KR101749457B1 - Factory energy management system using image sensor - Google Patents

Abstract

The present invention relates to a factory energy management system, and a factory energy management system according to an aspect of the present invention is a factory energy management system for managing energy consumption used in a factory. The system includes an image of an installed analog instrument A measurement system including a sensor unit to be acquired; And a management server for acquiring measurement information based on the image and providing a user interface (UI) for managing the energy consumption according to a user's selection based on the obtained measurement information through a server display unit have.

Description

FIELD OF THE INVENTION [0001] The present invention relates to a factory energy management system using an image sensor,

The present invention relates to a plant energy management system, and more particularly, to a plant energy management system capable of managing energy use of a plant.

Recently, due to the ever-increasing demand for electric power, the electric power supply can not keep up with the electric power demand.

Effective energy management is a key solution to this problem.

Conventional energy management has been carried out in such a manner as to check the amount of electric power used in the entire factory to charge the electric power consumption or to request the electric power saving.

However, such conventional energy management has a limit in that it can not provide detailed energy efficiency for each facility of the plant. To provide such detailed energy information, it is necessary to replace the existing analog type measuring instrument with a digital type measuring instrument There was a cost problem.

An object of the present invention is to provide a factory energy management system that provides a UI required for factory energy management.

Another object of the present invention is to provide a factory energy management system capable of selectively acquiring only measurement information desired by a user.

According to an aspect of the present invention, there is provided a factory energy management system for managing energy consumption used in a factory, comprising: a measurement system having a sensor unit for acquiring an image of an installed analog instrument located at a factory; And a management server for acquiring measurement information based on the image and providing a UI (user interface) for managing the energy consumption amount according to a user's selection based on the obtained measurement information through a server display unit An energy management system can be provided.

It is to be understood that the solution of the problem of the present invention is not limited to the above-mentioned solutions, and the solutions which are not mentioned can be clearly understood by those skilled in the art to which the present invention belongs It will be possible.

Industrial Applicability According to the present invention, a factory energy management system that provides a UI required for factory energy management can be provided.

According to the present invention, a factory energy management system capable of selectively acquiring only measurement information desired by a user can be provided.

1 is an environment diagram showing a factory energy management system according to an embodiment of the present invention.
2 is an exemplary diagram illustrating a measurement system according to an embodiment of the present invention.
3 is a block diagram illustrating a management server according to an embodiment of the present invention.
4 is a flowchart illustrating an operation method of a management server according to an embodiment of the present invention.
5 is an exemplary diagram illustrating basic management information output according to an embodiment of the present invention.
6 is a flowchart illustrating a method of adding a new sensor module according to an embodiment of the present invention.
7 is an exemplary view showing a sensor unit according to a modification of the present invention.

The above objects, features and advantages of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. It is to be understood, however, that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and similarities.

In the drawings, the thicknesses of the layers and regions are exaggerated for clarity and the element or layer is referred to as being "on" or "on" Included in the scope of the present invention is not only directly above another element or layer but also includes intervening layers or other elements in between. Like reference numerals designate like elements throughout the specification. The same reference numerals are used to designate the same components in the same reference numerals in the drawings of the embodiments.

The detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, numerals (e.g., first, second, etc.) used in the description of the present invention are merely an identifier for distinguishing one component from another.

In addition, the suffix "module" and " part "for constituent elements used in the following description are given or mixed in consideration of ease of specification, and do not have their own meaning or role.

According to an aspect of the present invention, there is provided a factory energy management system for managing energy consumption used in a factory, comprising: a measurement system having a sensor unit for acquiring an image of an installed analog instrument located at a factory; And a management server for acquiring measurement information based on the image and providing a UI (user interface) for managing the energy consumption amount according to a user's selection based on the obtained measurement information through a server display unit An energy management system can be provided.

The management server may obtain the measurement information based on the positions of the needle needles extracted from the image and the minimum and maximum values of the analog instrument previously stored.

