KR102405415B1 - Measurement and verification system for real-time evaluation of building energy saving effects - Google Patents

Abstract

The present invention relates to a performance verification system for real-time evaluation of building energy saving effects. and to calculate the expected building energy consumption value and compare it with the actual building energy consumption value to enable real-time evaluation and stable building energy management of the effects of building energy saving technology.
For example, the first building energy usage data is calculated based on the building energy usage billing data during the base period before the building energy saving technology is introduced, and the first building energy usage data and the first influence variable during the base period a baseline generator for constructing a baseline relational model defining a correlation between the two; Calculating the second building energy usage data during the project period to which the building energy saving technology, which is the target of verification, is applied, and establishing a project line relational model that defines the correlation between the second building energy usage data and the second influence variable during the project period project line generation unit; By substituting the value of the first influence variable with the value of the second influence variable in the baseline relational model to calculate the adjusted building data usage adjustment data in which the first building data usage data is adjusted, the second influence variable and an adjustment baseline generation unit for constructing an adjusted baseline relational model defining a correlation between the adjusted building energy usage adjustment data; and building energy saving technology evaluation verification for evaluating and verifying the building energy saving effect for the building energy saving technology by comparing the second building energy usage data and the adjusted building energy usage data according to the adjusted baseline relational model A performance verification system for real-time evaluation of building energy saving effects including wealth is disclosed.

Description

MEASUREMENT AND VERIFICATION SYSTEM FOR REAL-TIME EVALUATION OF BUILDING ENERGY SAVING EFFECTS

An embodiment of the present invention relates to a performance verification system for real-time evaluation of a building energy saving effect.

Performance verification (M&V, Measurement & Verification) of building energy saving technology is to verify the effect of applying energy saving technology by performing regression analysis based on the measured energy consumption and influence variable values.

Performance verification, which is generally conducted in the past, is performed after a certain period of reduction activities, and is a concept to perform future evaluations on the effect of energy saving activities using monthly energy consumption billing data. In addition, since a process of directly organizing and refining data such as daily/monthly units using a calculator or Excel is required, it takes a lot of manpower and time.

Meanwhile, BEMS (Building Energy Management System) collects building data in real time through a number of sensors and measuring equipment for efficient energy use in buildings. Although the facility systems of buildings are sometimes operated through automatic control or optimal control, in most cases, the absolute authority is given to the subjective judgment of the operator for the final overall building operation.

In this case, the operator actively establishes an operation strategy based on his or her experience and intuition, but also passively controls the operation of facility systems according to the indoor and outdoor environmental conditions occurring in the building. However, it is difficult to explain that such subjective operation always accurately diagnoses and responds to various situations occurring within the building.

Laid-open Patent Publication No. 10-2013-0133605 (published date: December 09, 2013) Registered Patent Publication No. 10-2085956 (Registration Date: March 02, 2020)

An embodiment of the present invention derives a model of the relationship between building energy consumption and influence variables, grasps influence variables affecting energy consumption close in real time, calculates expected building energy consumption values, and compares them with actual building energy consumption values It provides a performance verification system that enables real-time evaluation and stable building energy management as well as the effectiveness of building energy saving technologies.

The performance verification system for real-time evaluation of the building energy saving effect according to an embodiment of the present invention calculates the first building energy usage data based on the building energy usage billing data during the base period before the introduction of the building energy saving technology, and , a baseline generation unit for constructing a baseline relational model defining a correlation between the first building energy usage data and a first influence variable during the base period; Calculating the second building energy usage data during the project period to which the building energy saving technology, which is the target of verification, is applied, and establishing a project line relationship model that defines the correlation between the second building energy usage data and the second influence variable during the project period project line generation unit; By substituting the value of the first influence variable with the value of the second influence variable in the baseline relational model to calculate the adjusted building data usage adjustment data in which the first building data usage data is adjusted, the second influence variable and an adjustment baseline generation unit for constructing an adjusted baseline relational model defining a correlation between the adjusted building energy usage adjustment data; and building energy saving technology evaluation verification for evaluating and verifying the building energy saving effect for the building energy saving technology by comparing the second building energy usage data and the adjusted building energy usage data according to the adjusted baseline relational model includes wealth.

