thereby minimizing the operation cost of the combined monolithic refrigerator system and improving the energy efficiency.

In addition, a plurality of refrigerators constituting the combined monolithic refrigerator system are uniformly used to reduce the consumption of the refrigerator and the components, thereby prolonging the service life of the refrigerator and the maintenance cost.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the invention is not limited to the disclosed exemplary embodiments, but variations and modifications may be made without departing from the scope of the present invention. .

100 Integrated Integrated Freezer System
10 Load side
20 cooling section 21 first refrigerator, electric refrigerator 22 second refrigerator
30 cooling tower
40 cold water circulation channel 41 cold water supply line 411 cold water valve
412 cold water pump 42 first common piping 43 cold water recovery line
44 2nd common piping 441 Temperature sensor
50 Cooling water circulation channel 51 Cooling water recovery line 52 Cooling water supply line
60 control unit
S10 Initial start-up phase
S20 Operation phase determination step
S21 load increase step
S22 Load reduction step

Claims (9)

A cooling unit including a plurality of first refrigerators formed of a turbo chiller or a screw chiller, and a plurality of second chillers formed of an absorption chiller or an absorption chiller;
A plurality of cooling towers integrally formed in each of the first and second refrigerator units;
A cold water supply line connected to a first hollow pipe formed on one side of the load side for supplying cold water to the first and second freezers, and a cold water supply line connected to a second hollow pipe formed on the other side of the load side, A cold water circulating flow path formed by a cold water collecting line for collecting cold water cooled at the load side;
A cooling water circulation flow path connecting the first and second refrigerator and the plurality of cooling towers so that cooling water is supplied and recovered between the cooling part and the cooling tower; And
And a controller for controlling the operation of the first and second refrigerators according to a difference between a temperature of the cold water discharged from the second hollow pipe and a preset temperature,
The control unit
The first and second freezers are operated only when all of the first and second refrigerators being operated are operated at the maximum load, The first and second freezers are operated at a minimum operating ratio of the freezer, and when the load is reduced, the first and second freezers are operated to reduce the load of the freezer, The operation of the refrigerator having the highest operating ratio among the first and second refrigerators operating only when the refrigerating machine is operated is stopped,
The first integrated circuit type refrigerator system is activated by operating the first refrigerator having the least operation time among the plurality of first freezing devices and the operation of the first integrated refrigerator system is stopped to stop the operation of the integrated integrated type refrigerator system Wherein the refrigerator is a refrigerator.
The method according to claim 1,
The control unit
When there are a plurality of the first and second refrigerators having the minimum operating ratio, the operation time is checked and the refrigerator having the smallest operation time is operated by the alternate control, or the operation of the refrigerator having the longest operation time is stopped, When the operation of any one of the first and second refrigerators is stopped, if the refrigerator having the minimum operating ratio is the first refrigerator and the first refrigerator is in operation, And stops the refrigerator.
delete delete The method according to claim 1,
The cold water supply line
Wherein a plurality of cold water valves are provided in each of the plurality of refrigerators, and the plurality of cold water supply lines are individually opened and closed by the control unit, so that the plurality of refrigerators are individually operated. Integrated refrigerator system.
A cooling unit for performing heat exchange through the load side, the load side, and the cold water circulation channel; and a cooling tower for performing heat exchange through the cooling unit and the cooling water circulation channel,
Wherein the cooling unit comprises a plurality of electric refrigerators and an absorption type refrigerator, the method comprising:
An initial operation step of comparing the operation time of each of the plurality of electric freezers and operating the electric type freezer with the shortest operation time to start the integrated integrated type freezer system at an initial stage;
Determining an operation mode by measuring a temperature of cold water discharged from the cooling unit;
A first load increasing step of increasing a load of an operating refrigerator when the cold water temperature is higher than a predetermined set temperature in the operating step determining step; and a second load increasing step of, when the operating refrigerator is operating at a maximum load, The operation time of each of the selected plurality of freezers is compared to select one of the plurality of freezers, and when the plurality of freezers are selected, the operation time of each of the selected plurality of freezers is compared to operate the freezer A load increasing step formed by a second load increasing step; And
Wherein when the cold water temperature is lower than a predetermined set temperature, the control unit calculates the operation ratio of each of the plurality of refrigerators to be operated and determines the refrigerator having the highest operation ratio to reduce the load, And a controller for controlling the plurality of freezers to operate in accordance with the operating rates of the plurality of freezers, wherein when the all of the freezers are operated at a minimum load, And a second load reducing step of comparing the operation times of the plurality of selected refrigerators with each other to stop the refrigerator having the largest operation time,
If the electric refrigerator is one of the plurality of refrigerators to be operated,
Wherein the second load reducing step stops the operation of the absorption type refrigerator having the highest operation ratio among the operation absorption refrigerators.
delete The method according to claim 6,
When there are a plurality of refrigerators to be operated,
The first load increasing step may include calculating an operation ratio of each of the plurality of refrigerators operating in the freezing capacity, selecting the refrigerator having the minimum operating ratio to increase the load,
The load reduction step
A first load reducing step of calculating an operation ratio per each freezing capacity of each of the plurality of operating refrigerators and selecting the refrigerator having the highest operating ratio to reduce the load;
Wherein the control unit calculates the operation ratio of each of the plurality of refrigerators to be operated in a case where all of the refrigerators to be operated are operated at the minimum load to select and stop the refrigerator having the highest operation ratio, And a second load reduction step of comparing the operation times of the plurality of selected refrigerators with each other to stop the refrigerator having the largest operation time. delete

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