KR102480280B1 - Building energy management system - Google Patents

Abstract

The building energy management system includes first to nth building controllers and a building monitoring device. The first to n-th building controllers are respectively installed in first to n-th (provided that n is an integer of 2 or more) buildings located within a preset regional range, and the first to n-th power consumption of the first to n-th buildings The rate of change is derived, respectively, and the first to nth power consumption rate of change are transmitted at predetermined time intervals. The building monitoring device receives the first to nth power consumption rate of change for each time period, calculates a standard normal distribution for the first to nth power consumption rate of change, and the standard normal distribution among the first to nth building controllers. and transmits a power consumption check signal to a target building controller having a target power consumption change rate out of a predetermined setting range.

Description

Building energy management system {BUILDING ENERGY MANAGEMENT SYSTEM}

The present invention relates to a building energy management system (BEMS). More specifically, the present invention relates to a building energy management system that performs integrated energy management for buildings located in a preset regional range (eg, a regional range in which power consumption types are determined to be the same or similar). it's about

As various social problems such as global warming and climate change, such as disasters, abnormal temperatures, and diseases, emerge, energy saving and efficiency are attracting attention. In particular, since energy consumption in the building sector accounts for 22% of the total energy consumption in Korea, it is important to reduce energy consumption in the building sector in terms of energy saving and efficiency. In general, in terms of energy consumption in the building field, unnecessary energy consumption mainly occurs in heating type, cooling type, and lighting type. For example, heating energy is consumed inside the building even though the outside temperature is sufficiently high, cooling energy is consumed inside the building even though the outside temperature is sufficiently low, or the outside lighting level is sufficiently bright. There are many cases where lighting energy is consumed inside, but the effect is insignificant because it mainly relies on people's voluntary participation or effort (i.e., passive method) through publicity to seek energy saving and efficiency. . For this reason, building energy management systems for energy saving and efficiency have been introduced, but most of them are for specific buildings and have limitations in that they do not reflect the energy consumption characteristics of the area where the building is located.

One object of the present invention is to determine the energy consumption of buildings located in a predetermined regional range (eg, a regional range in which power consumption types are determined to be the same or similar), information commonly applied to the regional range (eg, , time information, season information, weather information, etc.) by limiting it to an appropriate level, thereby properly reflecting the energy consumption characteristics of the area where the buildings are located, and implementing a building energy management system that can effectively reduce and increase energy efficiency. is to provide However, the object of the present invention is not limited to the above-mentioned object, and may be expanded in various ways without departing from the spirit and scope of the present invention.

In order to achieve one object of the present invention, a building energy management system according to embodiments of the present invention is installed in each of the first to nth (where n is an integer of 2 or more) buildings located within a preset regional range, , first to n-th building controllers deriving first to n-th power consumption change rates of the first to n-th buildings, respectively, and transmitting the first to n-th power consumption change rates at predetermined time intervals, and the Receiving the first to n-th power consumption rate of change at each time, calculating a standard normal distribution for the first to n-th power consumption rate of change, and setting on the standard normal distribution among the first to n-th building controllers It may include a building monitoring device that transmits a power consumption check signal to a target building controller having a target power consumption change rate out of range.

According to one embodiment, each of the first to n-th building controllers may additionally transmit tagging information recording power consumption characteristics of each of the first to n-th buildings to the building monitoring device.

According to an embodiment, the building monitoring device may reflect the power consumption specifics recorded in the tagging information when calculating the standard normal distribution.

According to an embodiment, each of the first to n-th power consumption change rates includes power consumption change rates for each type derived by classifying internal facilities included in each of the first to n-th buildings according to preset power consumption types. can do.

According to an embodiment, the power consumption type may include at least one of a heating type, a cooling type, and a lighting type.

According to an embodiment, the building monitoring device may widen the set interval as the deviation of the first to nth power consumption rate of change increases, and narrow the set interval as the deviation decreases.

According to one embodiment, the building monitoring device may additionally adjust the setting section based on at least one or more of time information, season information, and weather information commonly applied to the regional range.

