KR20130118661A - Device and method for controlling outlet temperature of chilled water in network operating center building energy management system - Google Patents

Abstract

PURPOSE: A device for controlling a cold water supply temperature in a building energy management system and a method thereof are provided to maintain pleasant indoor environment of a building by slightly increasing the cold water supply temperature of a refrigerator to a control value set by using monitoring information obtained through the past statistical data and real-time monitoring. CONSTITUTION: A device for controlling a cold water supply temperature in a building energy management system includes a monitoring unit (120), a control unit (130), and a storage unit (160). The monitoring unit monitors a refrigerator system (10) in real time. The control unit analyzes the past statistical data of the refrigerator system and determines whether the cold water supply temperature of a refrigerator is changed or not according to a cooling capacity and air conditioning loads. When the change of the cold water supply temperature is necessary, the control unit controls the cold water supply temperature of the refrigerator with a predetermined control value set by using monitoring information obtained through the monitoring. The storage unit stores over one among the past statistical data, the monitoring information, main contents for the monitoring, and information for changing the cold water supply temperature. [Reference numerals] (10) Refrigerator system; (100) Cool water supply temperature control device; (110) Input unit; (120) Monitoring unit; (130) Control unit; (140) Output unit; (150) Communication unit; (160) Storage unit; (AA) Manager

Description

Device and method for controlling outlet temperature of chilled water in Network Operating Center Building Energy Management System

The present invention relates to a building energy management system, and more particularly, to an apparatus and method for controlling cold water supply temperature in a building energy management system for improving energy use efficiency while maintaining a comfortable indoor environment of a building by changing a cold water supply temperature of a building's refrigerator. It is about.

In Korea, which is highly dependent on the supply and demand of energy resources, the consumption of imported energy does not decrease even in the period of very high oil prices. In view of these circumstances, technology development and application of energy saving in the building sector is considered as a very important field among energy consumption fields.

Efficient use of energy in buildings is an important factor that has a direct impact on landlords and the national infrastructure industry.

In particular, unreasonable energy use in buildings is also associated with inefficient operation and management of the facilities in the building. For example, the fact that 20% of the summer's electricity demand is the share of the cooling load in the building's total load indicates that cooling load has a significant effect on peak power and power reserves. Occupies. Energy saving methods in such buildings include architectural planning approaches and facility approaches that improve the operating efficiency of energy-using devices and systems. Among these approaches, in the field of facilities, it is required to create a proper environment and to design energy consumption and environmental conservation and to operate an efficient facility system.

Accordingly, the present invention has been proposed to solve the conventional inconvenience, cold water supply temperature to increase the energy use efficiency while maintaining a comfortable indoor environment of the building by changing the cold water supply temperature of the refrigerator in the building remotely from the building energy management system It is intended to provide a control device and method.

 Cold water supply temperature control device in the building energy management system of the present invention for achieving the above object, the monitoring unit for monitoring the refrigerator system in real time; Analyze the trend of historical statistical data of the freezer system, determine whether the freezer cold water supply temperature changes according to the freezer capacity and air conditioning load of the freezer system, and use the monitoring information obtained through monitoring when the freezer cold water supply temperature needs to be changed. A control unit for performing a control for changing the cold water supply temperature of the refrigerator to a set control value; And a storage unit which stores at least one or more of past statistical data, monitoring information, main items for monitoring, and information for changing a cold water supply temperature.

In the cold water supply temperature control apparatus in the building energy management system of the present invention, the control unit controls to change the cold water supply temperature of the refrigerator when an alarm occurs due to abnormal operation of the refrigerator after the cold water supply temperature of the refrigerator is changed. Do it again.

In the cold water supply temperature control apparatus in the building energy management system of the present invention, the control unit, after changing the cold water supply temperature of the refrigerator, checks the energy consumption amount according to the analysis result by analyzing the monitoring information obtained by monitoring the refrigerator system. . .

In the cold water supply temperature control apparatus in the building energy management system of the present invention, the control unit applies preset basic data of the refrigerator system to the simulation, derives the first control value through simulation according to environmental variables, and After adjusting the first control value derived from the statistical data to set the second control value, changing the cold water supply temperature of the freezer to the set second control value, and using the monitoring information obtained by monitoring the freezer system in real time. The second control value is corrected to set the final control value, and the control for changing the cold water supply temperature of the refrigerator is performed with the set final control value.