In addition, building energy usage that calculates building energy usage prediction data by applying each predicted influence variable for the time points at which building energy usage is to be predicted to the project line relationship model evaluated and verified through the building energy saving technology evaluation verification unit prediction data calculation unit; a building energy usage actual data calculation unit that detects building energy usage in real time and calculates building energy usage actual data; And when the actual building energy usage exceeds a preset reference value than the expected building energy usage by comparing the building energy usage prediction data with the building energy usage actual data, information on the type of energy source that is exceeded and the excess amount of the energy source It may further include a building energy use monitoring unit that transmits an energy source abnormality warning notification signal comprising a.

In addition, when the energy source, the influence variable, and the inquiry period are set respectively, at least among the energy saving amount, energy saving cost, and energy saving rate, which is a comparison result between the building energy usage prediction data and the building energy usage actual data from the building energy usage monitoring unit It may further include a building energy usage monitoring data providing unit that provides one inquiry result, but provides a warning display for items exceeding the reference value.

In addition, when the energy source and the inquiry period are respectively set, a baseline data providing unit that inquires the first building energy usage data from the baseline generation unit and provides a corresponding inquiry result may be further included.

In addition, when the energy source and the inquiry period are respectively set, the second building energy usage data is inquired from the project line generation unit, and a project line data providing unit that provides a corresponding inquiry result may be further included.

In addition, when the energy source and the inquiry period are set, respectively, the adjustment baseline data providing unit may further include an adjustment baseline data providing unit that inquires the building energy usage adjustment data from the adjustment baseline generation unit and provides a corresponding inquiry result.

In addition, when the energy source and the inquiry period are respectively set, the second building energy usage data and the adjusted building energy usage data from the building energy saving technology evaluation verification unit are at least among the energy saving amount, energy saving cost, and energy saving rate. It may further include a building energy saving evaluation verification information providing unit that provides one inquiry result.

In addition, the building energy use monitoring unit converts information about the type of excess energy source included in the energy source abnormality warning notification signal, the excess detection time, the expected energy usage, the actual energy usage, the amount of energy savings, and the energy saving rate into electronic Braille. It is output through the display of the manager communication terminal, and for each converted Braille, at least one of a different vibration pattern, vibration intensity, sound effect pattern, and sound effect size is applied to allow the manager to read the information contained in the energy source abnormality warning notification signal. Electronic Braille services can be provided for this purpose.

According to the present invention, a model of the relationship between building energy consumption and influence variables is derived, the influence variables affecting energy consumption are closely identified in real time, and the expected building energy consumption value is calculated and compared with the actual building energy consumption value. It is possible to provide a performance verification system that enables real-time evaluation and stable management of building energy as well as the effectiveness of energy-saving technologies.

1 is a schematic diagram illustrating an overall operation description of a performance verification system for real-time evaluation of a building energy saving effect according to an embodiment of the present invention.
2 is a block diagram showing the overall configuration of a performance verification system for real-time evaluation of a building energy saving effect according to an embodiment of the present invention.
3 is a graph exemplarily illustrating a method of calculating adjusted baseline energy data according to an embodiment of the present invention.
4 is a view exemplarily showing information provided through a building energy usage monitoring data providing unit according to an embodiment of the present invention.
5 is a diagram illustrating a method of providing an energy source abnormality warning notification signal by a building energy use monitoring unit according to an embodiment of the present invention.
6 is a view exemplarily showing information provided through a baseline data providing unit, a project line data providing unit, and an adjusted baseline data providing unit according to an embodiment of the present invention.

Terms used in this specification will be briefly described, and the present invention will be described in detail.

The terms used in the present invention have been selected as currently widely used general terms as possible while considering the functions in the present invention, but these may vary depending on the intention or precedent of a person skilled in the art, the emergence of new technology, and the like. In addition, in a specific case, there is a term arbitrarily selected by the applicant, and in this case, the meaning will be described in detail in the description of the corresponding invention. Therefore, the term used in the present invention should be defined based on the meaning of the term and the overall content of the present invention, rather than the name of a simple term.

In the entire specification, when a part "includes" a certain element, this means that other elements may be further included, rather than excluding other elements, unless otherwise stated. In addition, terms such as "...unit" and "module" described in the specification mean a unit that processes at least one function or operation, which may be implemented as hardware or software, or a combination of hardware and software. .

