KR20140076771A - Energy remote control system based energy consumption predicting - Google Patents

Abstract

The present invention relates to an energy remote control system based on energy consumption prediction. The objective of the present invention is to provide an energy remote control system based on energy consumption predication, capable of monitoring a load in a state of classifying and registering control schedules of a fixing load and an additional load; switching the fixing load in order of a set priority when power consumption is read to be equal to or greater than a threshold; and remotely controlling the load by reflecting an energy saving pattern. Therefore, the energy remote control system of the present invention can efficiently use power, reduce power charges and suppress an overload by controlling a power insertion of the load in order of a priority to temporarily suspend the usage at the time point when the power consumption exceeds the target power due to generation of an accidental additional load, thereby stably operating a power system.

Description

[0001] ENERGY REMOTE CONTROL SYSTEM BASED ENERGY CONSUMPTION PREDICTING [0002]

More particularly, the present invention relates to an energy remote control system based on usage prediction, in which a load is monitored in a state in which a control schedule is classified by a fixed load and a control schedule when an additional load is generated, And to a remote control system based on a usage prediction based on an energy saving pattern so as to perform remote control on the load.

As is well known, the restructuring of the electric power and energy industry has been under way to build a cost-effective power and energy industry system through the establishment of a competitive market system in Korea. However, in the past, The centralized transaction policy and the passive demand management have not obtained the market-specific utility through the smooth competition mechanism.

As an effective technological solution to this problem, we can consider the improvement of the current demand management plan. In order to make the consumer's load as an active operating resource as an opportunity cost from the viewpoint of treating the load of the consumer as a wasteful fixed burial cost, it is necessary to draw the response of the consumer and to reflect the reaction to the market, It is necessary to make effective energy management by supplying energy supply and demand.

In order to do this, it is necessary to build up an infrastructure that can transfer the reaction information according to the selection of the consumer resource to the energy provider and reflect it to the market. Through this, it is necessary to build an efficient and competitive market system, And realistic demand management.

1 shows various conventional remote meter reading and control systems, which are composed of various slave devices 10, a gateway 20 and an upper server 30.

The sub-device 10 includes an AMR (Automatic Meter Reading) device 11, a meter (watt-hour meter) 12, a demand controller 13, an over-power monitor device 14 and a home automation device 15.

The gateway 20 is a wired or wireless network in which the various slave devices 10 communicate with the slave server 30 and the slave device 30 collects and monitors and manages the information acquired from the slave device 10 System.

First, AMR (Automatic Meter Reading) device 11 acquires various metering values (gas, water, hot water, calorie, power) and transmits the obtained remote meter reading information to a gateway 20 to the corresponding upper server 31 via the network. Therefore, it is possible to provide functions such as real-time monitoring of necessary data, analysis of meter reading data, month report, day report, trend report or Internet meter reading function, meter reading information by household or time zone, and charge inquiry.

The meter (watt hour meter) 12 acquires a metering value for the used power amount and provides it to the corresponding upper server 32 through the gateway 20.

The demand controller 13 provides a load control function for reducing the peak load under the control of the corresponding server 33. The demand controller 13 controls the load characteristics and the control functions according to the output method (circulation control, priority control, Control functions, seasonal or sectoral control functions, seasonal or sectoral tariff adjustment, alarm function, power usage prediction function, demand power reporting function, power usage pattern and peak power transition analysis And the like.

The over-power monitor 14 functions to alert or notify the upper server 34 via the gateway 20 when an over-current or an over-voltage occurs on a circuit such as a circuit breaker, a switch, a bus bar, a distribution board, and a switchboard.

The home automation device 15 is composed of a network system for living convenience in a residential space and various automatic operation devices, and provides a function of a living room, a crime prevention function and a telemedicine function. For example, home automation devices consist of HMI, home appliance control, remote meter reading, cell phone control, video call, parking control, unmanned delivery, security, door lock, health care,

In other words, conventionally, the function is limited to a manager by performing functions such as remote monitoring of power consumption, acquisition of corresponding power information according to the individual purpose of the product, control according to set values, arc monitoring, temperature monitoring, Due to the lack of necessary functions for effective energy management and demand management, active demand management is impossible, and there are many difficulties in responding to the market environment due to structural changes in the electric power industry.