In the cold water supply temperature control apparatus in the building energy management system of the present invention, the control unit analyzes the trend of the freezer statistical data to identify past cold preventive water and freezer power consumption to grasp the application period of the cold water supply temperature control of the freezer. The cold water is the value obtained by subtracting the preset temperature from the daily average temperature value obtained by dividing the maximum temperature and the minimum temperature by two.

In the apparatus for controlling cold water supply temperature in a building energy management system of the present invention, the controller may control the cold water of the refrigerator to be monitored in real time when the indoor measurement value included in the real-time monitored result information is lower than the reference value included in the input indoor environment data. After checking the supply temperature, it is determined whether the cold water supply temperature is changed.

Cold water supply temperature control method in the building energy management system of the present invention for achieving the above object comprises the steps of analyzing the trend of the historical statistical data of the refrigerator system; Monitoring the freezer system in real time; Determining whether the chilled water supply temperature of the refrigerator is changed according to the freezing capacity of the refrigerator and air conditioning load; And performing a control to change the cold water supply temperature of the freezer to a control value set by using the monitoring information obtained through monitoring, when the cold water supply temperature of the freezer is required to be changed.

In the cold water supply temperature control method in the building energy management system of the present invention, analyzing the trend of the pre-stored statistical data of the refrigerator, the step of identifying the past cold water; Identifying a freezer power consumption; And identifying the application period of the cold water supply temperature control of the refrigerator by applying the identified cold prevention water and the refrigerator power consumption.

In the cold water supply temperature control method in the building energy management system of the present invention, the step of determining whether the cold water supply temperature of the refrigerator changes, the step of checking the air conditioning load ratio using the monitoring information; Comparing the indoor measured value and the reference value included in the monitored indoor environment information; And if the indoor measured value is lower than the reference value, and comparing the confirmed air conditioning load factor and the refrigeration capacity of the freezer comprising the step of determining whether the cold water supply temperature changes.

A cold water supply temperature control method in a building energy management system according to the present invention, comprising: applying preset basic data of the refrigerator system to a simulation and deriving a first control value through simulation according to environmental variables; Correcting the first control value derived using past statistical data to set a second control value; Changing the cold water supply temperature of the freezer to the set second control value; Correcting the second control value according to the monitoring information obtained by real-time monitoring of the refrigerator system to set a final control value; And changing the cold water supply temperature of the refrigerator to the set final control value.

The present invention changes the chilled water supply temperature of the refrigerator slightly to a set control value using past statistical data and monitoring information obtained through real-time monitoring, thereby maintaining the pleasant indoor environment of the building based on systematic data of the heat source device of the building. By operating efficiently, the energy consumption can be reduced.

In addition, the present invention is energy-saving effect by changing the supply temperature setting of the refrigerator within a range that satisfies the conditions for securing the safety factor of the heat source equipment and the comfort of the indoor room by periodically monitoring the season or use status in the building energy management system Has the effect of optimizing.

1 is a block diagram showing the structure of a typical refrigerator.
2 is a block diagram illustrating a structure of a cold water supply temperature control device of a refrigerator in a building energy management system according to an exemplary embodiment of the present invention.
3 is a flowchart illustrating a method for controlling supply temperature of a refrigerator in a building energy management system according to an exemplary embodiment of the present invention.
4 is a graph illustrating an example of energy consumption reduction according to a change in the chiller cold water supply temperature according to an exemplary embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description and the accompanying drawings, detailed description of well-known functions or constructions that may obscure the subject matter of the present invention will be omitted. It should be noted that the same constituent elements are denoted by the same reference numerals as possible throughout the drawings.

Prior to the explanation, the NOC BEMS (Network Operating Center Building Energy Management System) is a system for improving energy performance while maintaining a comfortable indoor environment in a building. In addition, it analyzes energy consumption and analyzes environmental variables by time zone, and based on this, provides energy saving service to save energy by increasing efficiency of building energy.

In case of providing energy saving service by applying a refrigerator, the building energy management system monitors the seasonality or usage status periodically to satisfy the conditions for securing the safety factor of the refrigerator and the comfort of the indoor occupants. You can change the setting. For example, if the freezer cooling capacity (rated capacity) is greater than the air conditioning load (cold water temperature difference * flow rate * specific heat), the cold water temperature setting can be changed according to the cooling load.

Hereinafter, an embodiment of the present invention will be described with respect to the apparatus and method for controlling the cold water supply temperature of the refrigerator while performing the operating state monitoring and automatic control of the refrigerator system of the various equipment system in the building in the building energy management system.