Hereinafter, with reference to the accompanying drawings, the embodiments of the present invention will be described in detail so that those of ordinary skill in the art can easily implement them. However, the present invention may be embodied in several different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

1 is a schematic diagram showing the overall operation description of the performance verification system for real-time evaluation of the building energy saving effect according to an embodiment of the present invention, and FIG. 2 is for real-time evaluation of the building energy saving effect according to an embodiment of the present invention It is a block diagram showing the overall configuration of the performance verification system, FIG. 3 is a graph exemplarily shown to explain a method for calculating adjusted baseline energy data according to an embodiment of the present invention, and FIG. 4 is an embodiment of the present invention It is a view exemplarily showing information provided through a building energy usage monitoring data providing unit according to an example, and FIG. 5 is a method of providing an energy source abnormality warning notification signal of a building energy usage monitoring unit according to an embodiment of the present invention 6 is a diagram exemplarily showing information provided through a baseline data providing unit, a project line data providing unit, and an adjustment baseline data providing unit according to an embodiment of the present invention.

1 and 2 , the performance verification system 10 for real-time evaluation of the building energy saving effect according to an embodiment of the present invention includes a baseline generation unit 11, a project line generation unit 12, and adjustment Baseline generation unit 13, building energy saving technology evaluation verification unit 14, building energy usage prediction data calculation unit 15, building energy usage actual data calculation unit 16, building energy usage monitoring unit 17, Building energy usage monitoring data providing unit (18), baseline data providing unit (19), project line data providing unit (20), adjustment baseline data providing unit (21), and building energy saving evaluation verification information providing unit (22) may include at least one of

The baseline generation unit 11 calculates the first building energy usage data based on the building energy usage billing data during the base period before the building energy saving technology is introduced, and calculates the calculated first building energy usage data and the corresponding A baseline relational model that defines the correlation between the first influencing variables during the base period may be constructed.

The base period means the energy use period (usually a total period of one year) of the building 1 to be evaluated in which no building energy saving technology is introduced, and the first building energy use data is stored during the energy use period. It can be calculated based on billing data for building energy use (obtained from BEMS (Building Energy Management System)). In addition, the first influence variable is a variable that can affect the first building energy usage data, and may include temperature, HDD (heating degree days), CDD (cooling degree days), CO2 concentration, number of occupants, and building occupancy. However, it is not limited to only the variables for this, but may include more various variables that can affect the building energy consumption more. In addition, the baseline relational model is defined as a relational expression that mathematically defines the correlation between the first building energy consumption and the first influence variable, and can be obtained through regression analysis.

The project line generation unit 12 calculates the second building energy usage data during the project period to which the verification target building energy saving technology (or building energy saving device or system) is applied, and during the second building energy usage data and the project period A project line relationship model that defines the correlation between the second influence variables of .

The project period means the energy use period of the building 1 to be evaluated after the pre-established building energy saving technology is introduced (usually a total period of one year), and the second building energy use data is BEMS (Building Energy Management System) for the period of use of that energy. In addition, the second influence variable is a variable that can affect the second building energy usage data, and may include temperature, HDD (heating degree days), CDD (cooling degree days), CO2 concentration, number of occupants, and building occupancy. However, it is not limited to only the variables for this, but may include more various variables that can affect the building energy consumption more. In addition, the project line relational model is defined as a relational expression that mathematically defines the correlation between the second building energy consumption and the second influence variable, and can be obtained through regression analysis.

The adjustment baseline generation unit 13 calculates the adjusted building data usage adjustment data in which the first building data usage data is adjusted by replacing the value of the first influence variable with the value of the second influence variable in the baseline relation model. And, it is possible to build an adjusted baseline relational model that defines the correlation between the second influence variable and the adjusted building energy usage adjustment data.