As a basic function to be complemented with existing technology and products, various functions such as demand response function, function for participation inducement and integration of element function for various market environment should be considered.

If we look at the problems of existing technologies and products in more detail, it is impossible to reflect the responses according to the choice of customers, and it is impossible to apply various fee plans to attract customers, and it is necessary to integrate necessary functions to secure electric safety. In the case of existing watt-hour meters, there was no facility status monitoring function, power quality monitoring function, demand management control and maximum power control function.

In addition, in the case of the demand controller 14, it began to be distributed to load management operators and customers for the purpose of improving the load efficiency, which is one of the demand management measures. However, due to the limit of the unilateral and public- I can not get favor.

Considering the great advantages of efficient demand management, it is necessary for the government and related enterprises to make efforts for more active improvement, and more advanced type of demand management that can lead the active participation of the consumer, not the one-sided management type, is needed .

Demand for the development of various services and devices for demand response is expected to increase because ESP and electric power sales business are expected to be activated in accordance with the current government's ambitious renewal and decentralization policy. And there is an urgent need for this area.

In the case of the electric safety monitoring function, there is a product that detects and reports an arc and a short circuit. However, since it is expensive compared to the function and has a large size, it is difficult to secure the installation space and does not issue a cutoff command. Therefore, There may be something.

In addition, there is no overvoltage, overcurrent, and temperature sensing function, which are essential monitoring functions for electric safety and fire prevention, so it is necessary to purchase additional products and it is not easy to apply in terms of cost and space efficiency.

In terms of facility control functions, there are related control systems and building control systems. The facility management system is expensive, large in size and incompatible. In the case of a building management system (IBS, BEMS, etc.), it is installed for monitoring power and facilities in a building, lighting control, and building management. However, It was found that the actual adoption rate was very low due to the considerable high cost of up to 100 million won and the high maintenance cost after installation.

First of all, it is urgently required to acquire information collectively through an integrated and reliable device in a complex energy operating environment in which a variety of necessary information is collectively acquired and a timely and appropriate judgment is required. For this purpose, If sub-devices are purchased and installed, it will cost tens of thousands of won for installation of sub-devices and considerable installation space. Also, an additional integrated operation program is designed with individual installation of product-specific operation programs for each product operation and batch management And it faces the unreasonable reality that it must operate.

In particular, a building's energy management plan should ensure that energy is effectively managed at a priority in accordance with policy needs and that intelligent control of the load switch can be performed when additional surges or short- However, there is a problem that it is difficult to manage energy effectively because there is no such technology.

SUMMARY OF THE INVENTION The present invention has been made in view of the circumstances of the prior art described above, and it is an object of the present invention to provide a method and apparatus for monitoring a load in a state in which a load is divided into control schedules when a fixed load and an additional load are generated, And to provide an energy remote control system based on a usage prediction that allows remote control of a load to be performed by reflecting an energy saving pattern.

In order to accomplish the above object, according to a preferred embodiment of the present invention, there is provided a power supply apparatus comprising: a power supply unit connected to an electric line to supply electric power supplied from an electric line to a distribution panel side; A distribution board for distributing the power supplied from the power supply unit to the load side through a plurality of distribution ports; A power distribution port connected at one end to the distribution board and connected at the other end to a plurality of load sides to supply electric power of the distribution board for each load; A user surveillance server connected to the multiple meter reading enforcement module in a state in which information on energy interruption priorities for each load is set, for monitoring and monitoring energy usage information for each load and managing it in accordance with the enforcement priority; An upper server for storing the established energy management policy information and monitoring and managing energy usage information and enforcement information for each building and load from the user monitoring server; The energy usage information of each load mounted on the distribution panel and supplied through the power distribution port, and transmits the inspection information to the user monitoring server. In accordance with the control signal transmitted from the user monitoring server, And a multi-meter reading intermittent module for interrupting the usage of the energy meter.

Preferably, the multi-probe control module includes a switching module for interrupting power input to each load for each load.