According to an embodiment, upon receiving the power consumption check signal, the target building controller may check operating states of internal facilities included in the target building in which the target building controller is installed.

According to an embodiment, the target building controller may return tagging information recording that the operating state corresponds to the operating suitability criterion to the building monitoring device when the operating state corresponds to the operating suitability criterion of the target building.

According to an embodiment, the target building controller changes the operating state if the operating state does not correspond to the operation suitability criterion, and sends a warning signal indicating that the operating state has been changed to the user or operation manager of the target building. It can be transmitted to electronic devices.

The building energy management system according to embodiments of the present invention may include first to nth (provided that n is an integer of 2 or more) installed in each of the first to nth buildings, deriving first to nth power consumption change rates of the first to nth buildings, respectively, and transmitting the first to nth power consumption change rates at predetermined time intervals. Receives first to nth power consumption change rates from the nth building controllers and preset time intervals, calculates a standard normal distribution for the first to nth power consumption rate of change, and among the first to nth building controllers, By including a building monitoring device for transmitting a power consumption check signal to a target building controller having a target power consumption change rate outside a set range on a standard normal distribution, energy consumption of buildings located in a preset regional range is commonly applied to the regional range It can be limited to an appropriate level based on information (eg, time information, season information, weather information, etc.), and accordingly, while appropriately reflecting the energy consumption characteristics of the area where the buildings are located, energy saving and Efficiency can be effectively carried out. However, the effects of the present invention are not limited to the above-mentioned effects, and may be variously extended without departing from the spirit and scope of the present invention.

1 is a block diagram showing a building energy management system according to embodiments of the present invention.
FIG. 2 is a diagram illustrating an example of a power consumption change rate transmitted from a building controller to a building monitoring device in the building energy management system of FIG. 1 .
3 is a diagram illustrating an example in which a building monitoring device determines a target building controller in the building energy management system of FIG. 1 .
4 is a flowchart illustrating an example in which a building monitoring device adjusts a set section in the building energy management system of FIG. 1 .
5 is a flowchart illustrating an example in which a building controller checks operating states of internal facilities in the building energy management system of FIG. 1 .

For the embodiments of the present invention disclosed in the text, specific structural or functional descriptions are only exemplified for the purpose of explaining the embodiments of the present invention, and the embodiments of the present invention may be implemented in various forms and the text It should not be construed as being limited to the embodiments described above.

Since the present invention can have various changes and various forms, specific embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to a specific form disclosed, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The terms may be used for the purpose of distinguishing one component from another. For example, a first element may be termed a second element, and similarly, a second element may be termed a first element, without departing from the scope of the present invention.

It is understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, but other elements may exist in the middle. It should be. On the other hand, when an element is referred to as “directly connected” or “directly connected” to another element, it should be understood that no other element exists in the middle. Other expressions describing the relationship between elements, such as "between" and "directly between" or "adjacent to" and "directly adjacent to", etc., should be interpreted similarly.

Terms used in this application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly dictates otherwise. In this application, terms such as "comprise" or "having" are intended to indicate that the described feature, number, step, operation, component, part, or combination thereof exists, but that one or more other features or numbers are present. However, it should be understood that it does not preclude the presence or addition of steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and unless explicitly defined in this application, they are not interpreted in an ideal or excessively formal meaning. .

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in more detail. The same reference numerals are used for the same components in the drawings, and redundant descriptions of the same components are omitted.

1 is a block diagram showing a building energy management system according to embodiments of the present invention, and FIG. 2 is a diagram showing an example of a rate of change in power consumption transmitted by a building controller to a building monitoring device in the building energy management system of FIG. 1 3 is a diagram showing an example in which the building monitoring device determines a target building controller in the building energy management system of FIG. 1 .

Referring to Figures 1 to 3, the building energy management system 100 is the first to nth (however, n is an integer of 2 or more) building controllers (120-1, ..., 120-n) and building monitoring Device 140 (eg, a cloud server installed in a central management center, etc.) may be included. At this time, the first to n-th building controllers (120-1, ..., 120-n) and the building monitoring device 140 are located spaced apart from each other within a preset regional range, and accordingly, the first to the th Wired and wireless communication may be performed between n building controllers 120-1, ..., 120-n and the building monitoring device 140.