For example, if the air conditioner energy consumption in July 2020 during the base period was 100kW, but the air conditioner usage in July 2021 during the project period in which the building energy saving technology was introduced was 200kW, the building energy saving technology was introduced in the 21st year. In spite of the fact that energy is not saved, the wrong result can be obtained. Accordingly, when the first influencing variable is found that exceeds the preset reference value for the project period by comparing the influencing variables between the base period and the project period by month, the value of the first influencing variable is added to the baseline relational model (relational expression). 2 It is possible to adjust the baseline relational model (relational expression) by substituting the value of the influence variable. If the external temperature value of July 2020 (the first influence variable) during the baseline period is 28 degrees and the external temperature value of July 2021 (the second influence variable) of the project line is 45 degrees, the external temperature of the project period It is difficult to fairly verify the effectiveness of the building energy saving technology for the project period because the air conditioner usage must have increased rapidly as it itself is much higher than the external temperature of the base period. Accordingly, the first influencing variable is detected in the base period compared to the project period, and the value of the second influencing variable corresponding to the project period is used instead of the detected value of the first influencing variable in the baseline relational model (relational expression). By applying to , it is possible to partially adjust the existing baseline relational model (relational expression).

To explain more simply, it is assumed that there is a base-period energy value Y and an energy value Z used in the project period, as shown in FIG. 3, where the base-period energy value Y is, for example, Y=aX1 ² +bX2 (where X1 is HDD value, X2 is CDD value, and a and b are different fixed constants that specify the relationship between energy consumption and influence variables), and the energy value Z for the project period is, for example, Assuming that the relation of Z = aX1' ² +bX2' (where X1' is HDD value and X2' is CDD value) holds, the adjusted baseline energy Y' is Y' = aX1' ² +bX2' can be newly defined as In this way, the baseline relation model adjusted by adjusting some of the influencing variables included in the base period so that the influencing variables between the two periods become equal conditions so that the comparison between the project period and the base period in which the building energy saving technology is introduced is normally performed. (relational expression) can be derived, and the 'adjusted baseline relational model (relational expression)' derived in this way is compared with the project line relational model (relational expression) according to the passage of time, thereby providing more accurate verification of the effect of building energy saving technology and to allow evaluation to take place.

The building energy saving technology evaluation verification unit 14 compares the second building energy usage data with the adjusted building energy usage data according to the adjusted baseline relational model to evaluate the building energy saving effect for the building energy saving technology and verifiable. As described above, the 'adjusted baseline relational model (relational expression) and project line relational model (relational equation) By comparison, more accurate verification and evaluation of the effectiveness of building energy saving technologies can be made, and evaluation and verification can be made for each energy source, influence variable, and time (year, month, time). The energy source according to the present embodiment may include electricity, gas, district heating, and all (electric + gas + district heating).

The building energy usage prediction data calculation unit 15 evaluates and verifies the project line relationship model through the building energy saving technology evaluation verification unit 14 for each predicted influence variable for the time points at which the building energy usage is to be predicted. can be applied to calculate building energy usage forecast data.

For example, assuming that the present is January 01, 2022, and assuming that the time to predict the building energy consumption is January 02, 2022, the impact variable at the time to be predicted, that is, January 02, 2022 If (temperature, HDD (heating degree days), CDD (cooling degree days), CO2 concentration, number of occupants, building occupancy, etc.) is applied to the project line relational model, predictive data on building energy consumption by energy source can be calculated. .

The building energy usage actual data calculation unit 16 can calculate the building energy usage actual data by detecting the building energy usage in real time, and a number of It can be calculated by collecting real-time data from sensors.

The building energy usage monitoring unit 17 compares the building energy usage prediction data and the building energy usage actual data over time, and when the actual building energy usage exceeds a preset reference value than the expected building energy usage, the excess energy An energy source abnormality warning notification signal including information on the type of source (electricity, gas, district heating, total) and the excess amount of the corresponding energy source may be transmitted to the manager 2 .

Continuing the above example, if the electric energy consumption was 100 kW at the predicted time of January 02, 2022, but the actually measured electric energy consumption on January 02, 2022 was 200 kW, a problem occurred in the system related to the electric energy source It can be recognized that this has been done, and the information thus identified can be transmitted and reported to the manager, or an energy saving operation can be performed by outputting a control signal for energy saving to the corresponding energy source system.