 First, referring to FIG. 1 attached to the refrigerator system, the refrigerator system 10 may include a refrigerator 11, a cooling tower 12, a cold water coil 13, and the like, and supply cold water of a building energy management system. According to the temperature control, the chiller cold water supply temperature may be adjusted by an administrator to maintain a comfortable environment in the room.

In addition, the building energy management system may monitor the cooling water supply / inlet temperature, the cold water supply / inlet temperature and the flow rate of the refrigerator 11 while monitoring the operating state of the refrigerator system 10. Here, the cold water supply temperature for controlling in the embodiment of the present invention refers to the temperature of the cold water discharged to the cold water coil 13 on the basis of the refrigerator 11. On the other hand, prior to the cold water supply temperature control, the manager reviews the indoor environment management data, that is, the indoor temperature / humidity management index, and reviews the indoor temperature / humidity management standard document that is being managed, that is, the comfort management index for each building. To the building energy management system.

Next, a structure of a cold water supply temperature control device in a building energy management system for controlling a cold water supply temperature of a refrigerator according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 is a block diagram illustrating a structure of a cold water supply temperature control device of a refrigerator in a building energy management system according to an exemplary embodiment of the present invention.

Referring to FIG. 2, the apparatus for controlling cold water supply temperature of a refrigerator 100 may include an input unit 110, a monitoring unit 120, a control unit 130, an output unit 140, a communication unit 150, and a storage unit 160. It can be configured to include.

The input unit 110 receives indoor environment management data from the manager. Here, the indoor environment data may be room temperature / humidity data managed by an administrator, and may be stored in the storage unit 160 and used for controlling cold water supply temperature later. In addition, the input unit 110 generates a user input signal corresponding to a user's request or information according to a user's operation, and may be implemented by various input means that are currently commercialized or that can be commercialized in the future. For example, a keyboard In addition to general input devices such as a mouse, a joystick, a touch screen, a touch pad, and the like, gesture input means for detecting a user's motion and generating a specific input signal can be included.

The monitoring unit 120 may monitor real-time energy monitoring and period-by-period energy monitoring of the refrigerator system 10, facility / control, indoor environment, or alarm. In particular, the monitoring unit 120 monitors the indoor environment and the refrigerator 11 through various sensors and measuring instruments installed in the indoor or refrigeration system 10, that is, monitors the preset main items in real time to control the monitored result information. The controller 130 transmits the monitored results to the controller 130 by monitoring the refrigerator 11 to which the energy saving service is applied according to the set change value. Here, the main items monitored in real time include the outside air temperature / humidity, room temperature / humidity, cold water supply temperature, cold water return temperature, cooling water supply temperature, cooling water return temperature, cold water flow rate, cooling water flow rate, cold water pump power consumption, cooling tower power consumption, Cooling water pump power consumption and freezer power consumption may be included. In addition, it may further include other items necessary for the cold water supply temperature control of the refrigerator (11).

Looking at these main items, the outside air temperature / humidity is an item to examine the cold water (CDD) pattern at the outside air temperature. The room temperature / humidity is an item for determining the air conditioner load followability by comparing the room set temperature with the real time monitoring temperature. The cold water supply temperature and the cold water return temperature are for checking the range of the cold water supply temperature and the cold water return temperature, and confirming whether a temperature difference value (ΔT) between the cold water supply temperature and the cold water return temperature is secured. The cold water flow rate is an item for confirming the cold water flow rate pattern of the refrigerator 11 before performing cold water supply temperature control. Refrigerator power consumption is an item for checking the power consumption pattern of the refrigerator 11 before performing cold water supply temperature control compared to the power consumption of the refrigerator, cooling tower, cooling water pump, and cold water pump. Cooling water supply temperature is an item for confirming the cooling water supply temperature lower limit. Cooling water return temperature is an item to check whether the cooling water supply temperature and the temperature difference value is secured. The cooling water flow rate is an item for confirming the change in power consumption of the cooling water pump and for checking the cooling load.

In addition, the monitoring unit 120 monitors changes in cooling load, power consumption of the refrigeration system and individual equipment, cold water supply temperature, cold water return temperature, etc. after performing cold water temperature supply control with the final control value set by the controller 130. .

The controller 130 controls the overall operation of the cold water supply temperature control device 100. In particular, according to an embodiment of the present invention, the control unit 130 analyzes the trend of the statistical data of the refrigerator system 10 previously stored in the storage unit 160, and uses the inputted indoor environmental management data and the monitored main items. The control of the cold water supply temperature change of the refrigerator 11 is performed.