The first to n-th building controllers 120-1, ..., 120-n are located in the first to n-th buildings 110-1, ..., 110-n located within a preset regional range. Each can be installed. For example, the regional range may be set as a regional range determined to have the same or similar power consumption type. Accordingly, information (eg, time information, seasonal information, weather information, etc.). Accordingly, as the power consumption check is performed on the first to nth buildings 110-1, ..., 110-n belonging to the regional range, the energy consumption characteristics of the regional range can be appropriately reflected. . On the other hand, the first to n-th building controllers 120-1, ..., 120-n are the first to n-th of the first to n-th buildings 110-1, ..., 110-n The power consumption change rates PR1, ..., PRn are derived, respectively, and the first to nth power consumption change rates PR1 of the first to nth buildings 110-1, ..., 110-n , ..., PRn) may be transmitted to the building monitoring device 140 at each preset time. In one embodiment, each of the first to n-th power consumption change rates PR1 , ..., PRn is an interior included in each of the first to n-th buildings 110-1, ..., 110-n. It may include power consumption change rates for each type derived by classifying facilities according to preset power consumption types. In this case, the preset power consumption type may include at least one of a heating type, a cooling type, and a lighting type. For example, as shown in FIG. 2, the mth building controller 120-m (where m is an integer equal to or greater than 2 and less than or equal to n) sets the internal facilities included in the mth building 110-m to a heating type. , It is divided into cooling type and lighting type, and the power consumption change rate (ie, heating power consumption change rate (PR(HEAT))) of the heating type internal facilities included in the mth building (110-m), the mth building (110-m) Change rate of power consumption of cooling type internal facilities included in -m) (ie, cooling power consumption change rate (PR(COOL))) and power consumption change rate of lighting type internal facilities included in the mth building 110-m (ie, lighting power consumption change rate (PR(LIGHT))), heating power consumption change rate (PR(HEAT)), cooling power consumption change rate (PR(COOL)) and lighting of the mth building 110-m The mth power consumption change rate (PRm) including the power consumption change rate (PR(LIGHT)) may be transmitted to the building monitoring device 140 at predetermined time intervals. In this case, the building monitoring device 140 determines the first to n-th power consumption change rates PR1, ..., PRn of the first to n-th buildings 110-1, ..., 110-n. In calculating the standard normal distribution (SND) for the power consumption, it is classified according to the preset power consumption type (eg, the standard normal distribution (SND) for heating type, the standard normal distribution (SND) for cooling type, lighting Selecting a target building controller to transmit the power consumption check signal (CS1, ..., CSn) for each preset power consumption type by generating the standard normal distribution (SND) for each type).