Preferably, the user monitoring server includes a communication module for communicating the multi-probe control module and the upper server within the user monitoring server; An energy information collection server for collecting energy usage information from the multiple meter reading enforcement module; And an energy information management server for storing intermittent control information for each load for the energy use policy from the upper server and for interrupting the load of each user based on the priority of the usage policy. / RTI >

Preferably, the multi-probe control module includes: a communication module for communicating with the user monitoring server; (Voltage, current, phase, active power, reactive power, apparent power, frequency, power factor, distortion rate, demand, maximum value) by acquiring power quality information for each load and providing the power quality information to each user's monitoring server A PQ module; A meter reading sensing unit for measuring voltage, current, power, power factor, frequency, and cumulative power amount for each load; A threshold value setting unit for setting a threshold value for interrupting power input of each load by a load control schedule; A load control schedule setting unit configured to set a schedule to be switched according to priority according to a load if the detection value in the meter reading detection unit is equal to or greater than a threshold value; The control unit receives the meter reading information for each load and the meter reading information of the entire load from the meter reading sensing unit mounted on the distribution board port and controls transmission to the user monitoring server through the communication module, And a control unit for controlling the power supply of each load to be interrupted.

Preferably, the load is divided into a fixed load using normal power and a fluctuating additional load using power suddenly, and the multi-meter reading control module or the user monitoring server sets the fixed load to the intermittent schedule at the time of power- And a remote control unit configured to control the remote control unit based on the usage amount.

Preferably, the load control schedule setting unit may be configured such that the power-on priority of the load is set by reflecting the saving pattern information.

The energy remote control system based on the usage prediction according to the present invention can efficiently utilize the power by interrupting the power input of the load by each load according to the priorities in which the temporary use can be stopped at the time when the used power exceeds the target power due to the occurrence of the unexpected additional load And it is advantageous in that the electric power system can be operated stably by reducing the electricity rate and overload.

1 is a view showing various conventional remote meter reading and control systems,
FIG. 2 is a block diagram illustrating a configuration of an energy remote control system based on usage estimation according to an embodiment of the present invention;
FIG. 3 is a block diagram illustrating a configuration of a multi-meter reading enforcement module included in a usage prediction based energy remote control system according to an embodiment of the present invention;
4 is a diagram illustrating a control state of an energy remote control system based on a usage amount prediction according to an embodiment of the present invention;
FIG. 5 is a block diagram illustrating a control state of an energy remote control system based on a usage amount prediction according to an embodiment of the present invention.

Hereinafter, the present invention will be described in detail with reference to the drawings.

FIG. 2 is a block diagram illustrating a configuration of an energy remote control system based on a usage amount prediction according to an embodiment of the present invention. FIG. 3 is a block diagram illustrating a configuration of an energy remote control system based on a usage prediction according to an embodiment of the present invention. FIG. 4 is a diagram illustrating a control state of an energy remote control system based on a usage amount prediction according to an embodiment of the present invention. FIG. 5 is a block diagram illustrating a usage amount forecasting method according to an embodiment of the present invention. Based energy remote control system according to the present invention.

The energy remote control system based on usage prediction according to an embodiment of the present invention monitors a load in a state in which a load is divided into a fixed load and a control schedule when an additional load is generated, and a fixed load The system is switched according to the set priorities, and the energy saving pattern is reflected to perform the remote control for the load.

More specifically, the energy usage remote control system based on the usage prediction according to an embodiment of the present invention includes a power supply unit 40 connected to an electric wire and supplying electric power supplied from the electric wire to the distribution board 42 side.

The power supply unit 40 is a device for supplying stabilized power to the distribution board 42. The power supply unit 40 is a device for supplying stabilized power to the distribution board 42. The power supply unit 40 supplies power through one of the single- do.

The energy remote control system based on the usage prediction according to an embodiment of the present invention includes a distribution board 42 for distributing power supplied from the power supply unit 40 to a load side through a plurality of distribution ports 48; One end of which is connected to the distribution board 42 and the other end of which is connected to the side of the multiple loads 44a, 44b, 44c, .... to supply the power of the distribution board 42 by load, .

At this time, the load connected to the distribution port 48 is connected to a load such as a motor load 44a, an illumination load 44b, and a landscape illumination 44c as a general load representing a minus amount of electric power, Power supply unit 46, which is a power generation unit for supplying electric power to the electric power generating line, is connected to one of the power distribution ports 48 and the electric power supplied from the electric power utility line in the user monitoring server 60 And the power generated by the renewable power generation unit 46 are settled.