The building energy use monitoring unit 17, as shown in FIG. 5, includes the type of excess energy source included in the energy source abnormality warning notification signal, the excess detection time, the expected energy consumption, the actual energy consumption, the energy saving amount, and the energy saving rate. information is converted into electronic braille and output through the display of the manager communication terminal (2), and at least one of a different vibration pattern, vibration intensity, sound effect pattern, and sound effect size is applied to each converted braille to allow the manager to control the energy source An electronic braille service may be provided so that the information included in the abnormal warning notification signal can be read.

For example, as shown in FIG. 5 , as an energy source abnormality warning notification signal, 'electronic braille 1' may be displayed, and the black circle of 'electronic braille 1' is set to 'vibration pattern 1', and white The circle is set as 'vibration pattern 2' and when the administrator touches the corresponding braille on the screen, each circle that vibrates in a different pattern is identified and the contents (excess energy source type, excess detection time, expected energy use, actual energy usage, energy saving amount, energy saving rate) can be recognized.

In addition, as shown in FIG. 5 , 'electronic braille 2' may be displayed, and the black circle of 'electronic braille 1' is set to 'vibration intensity 1', and the white circle is set to 'vibration intensity 2'. When the user touches the corresponding Braille dots on the screen, the contents (excess energy source type, excess detection time, expected energy consumption, actual energy consumption, energy saving amount, energy saving rate) are identified by identifying each circle vibrating with different intensity. make it recognizable.

In addition, when each Braille is touched, the pattern of the sound effect is different for each Braille representing the black circle and the white circle, or the content to be conveyed by identifying each circle by varying the size of the sound effect (excess energy source type, excess detection time) , expected energy consumption, actual energy consumption, energy saving amount, energy saving rate) can be recognized.

The building energy usage monitoring data providing unit 18 sets the energy source, the influence variable, and the inquiry period, respectively, the comparison result between the building energy usage prediction data and the building energy usage actual data from the building energy usage monitoring unit 17 At least one inquiry result of energy saving amount, energy saving cost, and energy saving rate may be provided, but warning marks for items exceeding the standard value may be applied and provided.

For example, as shown in Fig. 4, the type of influence variable to be inquired along with the inquiry period (per period, current (real-time)), energy source (electricity, gas, district heating, total) standards, energy consumption, and time You can select or set the /day/month inquiry criteria, respectively, and according to the setting information, it is possible to display the comparison result with the actual building energy consumption data by calculating the building energy usage forecast value calculation based on the internal algorithm. In addition, it calculates the result of comparing the data on the impact variable, the predicted building energy usage data, and the actual building energy usage data value. can

The baseline data providing unit 19, when the energy source and the inquiry period are set, respectively, inquires the first building energy usage data from the baseline generation unit 11, and displays the inquiry result as shown in FIG. This can be provided through graphs.

The project line data providing unit 20, when the energy source and the inquiry period are set, respectively, inquires the second building energy usage data from the project line generation unit 12, and displays the inquiry result as shown in FIG. It can be provided through graphs and tables (Excel table).

The adjustment baseline data providing unit 21, when the energy source and the inquiry period are set, respectively, inquires the building energy usage adjustment data from the adjustment baseline generation unit 13, and displays the inquiry result as shown in FIG. It can be provided through graphs and tables (Excel table) as well.

The building energy saving evaluation verification information providing unit 22 compares the second building energy usage data and the adjusted building energy usage data from the building energy saving technology evaluation verification unit 14 when the energy source and the inquiry period are respectively set At least one of the results of energy saving, energy saving cost, and energy saving rate may be provided.

For example, as shown in FIG. 6, energy consumption reduction amount, reduction rate, reduction cost evaluation (performance verification) and inquiry (hour/day/month) functions are provided, and energy-saving technology is applied (before improvement - baseline) If you select or set the inquiry period for and after application (after improvement - project line), energy source (electricity, gas, district heating, overall) standards, and hour/day/month performance verification standards, the internal algorithm-based By performing performance verification, it is possible to calculate the adjusted baseline, calculate the amount of energy savings, cost savings, and reduction rates, and display data and information about them.

What has been described above is only one embodiment for implementing the performance verification system for real-time evaluation of the building energy saving effect according to the present invention, and the present invention is not limited to the above embodiment, and is claimed in the claims below. As described above, without departing from the gist of the present invention, it will be said that the technical spirit of the present invention exists to the extent that various modifications can be made by anyone with ordinary knowledge in the field to which the invention pertains.