The building monitoring device 140 determines the first to n-th power consumption change rates PR1, ..., PRn of the first to n-th buildings 110-1, ..., 110-n for each preset time. is received, and the standard normal distribution (SND) for the first to nth power consumption change rates PR1, ..., PRn of the first to nth buildings 110-1, ..., 110-n ), and among the first to nth building controllers 120-1, ..., 120-n, the target building having a target power consumption change rate outside the set interval (CI) on the standard normal distribution (SND) Power consumption check signals (CS1, ..., CSn) can be transmitted to the controller. At this time, the set interval (CI) on the standard normal distribution (SND) is the first to nth power consumption change rates (PR1) of the first to nth buildings 110-1, ..., 110-n. , ..., PRn) denotes a range in which it can be determined that the power consumption change rate is normal. That is, because the energy consumption characteristics of the region to which the first to nth buildings 110-1, ..., 110-n belong are similar (ie, the first to nth buildings 110-1, . .., 110-n), the trend of cooling or heating according to the weather is similar, and the trend of lighting according to the time of day is similar), the building monitoring device 140 is The standard normal distribution ( SND) to transmit power consumption check signals (CS1, ..., CSn) to buildings having power consumption change rates that deviate greatly from the average. In one embodiment, the building monitoring device 140 is the first to nth power consumption change rates (PR1, ..., PRn of the first to nth buildings 110-1, ..., 110-n) As the deviation of ) increases, the set interval (CI) on the standard normal distribution (SND) is widened, and the first to nth power consumption of the first to nth buildings 110-1, ..., 110-n As the deviation of the change rates PR1, ..., PRn is smaller, the setting interval CI on the standard normal distribution SND can be narrowed. That is, the relatively large deviation of the first to nth power consumption change rates PR1, ..., PRn of the first to nth buildings 110-1, ..., 110-n means that the first This means that the energy consumption characteristics of the regional range to which the to nth buildings 110-1, ..., 110-n belong are not constant, and in this case, the first to nth buildings 110-1, . .., 110-n) since it is not possible to relatively accurately determine the first to nth power consumption change rates PR1, ..., PRn as abnormal states, that is, target power consumption change rates, the standard normal distribution (SND ) to expand the setting interval (CI) on. In addition, the relatively small deviation of the first to nth power consumption change rates PR1, ..., PRn of the first to nth buildings 110-1, ..., 110-n means that This means that the energy consumption characteristics of the region to which the 1 to nth buildings 110-1, ..., 110-n belong are constant, and in this case, the first to nth buildings 110-1, . .., 110-n) since it can be relatively accurately determined that the first to nth power consumption change rates (PR1, ..., PRn) are abnormal states, that is, target power consumption change rates, the standard normal distribution (SND ) to reduce the setting interval (CI) on.

In one embodiment, the building monitoring device 140 includes time information, season information, and weather information commonly applied to the regional range to which the first to nth buildings 110-1, ..., 110-n belong. A set interval (CI) on the standard normal distribution (SND) may be additionally adjusted based on at least one or more factors. In other words, the building monitoring device 140 may include energy consumption characteristics (eg, time information, season information, weather information), the first to nth power consumption change rates PR1, ..., PRn of the first to nth buildings 110-1, ..., 110-n are set to a steady state, that is, It is to additionally adjust the range determined as the non-target power consumption change rate. For example, since the power consumption of lighting-type internal facilities is small during the daytime, while the power consumption of lighting-type internal facilities is large during the nighttime, the set interval on the standard normal distribution (SND) for the lighting type ( CI) may be determined differently depending on whether the time zone is a daytime zone or a nighttime zone. For another example, since the power consumption of the cooling-type internal facilities is small in winter while the power consumption of the cooling-type internal facilities is large in summer, the set interval (CI) on the standard normal distribution (SND) for the cooling type ) may be determined differently depending on whether the season is summer or winter. For another example, since the power consumption of heating-type internal facilities is small in summer while the power consumption of heating-type internal facilities is large in winter, the set interval on the standard normal distribution (SND) for heating type ( CI) may be determined differently depending on whether the season is summer or winter. However, this is exemplary and is based on at least one of time information, season information, and weather information commonly applied to the regional range to which the first to nth buildings 110-1, ..., 110-n belong. Thus, a method of adjusting the setting interval (CI) on the standard normal distribution (SND) may be selected in various ways. According to the embodiment, each of the first to n-th building controllers 120-1, ..., 120-n is the first to n-th buildings 110-1, ..., 110-n, respectively. Tagging information (TI) recording power consumption specifics may be additionally transmitted to the building monitoring device 140 . In this case, the building monitoring device 140 may reflect the power consumption specifics recorded in the tagging information TI when calculating the standard normal distribution (SND). For example, tagging information (TI-m) recording that the m-th building controller 120-m intentionally increased power consumption in the lighting field by a predetermined event in the m-th building 110-m is sent to the building. When transmitted to the monitoring device 140, the building monitoring device 140 adds or subtracts a predetermined value to the m power consumption change rate (PRm) of the m th building 110-m when calculating the standard normal distribution (SND) can do.