In addition, the energy usage remote control system based on the usage prediction according to an embodiment of the present invention is connected to the multi-meter reading enforcement module 50 in a state where information on energy interruption priority for each load is set, And the user monitoring server 60 monitors the communication between the multi-probe control module 50 and the upper server 30. The user monitoring server 60 monitors the multi- A communication module (62) An energy information collection server (66) for collecting energy usage information from the multiple meter reading enforcement module (50); An energy information management server (64) is configured to store the intermittent control information for each load on the energy usage policy from the upper server (30) and to control the load on each user side in accordance with the priority of the usage policy.

In addition, the energy usage remote control system according to an embodiment of the present invention stores the established energy management policy information and receives energy usage information and enforcement information for each building and load from the user monitoring server 60 And an upper server 30 for monitoring and managing the server.

More specifically, the multi-meter reading module 50 is mounted on the distribution board 42 in a board form to meter the energy usage information for each load supplied through the distribution port 48, To the server 60, and controls the power input of each load in accordance with the control signal transmitted from the user monitoring server 60. [

The energy remote control system based on the usage prediction according to an embodiment of the present invention includes a multi meter probe module 50 installed in a switchboard of a power receiving room such as a factory or a building or a user monitoring server 50 that performs energy monitoring and management through a user interface (60) or the upper server (30), or two or three configurations are all set in the control according to the energy use plan, especially the control within the predictable category, and the coping schedule for the additional load, And controls the power input to the load according to the setting.

Therefore, the energy usage remote control system based on the usage prediction according to an embodiment of the present invention controls the power supply of the load by interrupting the power supply of the load for each priority that can be temporarily stopped when the used power exceeds the target power, Efficient use of electric power, reduction of electric charges, suppression of overload, and stable operation of power system.

Meanwhile, the multi-probe control module 50 includes a communication module 74 for communicating with the user monitoring server 60. The communication module 74 includes various protocols and media It is desirable to be configured to be removable in the form of an option of various kinds of communication conversion cards (RS-485, RS-232, PLC, RF, Zigbee, Ethernet, Bluetooth, CDMA etc.).

In addition, the multi-meter reading intermittent module 50 acquires power quality information for each load within the multi-meter reading intermittent module 50 and provides the power quality information (voltage, current, phase, active power, reactive power, apparent power, And a PQ module 76 for monitoring a frequency, a power factor, a distortion rate, a demand, and a maximum value of the PQ module 76. The PQ module 76 may be configured as a package with a PQ extension module (not shown) High-performance, high-precision PQ meter (24 hours continuous data storage, 1024 sampling / cycle or more) can be added as modules. This is a configuration for coping with a special requirement of the general PQ function (less than 256 sampling / cycle) of the electronic meter 100 and a future system environment such as a distributed power system and a micro grid system.

The meter reading and controlling module 50 includes a meter reading sensor 68 for measuring voltage, current, power, power factor, frequency, and cumulative power for each load. The meter reading sensor 68 basically comprises an electric wire Preferably, a plurality of current sensors CT and voltage sensors PT are provided for detecting the current and the voltage of the electric line by each load, respectively, connected to the inlet end of the earth leakage breaker 70.

The multi-probe control module 50 includes a threshold value setting unit 82 in which a threshold value for interrupting the power-on of each load is set by a load control schedule; If the detection value of the meter reading sensor 68 is equal to or greater than the threshold value, the load control schedule setting unit 84 is provided with a schedule to be switched and controlled according to the priority according to the load. In the energy remote control system based on the usage prediction, the power is supplied to the loads within the target power category at all times. However, when the additional power load is generated and the used power exceeds the threshold value exceeding the target power, It is possible to control the power input from a load having a lower priority or a load capable of suspending temporary use according to the schedule set in the control schedule setting unit 84. [

For example, assuming that the fixed load used at all times is an LED such as shown in FIG. 4, a floodlight, a garden, etc., if the used power exceeds the target power due to the occurrence of an additional load, If the load is set to flood light, the floodlight is turned off so that intelligent energy savings can be achieved.