Specifically, the control unit 130 analyzes the trend of the statistical data for each day / month / day / quarter / half year / season of the refrigerator system and the cooling load, and compares the energy of the cooling degree water (CDD) and the refrigerator system in the middle year of the previous year. The consumption amount is checked to determine the application period of the cold water supply temperature control according to the cold water supply temperature control. Here, the comparative analysis items for analyzing the trend of the statistical data for each day / month / day / quarter / half / season is as shown in Table 1 below.

No. Process
Value Alarm Type X-axis Y-axis Y'-axis Remarks Name Unit Name Unit Name Unit One CDD vs Refrigerator Power Consumption vs Cooling Tower Power Consumption vs Coolant Pump Power Consumption vs Cold Water Pump Power Consumption - time January Freezer energy consumption TOE
Ton of Oil Equivalent Outside temperature
℃ - 2 Cold water supply temperature vs cold water return temperature vs coolant supply temperature vs coolant return temperature January Cold water return temperature ℃ Cold water supply temperature ℃ - - -

Here, the power consumption of the refrigerator is dependent on the variable of the external temperature, the coolant is calculated by subtracting the preset temperature (for example, 18 degrees) from the daily average temperature, and counting as 0 when the day average temperature is 18 degrees or less. do. The daily average temperature can be calculated by dividing the sum of the highest and lowest temperatures by two (= (highest temperature + lowest temperature) / 2).

The controller 130 checks the air conditioning load (cooling / heating load) and the air conditioning load rate (cooling / heating load rate) by analyzing the monitoring information obtained through real-time monitoring transmitted from the monitoring unit 120, and freezing the freezer 11. The capacity (rated capacity) is compared to determine whether the cold water supply temperature has changed. Here, the value for the air conditioning load can be calculated by multiplying all of the cold water temperature difference, flow rate, and specific heat, and the air conditioning load ratio is a percentage obtained by dividing the cooling heat amount by the rated cooling heat amount for a certain period of time, in order to keep the indoor air in a comfortable state. The amount of heat that must be released to the outside per unit time.

The controller 130 compares the monitored indoor measured value (measured humidity) with a reference value (referenced humidity) included in the inputted indoor environment management data to determine whether the indoor humidity condition is satisfied. Accordingly, when the indoor measurement humidity is lower than the reference humidity, the controller 130 checks the cold water supply temperature of the refrigerator 11 from the result information monitored in real time through the monitoring unit 120 to determine whether the cold water supply temperature can be changed. More specifically, the determination of whether the cold water supply temperature can be changed determines that the cold water supply temperature is changed when the freezing capacity is greater than the air conditioning load ratio. Here, the change of the cold water supply temperature is made in the direction of raising the cold water supply temperature. For example, the controller 130 may change the cold water supply temperature of the refrigerator 11 when the air conditioning load ratio is greater than or equal to the preset first value (50%) and the air conditioning load ratio is greater than or equal to the preset second value (20%). It can be judged that. On the other hand, when the indoor humidity conditions are not satisfied, the cold water supply temperature of the refrigerator 11 is lowered to ensure indoor comfort.

In addition, in the embodiment of the present invention, not only the indoor humidity but also the room temperature may be applied, and when the indoor temperature condition is not satisfied, the controller 130 may determine the overload of the freezer 11. The cold water supply temperature. If the indoor measurement value (humidity or temperature) is less than the reference value, the controller 130 determines whether the cold water supply temperature is changed, and if the cold water supply temperature is required to be changed, the cold water supply temperature is changed.

In order to control the cold water supply temperature change, specifically, the control unit 130 applies the basic data set in the specifications of the refrigerator system 10 to the simulation, and the environmental variables (for example, the outside air temperature, the room temperature, the living room). Rate, CO ₂ concentration, etc.) to derive a first control value for the first optimal cold water supply temperature control. Next, the controller 130 sets the second control value by correcting the first control value using the collected statistical data in order to derive a predicted value for controlling the second optimal cold water supply temperature. Finally, the controller 130 changes the cold water supply temperature to the second control value and then corrects the cold water supply temperature according to the site through monitoring information obtained by monitoring the refrigerator system 10 in real time. To adjust the final control value.

Accordingly, the controller 130 controls to change the cold water supply temperature of the refrigerator system 10 to the final control value.