As described above, the building monitoring device 140 sends a power consumption check signal (CS1) to a target building controller having a target power consumption change rate among the first to nth building controllers 120-1, ..., 120-n. , ..., CSn) can be transmitted. For example, when it is determined that the m-th building controller 120-m is a target building controller with a target power consumption change rate, the building monitoring device 140 sends a power consumption check signal to the m-th building controller 120-m ( CSm) can be transmitted. In one embodiment, when the m-th building controller 120-m determined to be the target building controller receives the power consumption check signal CSm, the internal facilities included in the target building, that is, the m-th building 110-m Operation status can be checked. For example, when the power consumption check signal CSm indicates that it is necessary to check the power consumption of lighting-type internal facilities, the m-th building controller 120-m determined to be the target building controller determines the target building, that is, the th building controller 120-m. m Checks the operation status of the lighting type internal facilities included in the building (110-m), and if the power consumption check signal CSm indicates that the cooling type internal facilities need to be checked, the target building controller The m-th building controller 120-m determined to check the operating state of the cooling-type internal facilities included in the target building, that is, the m-th building 110-m, and the power consumption check signal CSm is the heating type If it is necessary to check the power consumption of internal facilities, the m-th building controller 120-m determined as the target building controller is the target building, that is, the inside of the heating type included in the m-th building 110-m. You can check the operating status of equipment. At this time, the m-th building controller 120-m determined to be the target building controller determines that the target building, that is, the operational state of the internal facilities included in the m-th building 110-m is the operation of the m-th building 110-m. If the suitability criterion is satisfied, the building monitoring device 140 may return tagging information TIm, which indicates that the operating state of the internal facilities corresponds to the suitability criterion for the mth building 110-m. On the other hand, the m-th building controller 120-m determined to be the target building controller is the target building, that is, the operating state of the internal facilities included in the m-th building 110-m is the operation of the m-th building 110-m. If the suitability criterion is not met, the operating state of the internal facilities is changed (eg, power off internal facilities operating unnecessarily, control internal facilities operating more than necessary to operate at an appropriate level, etc.) , A warning signal indicating that the operating state of the internal facilities has been changed may be transmitted to the electronic device of the user or manager of the target building, that is, the m-th building 110-m. Accordingly, the internal facilities of the first to nth buildings 110-1, ..., 110-n belonging to the preset regional range can automatically operate at a level suitable for the energy consumption characteristics of the regional range, A user or manager of operation of the first to nth buildings 110-1, ..., 110-n belonging to a predetermined regional range can easily manage the building at a level suitable for the energy consumption characteristics of the regional range. can

In this way, the building energy management system 100 is the first to nth buildings 110-1 located within a preset regional range (eg, a regional range determined to have the same or similar power consumption type), ..., 110-n), and the first to nth power consumption change rates PR1, ..., of the first to nth buildings 110-1, ..., 110-n PRn) is derived, and the 1st to nth power consumption change rates (PR1, ..., PRn) of the 1st to nth buildings 110-1, ..., 110-n are calculated for a preset period of time. The first to n-th building controllers 120-1, ..., 120-n respectively transmitting each and the first to n-th buildings 110-1, ..., 110-n for each preset time 1st to nth power consumption change rates (PR1, ..., PRn) of the first to nth buildings 110-1, ..., 110-n are received, and the first to nth power of the first to nth buildings 110-1, ... A standard normal distribution (SND) is calculated for the consumption change rates (PR1, ..., PRn), and among the first to nth building controllers 120-1, ..., 120-n, the standard normal distribution (SND) by including a building monitoring device 140 for transmitting a power consumption check signal (CS1, ..., CSn) to a target building controller having a target power consumption change rate outside the set interval (CI), Energy consumption of buildings located within the range can be limited to an appropriate level based on information commonly applied to the regional range (eg, time information, season information, weather information, etc.), and accordingly, the buildings are located It is possible to effectively reduce energy consumption and increase efficiency while appropriately reflecting the energy consumption characteristics of the region in which it is located. Meanwhile, the preset regional range may be set in various ways (eg, country, city, etc.) according to required conditions.

4 is a flowchart illustrating an example in which a building monitoring device adjusts a set section in the building energy management system of FIG. 1 .