The UI includes a basic management information UI for providing basic information on factory energy management, a system standard UI for acquiring information as a basis for calculating the energy efficiency of the plant, and the measurement information on energy consumption consumed by each facility An energy information UI to be provided, a measurement and efficiency information UI for providing efficiency information on the energy consumption of the product produced by the facility, an operation schedule of the facility, and an equipment control providing an interface capable of controlling power on / UI, energy efficiency information for a first time interval, and energy efficiency information for a second time interval from the first time interval, and provides maintenance information for the facility maintenance history And a maintenance UI that provides a maintenance UI The system according to claim 3, wherein the basic management information UI includes at least one of a weather information, a current power consumption amount, a current peak power consumption amount, a current day power use amount, a charge calculation amount for today's day power use amount, a monthly power use amount, A graph indicating a power consumption trend for a predetermined period, an energy consumption status of a main facility, a production efficiency of a facility, and a usage amount of oil energy.

Also, the weather information includes a weather forecast for a predetermined period, and the basic management information UI can output a predicted energy consumption amount for a predetermined period based on the weather forecast.

The predicted energy consumption amount is calculated by increasing / decreasing the energy consumption amount at the predetermined temperature, the increase / decrease value of the energy source according to the difference value between the predetermined temperature and the temperature included in the weather forecast, .

In addition, the system standard UI includes position information on the positions of the plant and the facility, a unit price of the energy, a unit of the energy, specification information of the facility, types of measurement information to be measured in the facility, A type of product to be produced, a parameter that can be controlled in the facility, and maintenance information of the facility.

In addition, the energy information UI may include unit-level information on the amount of energy consumed in producing one product in the facility.

When the new sensor module is added to the metrology system, the management server can register the new sensor module based on the pre-stored registration setting if there is a pre-stored registration setting corresponding to the new sensor module .

1 is an environment diagram showing a factory energy management system 10000 according to an embodiment of the present invention.

Referring to FIG. 1, a factory energy management system 10000 may include at least one metering system 1000 and a management server 2000.

The metrology system 1000 can acquire various signals for the plant. For example, the metrology system 1000 may obtain signals for energy usage such as temperature, humidity, power consumption, oil consumption, gas consumption, and the like.

The measurement system 1000 may include a measurement signal collection device 1100 and a sensor unit 1200.

The measurement signal collecting apparatus 1100 may be connected to at least the sensor unit 1200. Also, the measurement signal collection device 1100 can be connected to the management server 2000.

The measurement signal collecting apparatus 1100 can acquire the measurement signal from at least the sensor unit 1200. The measurement signal collecting apparatus 1100 can also transmit the acquired measurement signals to the management server 2000. [

The sensor unit 1200 can acquire various signals for the factory. For example, the sensor unit 1200 may be a temperature sensor, a humidity sensor, a power meter, an oil meter, or the like.

The sensor unit 1200 can transmit the acquired measurement signal to the measurement signal acquisition apparatus 1100. [

The management server 2000 may be connected to the measurement signal collection device 1100.

The management server 2000 can acquire the measurement signal from the measurement signal collection device 1100. [

The management server 2000 can store the acquired measurement signals. Also, the management server 2000 can manage the history of acquiring the measurement signal. For example, the management server 2000 can separate the measurement signals according to their types and store them. More specifically, for example, the management server 2000 may separately store temperature information obtained by the temperature sensor, humidity information acquired by the humidity sensor, humidity information acquired by the power meter, and oil information acquired by the oil meter. For example, the management server 200 may store the acquired measurement signals according to time.

2 is an exemplary diagram illustrating a measurement system 1000 according to an embodiment of the present invention.

Referring to FIG. 2, the measurement system 1000 may include a measurement signal collection device 1100 and a sensor unit 1200. The sensor unit 1200 may include a temperature sensor module 1210, a humidity sensor module 1220, a power sensor module 1230, and an oil sensor module 1240.