Meanwhile, the controller 130 directly controls the freezer system 10 or requests a manager for cold water supply temperature control to control the cold water supply temperature of the freezer 11 so that the manager controls the freezer system 10. To change the cold water supply temperature of the freezer (11). To this end, the controller 130 may generate a job request information for controlling the refrigerator system 10 and transmit the job request information to the manager to change the cold water supply temperature of the refrigerator 11. Accordingly, the manager changes and operates the cold water supply temperature of the refrigerator 11 in the work request information, and informs the cold water supply temperature control device 100 that the cold water supply temperature has been changed.

In addition, the controller 130 analyzes the monitoring information obtained by monitoring the refrigerator system 10 operated according to the changed cold water supply temperature, checks whether or not an alarm occurs due to an abnormal operation of the refrigerator system 10, and thereby freezer system 10. When the alarm occurs in the), the control for changing the cold water supply temperature of the refrigerator 11 to the final control value is performed again. In this case, the alarm is generated when the measured value in the refrigerator system 10 is continuously operated for a predetermined number of times or for a predetermined time or more in a predetermined period of time or more than an error range compared to the criterion. In the embodiment of the present invention, for example, If the humidity is lower than the standard humidity or if the chilled water supply temperature of the freezer is changed, an alarm will be triggered.If the temperature exceeds the error range (± 5) of the appropriate cold water supply temperature (predetermined value) according to the load rate, an alarm will be triggered. do.

The control unit 130 performs the cold water supply temperature control and analyzes the energy consumption through monitoring, checks how much energy is saved according to the analyzed energy consumption, and provides information on the energy consumption information and the confirmed energy result. The energy saving report data is managed by day / month / day / quarter / half year / season, and the energy saving report data is delivered to the manager. When the controller 130 instructs the manager to review or add work according to the energy saving report data, the controller 130 registers information on the review result or additional work as an example of the energy saving item. The private energy savings reporting data can be provided to managers in various forms, including web pages, e-mails, and printed materials.

The output unit 140 is a means for providing a user recognition of the operation result or state of the cold water supply temperature control device 100. For example, a display unit for visually outputting through a screen or a speaker for outputting an audible sound. And the like. In particular, in the present invention, the output unit 140 configures and displays the screen so that the administrator can input the indoor environment management data, the result information monitored by the monitoring unit 120 and the job generated by the control unit 130 Request information and energy saving report data can be displayed on the screen.

The communication unit 150 performs communication for remotely controlling the refrigerator system 10 and transmits and receives data by connecting to a terminal device of an administrator, and other terminal devices through various communication methods as well as wired and wireless methods. Send and receive data with In addition, data may be transmitted and received using one or more communication methods, and for this purpose, the communication unit 150 may include a plurality of communication modules that transmit and receive data according to different communication methods. In particular, in the present invention, the communication unit 150 transmits the job request information and the energy saving report data generated by the control unit 130 to the terminal device of the manager. In addition, the communication unit 150 receives a notification message for changing the cold water supply temperature of the refrigerator, and transmits the information received from the terminal device of the manager to the controller 130 to register as an example of an energy saving item.

 Meanwhile, the communication unit 150 may receive the indoor environment management data as a message including the indoor environment management data standard document from the administrator's terminal device.

The storage unit 160 stores programs and data necessary for the operation of the cold water supply temperature control device 100, and basically stores an operation program of the cold water supply temperature control device 100, and further, the refrigerator system 10. Statistics data, input indoor environment management data and monitored result information, information necessary for generation of work request information, and the like are stored. The storage unit 160 may include an optical media such as a magnetic media such as a hard disk, a floppy disk, and a magnetic tape, a compact disk read only memory (CD-ROM), and a digital video disk (DVD). Magnetic-optical media such as floppy disks, and ROM, random access memory (RAM), and flash memory.

Next, a method for controlling a cold water supply temperature of a refrigerator in a cold water supply temperature control apparatus of a building energy management system according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

3 is a flowchart illustrating a method for controlling a cold water supply temperature of a refrigerator in a building energy management system according to an exemplary embodiment of the present invention.

Referring to FIG. 3, in operation 1101, the cold water supply temperature control device 100 receives indoor environment management data. Here, the indoor environment data may be indoor temperature / humidity data managed by the manager, and may be input from the manager or received through the communication unit 150.