Referring to Figure 4, the building monitoring device 140 is the first to nth power consumption change rates (PR1, ..., of the first to nth buildings 110-1, ..., 110-n) As the deviation of PRn) increases, the setting interval (CI) on the standard normal distribution (SND) for the first to nth power consumption change rates (PR1, ..., PRn) is widened, and the first to nth buildings As the deviation of the first to nth power consumption change rates PR1, ..., PRn of (110-1, ..., 110-n) is smaller, the first to nth power consumption change rates PR1, ..., PRn) on the standard normal distribution (SND) can be narrowed.

Specifically, the building monitoring device 140 is the first to n-th power consumption change rates (PR1, ..., PRn) of the first to n-th buildings (110-1, ..., 110-n) The deviation is derived (S110), and the deviation of the first to nth power consumption change rates PR1, ..., PRn of the first to nth buildings 110-1, ..., 110-n is It is possible to check whether it is smaller than the first reference value (S120). At this time, deviations of the first to n th power consumption change rates PR1 , ..., PRn of the first to n th buildings 110-1, ..., 110-n are greater than the first reference value. If not small (that is, the first to n th buildings 110-1, ..., 110-n), the deviation of the first to n th power consumption change rates PR1, ..., PRn is the first criterion If greater than or equal to the value), the building monitoring device 140 expands the set interval (CI) on the standard normal distribution (SND) for the first to n-th power consumption change rates (PR1, ..., PRn) (S130). On the other hand, deviations of the first to nth power consumption change rates PR1, ..., PRn of the first to nth buildings 110-1, ..., 110-n are greater than the first reference value. If small, the building monitoring device 140 of the first to nth power consumption change rates (PR1, ..., PRn) of the first to nth buildings (110-1, ..., 110-n) It may be checked whether the deviation is smaller than the second reference value smaller than the first reference value (S140). At this time, the deviation of the first to n th power consumption rate of change (PR1, ..., PRn) of the first to n th buildings 110-1, ..., 110-n is greater than the second reference value. If it is small, the building monitoring device 140 reduces (S150) the set interval (CI) on the standard normal distribution (SND) for the first to nth power consumption change rates (PR1, ..., PRn). can On the other hand, deviations of the first to nth power consumption change rates PR1, ..., PRn of the first to nth buildings 110-1, ..., 110-n are greater than the second reference value. If not small (that is, the first to n th buildings 110-1, ..., 110-n), the deviation of the first to n th power consumption change rates PR1, ..., PRn is the first criterion If smaller than the value and greater than or equal to the second reference value), the building monitoring device 140 is set on the standard normal distribution (SND) for the first to n-th power consumption change rates (PR1, ..., PRn) The interval CI may be maintained (S160). In this way, the building monitoring device 140 of the first to nth power consumption change rates (PR1, ..., PRn) of the first to nth buildings (110-1, ..., 110-n) The first to nth power consumption in consideration of the deviation (that is, according to whether the energy consumption characteristics of the regional range to which the first to nth buildings 110-1, ..., 110-n belong are constant) By adjusting the set interval (CI) on the standard normal distribution (SND) for the rates of change (PR1, ..., PRn), the first to nth buildings 110-1, ..., 110-n It is possible to more accurately determine whether the first to n th power consumption change rates (PR1, ..., PRn) are in a target power consumption state (ie, an abnormal state) or a non-target power consumption state (ie, a normal state). can

5 is a flowchart illustrating an example in which a building controller checks operating states of internal facilities in the building energy management system of FIG. 1 .