The measurement signal collecting apparatus 1100 can acquire a measurement signal from the sensor unit 1200 included in the measurement system 1000 and can transmit the measurement signal to the management server 2000.

The measurement signal collecting apparatus 1100 may be connected to the management server 2000 and the sensor unit 1200. The measurement signal collecting apparatus 1100 may include a communication module for connecting to the management server 2000 and the sensor unit 1200. For example, the measurement signal collecting apparatus 1100 may include a first communication module for connecting to the management server 2000 and a second communication module for connecting to the sensor unit 1200. Here, the first communication module may be a module for long-distance communication such as LAN, WIFI, LTE and the like. The second communication module may be a communication module supporting the Modbus communication method.

The measurement signal collecting apparatus 1100 includes a measurement signal collecting apparatus control unit for collecting the operation of the measurement signal collecting apparatus 1100 and a measurement signal collecting apparatus storing unit for storing data necessary for operation of the measurement signal collecting apparatus 1100 can do.

The measurement signal collecting apparatus 1100 may be implemented by, for example, a server apparatus and a router.

The sensor unit 1200 can acquire the measurement signal. The sensor unit 1200 may include a temperature sensor module 1210, a humidity sensor module 1220, a power sensor module 1230, and an oil sensor module 1240.

The temperature sensor module 1210 can obtain a temperature signal that is an electrical signal corresponding to the temperature. For example, the temperature sensor module 1210 may be installed at a predetermined position and transmit the obtained temperature signal to the measurement signal collection device 1100. Also, a plurality of temperature sensor modules 1210 may be provided to acquire temperature signals at different positions and transmit them to the measurement signal collection device 1100.

The humidity sensor module 1220 can acquire a humidity signal that is an electrical signal corresponding to the humidity, for example, the humidity sensor module 1220 is installed at a predetermined position, and transmits the humidity signal thus obtained to the measurement signal collection device 1100 A plurality of humidity sensor modules 1220 may be provided to acquire humidity signals at different positions and transmit the humidity signals to the measurement signal collector 1100. [

Here, the positions where the temperature sensor module 1210 and the humidity sensor module 1220 are installed may be the same as each other, and at least some of them may be installed at different positions.

The power sensor module 1230 may obtain a power signal that is an electrical signal corresponding to power consumption. For example, the power sensor module 1230 may obtain a power signal for the power used in the installation. Also, the power sensor module 1230 can transmit the acquired power signal to the measurement signal collection device 1100. [

The oil sensor module 1240 can acquire the oil signal which is an electric signal corresponding to the oil consumption amount. Here, the oil may be at least one of oil, gasoline, kerosene, and gas.

For example, the oil sensor module 1240 can acquire oil signals for the oil consumption of a facility that uses oil as an energy source. In another example, the oil sensor module 1240 may obtain the oil signal for the amount of oil discharged from the reservoir storing the oil.

The metrology system 1000 described above is for convenience of explanation and may optionally be provided with a metrology system 1000 that includes fewer or more sensors.

3 is a block diagram illustrating a management server 2000 according to an embodiment of the present invention.

3, the management server 2000 may include a server communication unit 2100, a server display unit 2200, a server storage unit 2300, and a server control unit 2400.

The server communication unit 2100 may be connected to the measurement system 1000. For example, the server communication unit 2100 may be connected to the measurement signal collecting apparatus 1100. The server communication unit 2100 can acquire the measurement signal from the measurement signal collecting apparatus 1100. [

The server display unit 2200 can output visual information. For example, the server display unit 2200 may output a graphical user interface (GUI) for providing information. Also, the server display unit 2200 can output at least one of measurement information and analysis information based on the measurement signal.

The server storage unit 2300 may store data necessary for the operation of the management server 2000. [ For example, the server storage unit 2300 may store programs necessary for the operation of the management server 2000. [ In another example, the server storage unit 2300 may store settings for the operation of the management server 2000 in advance. In another example, the server storage unit 2300 may store the acquired measurement signal.