In addition, the multi-meter reading intermittent module 50 receives meter reading information of each load and meter reading information of the entire load from the meter reading sensor 68 mounted on the panel switch port 48, And a control unit (80) for controlling transmission of power to each load according to priority of each load according to the load control schedule setting unit (84) do.

At this time, the load is divided into fixed loads 88A, 88B, 88C .... using a constant power and a variable additional load 90 using power abruptly,

The multi-meter reading enforcement module 50 or the user monitoring server 60 or the upper server 30 is configured to remotely control the fixed load according to the enforcement schedule or to request control when the power meter reading exceeds the threshold.

Meanwhile, the load control schedule setting unit 84 may be configured so that the power-on priority of the load is set by reflecting the saving pattern information 92. [

At this time, in order to intermit the power input to the load, the multi-meter reading intermittent module 50 includes a switching module 86 for interrupting power input for each load 88 for each load.

Therefore, the energy remote control system based on the usage prediction according to the embodiment of the present invention controls the power supply of the load by interrupting the power supply of the load at a time when the used power exceeds the target power due to the occurrence of the unexpected additional load, Efficient utilization, reduction of electricity rates, and overload, thereby enabling stable operation of the power system.

Meanwhile, the energy usage remote control system based on the usage amount prediction according to the embodiment of the present invention is not limited to the above-described embodiments, but various modifications can be made within the scope of the present invention.

30: upper server, 40: power supply unit,
42: distribution board, 44: load,
46: New & Renewable Power, 48: Power port,
50: multiple meter reading module, 60: user monitoring server,
80: control unit, 82: threshold value setting unit,
84: Load control schedule setting section, 86: Switching module.

Claims (6)

A power supply unit connected to the electric line for supplying electric power supplied from the electric line to the distribution panel side;
A distribution board for distributing the power supplied from the power supply unit to the load side through a plurality of distribution ports;
A power distribution port connected at one end to the distribution board and connected at the other end to a plurality of load sides to supply electric power of the distribution board for each load;
A user surveillance server connected to the multiple meter reading enforcement module in a state in which information on energy interruption priorities for each load is set, for monitoring and monitoring energy usage information for each load and managing it according to the enforcement priority;
An upper server for storing the established energy management policy information and monitoring and managing energy usage information and enforcement information for each building and load from the user monitoring server;
The energy usage information of each load mounted on the distribution panel and supplied through the power distribution port, and transmits the inspection information to the user monitoring server. In accordance with the control signal transmitted from the user monitoring server, And a multi-meter reading intermittent module for interrupting the measurement of the energy. The method according to claim 1,
Wherein the multi-meter reading enforcement module includes a switching module for controlling energization of each load for each load. The method according to claim 1,
The user monitoring server includes a communication module for communicating the multi-probe control module and the upper server within the user monitoring server;
An energy information collection server for collecting energy usage information from the multiple meter reading enforcement module;
And an energy information management server for storing intermittent control information for each load for the energy use policy from the upper server and for interrupting the load of each user based on the priority of the usage policy. . The method according to claim 1,
Wherein the multi-probe control module includes: a communication module for communicating with the user monitoring server;
(Voltage, current, phase, active power, reactive power, apparent power, frequency, power factor, distortion rate, demand, maximum value) by acquiring power quality information for each load and providing the power quality information to each user's monitoring server A PQ module;
A meter reading sensing unit for measuring voltage, current, power, power factor, frequency, and cumulative power amount for each load;
A threshold value setting unit for setting a threshold value for interrupting power input of each load by a load control schedule;
A load control schedule setting unit configured to set a schedule to be switched according to priority according to a load if the detection value in the meter reading detection unit is equal to or greater than a threshold value;
The control unit receives the meter reading information for each load and the meter reading information of the entire load from the meter reading sensing unit mounted on the distribution board port and controls transmission to the user monitoring server through the communication module, And the control unit controls the power supply of each load to be interrupted. The method according to claim 1,
The load is divided into a fixed load using normal power and a fluctuating additional load using power suddenly,
Wherein the multi-probe control module or the user monitoring server is configured to remotely control the fixed load in accordance with a sched- uling schedule upon power meter reading exceeding a critical point. 5. The method of claim 4,
Wherein the load control schedule setting unit can be configured to set the power-on priority of the load by reflecting the saving pattern information.

Images