In step 1102, the cold water supply temperature control apparatus 100 analyzes the trend of historical statistical data of the pre-collected refrigeration system 10 to check the cooling degree day (CDD: Cooling Degree Day) and the power consumption of the refrigerator in the middle of the previous year to supply the cold water. Determine the duration of application of temperature control. Here, when past statistical data is not prepared, monitoring data collected for a predetermined period may be accumulated and used.

In operation 1103, the cold water supply temperature control device 100 compares the monitored indoor measurement value (measurement humidity or temperature) with a reference value (reference humidity or temperature) included in the input indoor environment management data to determine whether the indoor setting condition is satisfied. Check it.

As a result of the check, when the indoor measured value is lower than the reference value and does not satisfy the indoor setting condition, in step 1104, the cold water supply temperature control apparatus 100 determines whether the cold water supply temperature of the refrigerator 11 may be changed. The determination of whether the cold water supply temperature can be changed is determined based on the air conditioning load rate of the refrigerator system 10 confirmed through monitoring information obtained through real-time monitoring. When the refrigeration capacity is greater than the air conditioning load rate, the cold water supply temperature is determined to be changed. do.

If it is determined that the cold water supply temperature needs to be changed, in step 1105, the cold water supply temperature control device 100 performs a control for changing the cold water supply temperature of the refrigerator 11.

First, the cold water supply temperature control device 100 applies the basic data set in the specifications of the refrigerator system 10 to the simulation, and applies to the environmental variables (for example, outside air temperature, room temperature, occupancy rate, CO ₂ concentration, etc.). The first control value for controlling the cold water supply temperature is primarily derived through the simulation.

Then, the cold water supply temperature control apparatus 100 secondly corrects the derived first control value by using the collected statistical data to derive a second control value in order to derive a predicted value for cold water supply temperature control. Set it.

Finally, after the cold water supply temperature control device 100 changes the cold water supply temperature to the second control value, the second control value for correcting the cold water supply temperature according to the site situation through real-time monitoring of the refrigerator system 10. To adjust the final control value. Accordingly, the cold water supply temperature control device 100 finally changes the cold water supply temperature of the refrigerator 11 by using the final control value set as described above, thereby performing cold water supply temperature control.

Thereafter, if necessary in step 1106, the cold water supply temperature control device 100 may request a manager to change the cold water supply temperature. To this end, the cold water supply temperature control apparatus 100 may generate the work request information applying the final control value and transmit the generated work request information to the manager to change the cold water supply temperature of the refrigerator 11. Accordingly, the manager changes the cold water supply temperature of the refrigerator 11 and transfers the changed result information to the cold water supply temperature control device 100.

Thereafter, in step 1107, the cold water supply temperature control apparatus 100 checks whether an alarm has occurred according to the abnormal operation of the refrigerator system 10 during the application period of the cold water supply temperature control, and if an alarm occurs, the process proceeds to step 1105 and again cold water is performed. Perform supply temperature control. Here, the alarm is an alarm for abnormal operation of the refrigerator 11, and after the cold water supply temperature is changed, when the indoor measurement value (humidity or temperature) is lower than the reference value (humidity or temperature) or the cold water supply temperature of the refrigerator 11 is changed. Will occur.

After changing the cold water supply temperature of the freezer (11), in step 1108 the cold water supply temperature control device 100 monitors the freezer 11 and the indoor environment in real time, and the energy saving results and effects of changing the cold water supply temperature Analyze That is, the cold water supply temperature control device 100 may analyze the total energy saving effect by analyzing the energy saving facility, energy increase facility, proper temperature and flow rate, required investment cost, etc. when the cold water supply temperature is changed. In addition, it is possible to calculate the expected fuel consumption through the monitoring result information, to obtain the expected savings and savings, and to calculate the expected savings by applying the fuel cost according to the expected savings. At this time, the cold water supply temperature control device 100 monitors changes in cooling load, power consumption, cold water supply temperature, cold water return temperature, etc. of the cooling load, the refrigeration system 10 and individual equipments after performing the cold water supply temperature control to the set final control value. The total energy consumption of the refrigerator system 10 before and after the cold water supply temperature control is analyzed.

Accordingly, the cold water supply temperature control device 100 checks how much energy is saved according to the analyzed total energy consumption, and applies energy consumption information and the confirmed result information to report the energy saving report data by period ( Day / month / day / year / quarter / half year / seasonal) The cold water supply temperature control device 100 transmits the energy saving report data thus generated to the manager. Then, when receiving a request or request for additional work according to the result of the review according to the energy saving data from the manager, the cold water supply temperature control device 100 may register the information on the review or additional work as an example of the energy saving item. have.