The server control unit 2400 can supervise the operation of the management server 2000. For example, the server control unit 2400 can control the operation of the configurations included in the management server 2000. [ More specifically, for example, the server control unit 2400 may control the server display unit 2200 to output visual information. For example, the server control section 2400 can acquire the measurement information based on the measurement signal. In another example, the server control unit 2400 can acquire at least one of the analysis information based on the measurement signal.

4 is a flowchart showing an operation method of the management server 2000 according to an embodiment of the present invention.

Referring to FIG. 4, an operation method of the management server 2000 includes a step S110 of obtaining a measurement signal, a step S120 of outputting basic management information, a step S130 of selecting a management menu, A step S160 of outputting a UI, a step S150 of outputting an energy information UI, a step S160 of outputting a measurement and efficiency information UI, a step S170 of outputting a facility control UI, Step S180, and outputting the maintenance UI (S190).

The server control unit 2400 can acquire the measurement signal (S110).

The server control unit 2400 can acquire a measurement signal through the server communication unit 2100.

The server control section 2400 can acquire the measurement information based on the acquired measurement signal. For example, the server control unit 2400 can acquire temperature information of 37 占 폚 when the temperature signal of the obtained measurement signal is 3V. For example, when the humidity signal is 2.5V, the server control unit 2400 can acquire humidity information of 50% humidity. For example, when the server controller 2400 acquires an average power of 2V for one hour, the server controller 2400 can obtain power information of 2KWH, which is a power consumption per hour. For example, the server control unit 2400 can acquire the oil information of 3.5 L / H, which is the amount of oil consumption per hour, when an average power signal of 3.5 V is acquired for one hour.

The server control unit 2400 can control to output the basic management information (S120).

The server control unit 2400 can control the server display unit 2200 to output the basic management information.

5 is an exemplary diagram illustrating basic management information output according to an embodiment of the present invention.

For example, as shown in FIG. 5, the management server 2000 may calculate the amount of electricity used for the current day, the amount of electricity used for the current month, the amount of electricity used for the current month, the amount of electricity used for the current month, A graph showing a power consumption trend for a predetermined period, energy consumption status of a main facility, production efficiency of a facility, amount of oil energy consumption, and the like can be output. Here, the weather information may be information obtained from a separate weather information providing apparatus connected to the management server 2000. In addition, the weather information may include weather information of the current time point. In addition, the weather information may further include a weather forecast for a predetermined period of time.

The server control unit 2400 can calculate the current power consumption amount, the current day power consumption amount, and the current monthly power consumption amount based on the power information. Also, the server control section 2400 can calculate the target power with respect to the peak target value of the current power consumption amount based on the previously stored target information. Also, the server control unit 2400 can calculate the charge calculation amount for today's power consumption amount and the charge calculation amount for power consumption for the current month based on the previously stored unit price information and the power information.

The server control unit 2400 can store the respective pieces of information included in the basic management information in the server storage unit 2300. Also, the server control unit 2400 can manage the history of each information to be stored. For example, the server control unit 2400 may store the information and the time information of the corresponding information in the server storage unit 2300. More specifically, for example, the server control unit 2400 can match and store the time at which each information is acquired in order to distinguish information acquired at 1:00 and information acquired at 2:00 by the time table.

The server control section 2400 can calculate the predicted consumption amount according to the weather forecast.

The server control unit 2400 can calculate the predicted consumption amount for at least one of the day, the week, and the month.

For example, the server control unit 2400 can predict the oil consumption required for heating based on the temperature change included in the weather forecast. More specifically, the temperature difference can be calculated by comparing at least one of the preset appropriate temperature and the predicted time, morning / afternoon, day, and daytime temperature included in the weather forecast, and the amount of oil consumption according to the calculated temperature difference And / or increase / decrease of the amount of power can be calculated. For example, in the case where the predetermined temperature is 25 占 폚 and the calculated temperature difference is -5 占 폚, the server control section 2400 judges that 5 L of oil is needed more than when the proper temperature is maintained at 25 占 폚 . To this end, the server storage unit 2300 stores information on the amount of increase or decrease per 1 ° C (for example, an increasing amount of oil required to raise 1 ° C, an amount of oil saved as the temperature is increased by 1 ° C from a predetermined temperature, Can be stored in advance.