10: Performance verification system for real-time evaluation of building energy saving effects
11: Baseline generator
12: Project line generation unit
13: adjustment baseline generator
14: Building energy saving technology evaluation verification department
15: Building energy usage prediction data calculation unit
16: Building energy consumption actual data calculation unit
17: Building energy use monitoring department
18: Baseline data providing unit
19: Project line data provider
20: adjustment baseline data providing unit
21: Building energy saving evaluation verification information provision department

Claims (7)

The first building energy usage data is calculated based on the building energy usage billing data during the base period before the building energy saving technology is introduced, and the correlation between the first building energy usage data and the first influence variable during the base period a baseline generation unit that builds a baseline relational model defining
Calculating the second building energy usage data during the project period to which the building energy saving technology, which is the target of verification, is applied, and establishing a project line relational model that defines the correlation between the second building energy usage data and the second influence variable during the project period project line generation unit;
By substituting the value of the first influence variable with the value of the second influence variable in the baseline relational model to calculate the adjusted building energy usage adjustment data in which the first building energy usage data is adjusted, the second influence variable and an adjustment baseline generation unit for constructing an adjusted baseline relational model defining a correlation between the adjusted building energy usage adjustment data;
A building energy saving technology evaluation verification unit that compares the second building energy usage data and the adjusted building energy usage data according to the adjusted baseline relational model to evaluate and verify the building energy saving effect for the building energy saving technology ;
Building energy usage prediction data that calculates building energy usage prediction data by applying each predicted influence variable for the time points at which building energy usage is to be predicted to the project line relationship model evaluated and verified through the building energy saving technology evaluation verification unit output unit;
a building energy usage actual data calculation unit that detects building energy usage in real time and calculates building energy usage actual data; and
By comparing the building energy usage forecast data with the building energy usage actual data, if the actual building energy usage exceeds a preset threshold value than the expected building energy usage, information on the type of energy source exceeded and the excess amount of the energy source included Including a building energy use monitoring unit that transmits an energy source abnormality warning notification signal to the manager,
The building energy use monitoring unit,
Information on the type of excess energy source, excess detection time, expected energy use, actual energy use, energy saving amount, and energy saving rate included in the energy source abnormality warning notification signal is converted into electronic braille and output through the display of the manager communication terminal, , by applying at least one of a different vibration pattern, vibration intensity, sound effect pattern, and sound effect size to each converted Braille to provide an electronic Braille service so that the administrator can read the information included in the energy source abnormality warning notification signal A performance verification system for real-time evaluation of the characteristic building energy saving effect.
delete According to claim 1,
When the energy source, influence variable, and inquiry period are respectively set, at least one of energy saving amount, energy saving cost, and energy saving rate, which is a comparison result between the building energy usage prediction data and the building energy usage actual data from the building energy usage monitoring unit A performance verification system for real-time evaluation of building energy saving effect, characterized in that it further comprises a building energy usage monitoring data providing unit that provides an inquiry result, but provides a warning display for items exceeding the reference value.
According to claim 1,
When the energy source and the inquiry period are respectively set, the building energy saving effect further comprises a baseline data providing unit that inquires the first building energy usage data from the baseline generation unit and provides the inquiry result. Performance verification system for real-time evaluation.
According to claim 1,
When the energy source and the inquiry period are respectively set, the building energy saving effect further comprises a project line data providing unit that inquires the second building energy usage data from the project line generation unit and provides the inquiry result. Performance verification system for real-time evaluation.
According to claim 1,
When the energy source and the inquiry period are respectively set, the building energy saving effect further comprising an adjustment baseline data providing unit that inquires the building energy usage adjustment data from the adjustment baseline generation unit and provides a corresponding inquiry result performance verification system for real-time evaluation of
According to claim 1,
When the energy source and the inquiry period are respectively set, the comparison result between the second building energy usage data and the adjusted building energy usage data from the building energy saving technology evaluation verification unit is at least one of energy saving amount, energy saving cost, and energy saving rate. A performance verification system for real-time evaluation of the building energy saving effect, characterized in that it further comprises a building energy saving evaluation verification information providing unit that provides an inquiry result.

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