When generating the energy saving report data, the cold water supply temperature control device 100 may generate the energy saving report data by comparing and analyzing the energy saving check item using historical data and applying the analysis result. The energy saving confirmation items may include comparison of refrigerator power usage, hourly enthalpy and power (energy) usage analysis before and after cold water supply temperature control, freezer period COP analysis, and outside air enthalpy versus power (energy) consumption items.

Refrigerator power consumption comparison item is to check the savings effect by comparing the refrigerator power consumption of the previous year and the refrigerator power consumption of the year, and can compare the data on a monthly / year basis.

The enthalpy per hour and energy usage analysis items before and after implementation are items for confirming the savings effect with the graphs of external enthalpy and energy consumption per hour before and after the cold water supply temperature control, and data can be compared on a daily basis.

The term “Coefficient Of Performance” (hereinafter referred to as “COP”) in the Refrigerator is an item that compares COP before and after the same year of the previous year and cold water supply temperature control in the same period. Can be. Here, COP is a ratio of the freezing capacity to the heating amount input to the regenerator by the freezing effect obtained by freezing with respect to the work (W) to be supplied under a certain condition, and the cooling capacity or the heat quantity Q _e is the input heat quantity (A). It can be calculated by dividing by _W ). Here, the cooling capacity or the heat amount Q _e is a value obtained by multiplying the cold water flow rate, the specific heat of water (1.0 at room temperature), the specific weight of water (1,000 at room temperature), and the cold water supply temperature minus the cold water supply temperature. The input calorie value is a product of fuel consumption and fuel calorific value.

The outside air enthalpy vs. energy consumption per hour item selects the days when the air conditioning load is stabilized and draws a graph before and after implementation to check the effect within the target period. Data can be compared on a daily / monthly basis.

On the other hand, when comparing the energy saving effect precisely, it is necessary to select and judge a period similar to the outside air temperature / humidity and air conditioning load, cooling water supply / return temperature, etc. other than the cold water temperature setting value of the refrigerator 11. However, since the factors affecting energy consumption are so complex, it is possible to evaluate the energy saving effect simply by comparing the increase or decrease of the air conditioning energy consumption and the cooling water supply quantity.

The energy consumption reduction effect according to the change in the cold water supply temperature of the refrigerator as described above is as shown in FIG. 4, and the cold water supply temperature is set slightly higher, for example, the energy consumption rate is set to about 2 degrees to 9 degrees. % Can be reduced.

In addition, the cold water supply temperature change according to an embodiment of the present invention is to be applied when the load of the freezer, such as the intermediate machine is particularly light load, the bypass flow rate decreases as the cold water supply temperature is increased, but the fluctuation of the total cold water flow rate does not occur. Do not.

The method for controlling cold water supply temperature of the refrigerator according to the present invention may be implemented in software form readable by various computer means and recorded on a computer readable recording medium. Here, the recording medium may include program commands, data files, data structures, and the like, alone or in combination. Program instructions to be recorded on a recording medium may be those specially designed and constructed for the present invention or may be available to those skilled in the art of computer software. For example, the recording medium may be an optical recording medium such as a magnetic medium such as a hard disk, a floppy disk and a magnetic tape, a compact disk read only memory (CD-ROM), a digital video disk (DVD) Includes a hardware device that is specially configured to store and execute program instructions such as a magneto-optical medium such as a floppy disk and a ROM, a random access memory (RAM), a flash memory, do. Examples of program instructions may include machine language code such as those generated by a compiler, as well as high-level language code that may be executed by a computer using an interpreter or the like. Such hardware devices may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It will be apparent to those skilled in the art. Furthermore, although specific terms are used in this specification and the drawings, they are used in a generic sense only to facilitate the description of the invention and to facilitate understanding of the invention, and are not intended to limit the scope of the invention.

The present invention relates to an apparatus and method for controlling a cold water supply temperature in a building energy management system. The present invention relates to a method of systematically controlling a heat source device of a building while maintaining a comfortable indoor environment of a building by changing a chilled water supply temperature of a refrigerator to a predetermined control value. It is effective to reduce the energy consumption by operating efficiently based on.

In addition, the present invention is energy-saving effect by changing the supply temperature setting of the refrigerator within a range that satisfies the conditions for securing the safety factor of the heat source equipment and the comfort of the indoor room by periodically monitoring the season or use status in the building energy management system Has the effect of optimizing.