The server control unit 2400 may control the flow of at least one of daily, weekly, monthly, and yearly based on the increase / decrease of the oil consumption amount and / or the electric energy amount according to at least one temperature difference among the calculated time, morning / afternoon, And / or predicted consumption of power can be calculated. The server control unit 2400 can control the server display unit 2200 to output the calculated predicted consumption amount. Also, the server control unit 2400 can calculate the predicted charge based on the predicted consumption amount and the unit price information, and can control to output the calculated predicted charge.

The server control unit 2400 can periodically update the information output to the basic management information. For example, the server control unit 2400 can update the information output to the basic management information at intervals of one minute.

The server control unit 2400 can determine the selection of the management menu (S130).

The server control unit 2400 can receive the user's selection of the management menu through a separate input unit and can control to output the GUI corresponding to the input selection.

The server control unit 2400 may control to output the system standard UI (S140).

The server control unit 2400 can control the server display unit 2200 to output energy information when a menu for energy information is selected.

The system-based UI can be a UI for setting information necessary for factory energy management.

For example, the system-based UI may include a location management UI, an energy reference information UI, a facility reference information UI, a facility measurement information UI, a production information UI, a facility control information UI, a facility maintenance information UI, .

The server control unit 2400 can acquire the location information based on the user's selection acquired through the separate input unit. For example, the server control unit 2400 can acquire and set information on the position of the measurement system 1000 through the location management UI. Also, the server control unit 2400 can acquire and set the position where the sensor module included in the sensor unit 1200 is installed. For example, the server control unit 2400 may match and store the facility in which the sensor module is installed and the sensor module. More specifically, for example, the server control unit 2400 can match and store the first power sensor module 1230a in the pipe production facility. For example, the server control unit 2400 may store and store the second power sensor module 1230b in the bearing production facility.

The server control unit 2400 can acquire the user's input of the energy reference information through the separate input unit and the energy reference information UI. For example, the server control unit 2400 can obtain the user's input on the unit, unit price, petroleum conversion factor, carbon emission factor, greenhouse gas coefficient, and usage of energy sources such as electricity, LNG, LPG and diesel , The input of the acquired user can be stored.

The server control unit 2400 can acquire facility reference information through a separate input unit and facility reference information UI. For example, the server control unit 2400 may input the user's input about the facility name, module name, equipment type, manufacturer, model name, manufacturing (installation) date, installation building, installation room / line, And can store the acquired user's input.

The server control unit 2400 can receive settings for whether to use the facility through the facility reference information UI.

The server control unit 2400 can acquire the facility measurement information through the separate input unit and the facility measurement information UI. For example, the server control unit 2400 may obtain a selection of measurement information to be acquired at the facility. More specifically, for example, the server control unit 2400 determines whether or not to acquire the measurement information on the production amount, the measurement information on the operation pressure, the measurement information on the operation time, the measurement information on the voltage, and the measurement information on the current A selection can be obtained. The server control unit 2400 can store the setting according to the acquired user's selection.

In addition, the server control unit 2400 can obtain a selection of whether to acquire the measurement signal from each of the sensor modules included in the sensor unit 1200 through the facility measurement information UI. For example, the server control unit 2400 may obtain a selection of whether to acquire the measurement signal from the first power sensor module 1230a matched to the pipe production facility. The server control unit 2400 may block or allow transmission of the measurement signal of the first power sensor module 1230a according to the selection.

The server control unit 2400 can acquire the production information based on the separate input unit and the production information UI. For example, the server control unit 2400 may obtain a user's input on a product and a production unit produced in the facility. The server control unit 2400 can store the setting according to the input of the user.