5, when the m-th building controller 120-m determined to be the target building controller receives the power consumption check signal CSm from the building monitoring device 140 (S210), the m-th building controller 120-m m) may be installed, that is, operating states of internal facilities included in the mth building 110-m may be checked (S220). Thereafter, the m-th building controller 120-m determines whether the target building, that is, whether the operation state of the internal facilities included in the m-th building 110-m corresponds to the operation suitability criterion of the m-th building 110-m. It can be confirmed (S230). At this time, when the target building, that is, the operating state of the internal facilities included in the m-th building 110-m corresponds to the operation suitability criterion of the m-th building 110-m, the m-th building controller 120-m The building monitoring device 140 records the tagging information (TIm) that indicates that the target building, that is, the operational state of the internal facilities included in the m-th building 110-m corresponds to the operation suitability criterion of the m-th building 110-m. It can be replied (S240). On the other hand, if the target building, that is, the operating state of the internal facilities included in the m-th building 110-m does not correspond to the operation suitability criteria of the m-th building 110-m, the m-th building controller (120-m ) may change the operating state of internal facilities included in the target building, that is, the m-th building 110-m (S250). For example, if the target building, that is, the operating state of the internal facilities included in the m-th building 110-m does not correspond to the operation suitability criterion of the m-th building 110-m, the m-th building controller (120-m) m) can control the internal facilities that are operating unnecessarily to be powered off and the internal facilities that are operating more than necessary to operate at an appropriate level. Thereafter, the m-th building controller 120-m sends a warning signal indicating that the operating state of internal facilities included in the target building, that is, the m-th building 110-m has changed, to the user of the m-th building 110-m. Alternatively, it may be transmitted to the electronic device of the person in charge of operation (S260). In this way, the m-th building controller 120-m determined to be the target building controller checks the operating state of the internal facilities included in the target building, that is, the m-th building 110-m, and determines the operating state in the m-th building ( 110-m) can be changed to a level suitable for the energy consumption characteristics of the area to which the m-th building belongs, and by notifying the user or operation manager of the m-th building (110-m) of this change, they can make the m-th building (110-m) m) can be made to perform building management at a level suitable for the energy consumption characteristics of the region to which the mth building 110-m belongs.

The present invention can be widely applied to a building energy management system that performs integrated energy management for buildings located in a preset regional range. On the other hand, although the present invention has been described with reference to the embodiments above, those skilled in the art will variously modify and change the present invention within the scope not departing from the spirit and scope of the present invention described in the claims below. You will understand that it can be done.

100: building energy management system 110: building
120: building controller 140: building monitoring device
PR: power consumption change rate CS: power consumption check signal
TI: Tagging Information CI: Setting Section

Claims (10)

It is installed in first to nth (where n is an integer of 2 or more) buildings located within a predetermined regional range, and derives first to nth power consumption change rates of the first to nth buildings, respectively, First to n-th building controllers respectively transmitting first to n-th power consumption change rates at preset time intervals; and
Receiving the first to n-th power consumption rate of change at each time, calculating a standard normal distribution for the first to n-th power consumption rate of change, and on the standard normal distribution among the first to n-th building controllers Including a building monitoring device that transmits a power consumption check signal to a target building controller having a target power consumption change rate outside the set range,
The building energy management system, characterized in that the building monitoring device widens the set interval as the deviation of the first to nth power consumption change rates increases, and narrows the set interval as the deviation decreases. The method of claim 1, wherein each of the first to n-th building controllers additionally transmits tagging information recording power consumption characteristics of each of the first to n-th buildings to the building monitoring device. building energy management system. The building energy management system according to claim 2, wherein the building monitoring device reflects the power consumption peculiarities recorded in the tagging information when calculating the standard normal distribution. The method of claim 1, wherein each of the first to n-th power consumption change rates includes power consumption change rates for each type derived by classifying internal facilities included in each of the first to n-th buildings according to preset power consumption types. A building energy management system characterized in that for doing. The building energy management system of claim 4, wherein the power consumption type includes at least one of a heating type, a cooling type, and a lighting type. delete The building energy management system according to claim 1, wherein the building monitoring device additionally adjusts the setting section based on at least one of time information, season information, and weather information commonly applied to the regional range. The building energy management system according to claim 1, wherein the target building controller checks operating states of internal facilities included in the target building in which the target building controller is installed when receiving the power consumption inspection signal. 9. The method of claim 8 , wherein the target building controller returns tagging information recording that the operating state corresponds to the operating suitability criterion to the building monitoring device when the operating state corresponds to the operating suitability criterion of the target building. building energy management system. The method of claim 9, wherein the target building controller changes the operating state if the operating state does not correspond to the operation suitability criterion, and sends a warning signal indicating that the operating state has been changed to a user of the target building or an operation manager. A building energy management system characterized by transmitting to electronic devices.

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