10: freezer system 11: freezer
100: cold water supply temperature control device
110: input unit 120: monitoring unit
130: control unit 140: output unit
150: communication unit 160: storage unit

Claims (10)

A monitoring unit for monitoring the refrigerator system in real time; Analyze the trend of the historical statistical data of the refrigerator system, determine whether to change the cold water supply temperature of the freezer according to the freezing capacity and air conditioning load of the freezer, and if necessary to change the cold water supply temperature of the freezer, monitoring obtained through monitoring A control unit which performs a control for changing the cold water supply temperature of the refrigerator to a control value set using information; And
A storage unit storing at least one of the past statistical data, the monitoring information, main items for monitoring, and information for changing the cold water supply temperature;
Cold water supply temperature control device in a building energy management system comprising a. The apparatus of claim 1,
After the cold water supply temperature of the refrigerator is changed, if an alarm occurs due to abnormal operation of the refrigerator, cold water supply temperature control in the building energy management system, characterized in that the control for changing the cold water supply temperature of the refrigerator again. Device. The apparatus of claim 1,
Cold water supply temperature control device in a building energy management system, characterized in that after the cold water supply temperature of the refrigerator is changed, the energy consumption is confirmed according to the analysis result by analyzing the monitoring information obtained by monitoring the refrigerator system. The apparatus of claim 1,
Apply the preset basic data of the refrigerator system to a simulation, derive a first control value through simulation according to an environmental variable, correct the first control value derived using the statistical data of the past, and control the second control value. After setting the, and changing the cold water supply temperature of the refrigerator to the set second control value, by using the monitoring information obtained by monitoring the refrigerator system in real time, correcting the second control value to set the final control value, Cold water supply temperature control device in a building energy management system, characterized in that for performing control for changing the cold water supply temperature of the refrigerator to a set final control value. The method of claim 1,
Analyzing the trend of the refrigerator statistical data to check the past cold water and the refrigerator power consumption to determine the application period of the cold water supply temperature control of the refrigerator,
The cold protection water is a value obtained by subtracting a preset temperature from a daily average temperature value obtained by dividing a maximum temperature and a minimum temperature by 2, and building energy management, wherein the day average temperature is less than a preset temperature. Cold water supply temperature control system in the system. The apparatus of claim 1,
When the indoor measurement value included in the real-time monitored result information is lower than the reference value included in the input indoor environment data, after checking the cold water supply temperature of the monitored refrigerator in real time, it is determined whether the cold water supply temperature is changed. Cold water supply temperature control device in the building energy management system, characterized in that. Analyzing the trend of historical statistical data of the freezer system;
Monitoring the freezer system in real time;
Determining whether the chilled water supply temperature of the refrigerator is changed according to the freezing capacity of the refrigerator and air conditioning load; And
If it is necessary to change the cold water supply temperature of the refrigerator, performing control for changing the cold water supply temperature of the refrigerator to a control value set by using monitoring information obtained through monitoring;
Cold water supply temperature control method in a building energy management system comprising a. The method of claim 7, wherein analyzing the trend of the pre-stored statistical data of the refrigerator,
Identifying past cold water;
Identifying a freezer power consumption; And
Determining the application period of the cold water supply temperature control of the refrigerator by applying the identified cold prevention water and the refrigerator power consumption;
Cold water supply temperature control method in a building energy management system comprising a. The method of claim 7, wherein the determining whether the cold water supply temperature of the refrigerator is changed,
Confirming an air conditioning load ratio using the monitoring information;
Comparing the indoor measured value and the reference value included in the monitored indoor environment information; And
When the indoor measurement value is lower than the reference value, determining whether the cold water supply temperature is changed by comparing the identified air-conditioning load ratio with the freezing capacity of the freezer;
Cold water supply temperature control method in a building energy management system comprising a. The method of claim 7, wherein performing the control for changing the cold water supply temperature of the refrigerator,
Applying preset basic data of the refrigerator system to a simulation and deriving a first control value through simulation according to an environmental variable;
Setting a second control value by correcting the first control value derived using the past statistical data;
Changing a cold water supply temperature of the refrigerator to a set second control value;
Correcting the second control value according to monitoring information obtained by real-time monitoring of the refrigerator system to set a final control value; And
Changing the cold water supply temperature of the refrigerator to a set final control value;
Cold water supply temperature control method in a building energy management system comprising a.

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