The server control unit 2400 can acquire facility control information based on a separate input unit and facility control information UI. For example, the server control unit 2400 can obtain an input on control settings related to operation of the facility, such as ON / OFF of the facility, schedule control, and manual control. The server control unit 2400 may store settings according to the acquired user input.

The server control unit 2400 can obtain the maintenance information on the basis of the separate input unit and the equipment maintenance information UI. For example, the server control unit 2400 can acquire information on maintenance or maintenance of the facility. Also, the server control unit 2400 can control to output information on the maintenance state at the current time. Also, the server control unit 2400 can acquire information on the history of performing the maintenance, and can output information on the obtained maintenance history.

The server control unit 2400 can obtain performance reference information through a separate input unit and performance reference information UI. For example, the server control unit 2400 can obtain an input on which item the efficiency of each item is to be managed. The server control unit 2400 can store settings for the acquired efficiency management information.

The server control unit 2400 can control to output the energy information UI (S150).

The server control unit 2400 can control the server display unit 2200 to output the production information when the menu for the production information is selected.

For example, the Energy Information UI can include energy usage analysis, usage by energy source, usage by facility and unit size analysis. Energy usage analysis can be information about the history of using energy. The usage amount per energy source may be information on the history using the energy source. The usage amount per facility may be information on the history of energy amount used by each facility. The unitary analysis can also be information on the amount of energy consumed in producing one product.

The server control unit 2400 can control to output the measurement and efficiency information UI (S160).

The server control unit 2400 may control the server display unit 2200 to output measurement and efficiency information when the menu for measurement and efficiency information is selected.

For example, the server control unit 2400 can acquire the measurement information about the time when each facility is operated, and can output the measurement information about the obtained operation time.

The server control unit 2400 can control to output the facility control UI (S170).

The server control unit 2400 can output information on the control state per facility at the current time. The server control unit 2400 can acquire the operation schedule and ON / OFF setting of each facility based on a separate input unit and the facility control UI. The server control unit 2400 can store the acquired setting and output it through the facility control UI.

The server control unit 2400 can control to output the performance monitoring UI (S180).

For example, the server control unit 2400 may output information that compares the previous energy efficiency and the current energy efficiency. For example, the server control unit 2400 may output energy efficiency information of the first time period and energy efficiency information of the second time period that is later than the first time period. For example, the server control unit 2400 may output energy usage information of the first time period and energy usage information of the second time period that is later than the first time period.

The server control unit 2400 can control to output the maintenance UI (S190).

The server control unit 2400 can acquire information on the history of replacement of parts for each facility and can control to output the acquired information.

The server control unit 2400 can output information comparing the energy efficiency before the component replacement and the energy efficiency after the component replacement. In addition, the server control unit 2400 can quantify the effect of each component on the energy efficiency improvement based on the energy efficiency before the component replacement and the energy efficiency after component replacement. The server control unit 2400 can output the numerical value of the improvement effect calculated for each part. Also, the server control unit 2400 can acquire information on the previous energy efficiency and the predicted energy efficiency after replacement, and can output the obtained information.

6 is a flowchart illustrating a method of adding a new sensor module according to an embodiment of the present invention.

Referring to FIG. 6, the method of adding a new sensor module includes a step S200 of detecting installation of an additional module, a step S210 of notifying the addition, a step S220 of determining whether to add or not, Step S240 of determining whether the factory energy management system 10000 supports installation of a new sensor module, registering an additional module S240, and acquiring manual registration information S250 can do.

The server control unit 2400 can detect installation of the additional module (S200).

The server control unit 2400 can detect that the additional module is installed based on whether or not the newly added sensor module identification information exists, detection of an unidentified electric signal, and the like.

The server control unit 2400 can control to add or not to be added (S210).

The server control unit 2400 may control the server display unit 2200 to notify that the additional module is detected.

The server control unit 2400 can determine whether to add or not by obtaining a selection of whether or not to register (S220).

The server control unit 2400 can obtain the user's selection of whether to register the additional module.

The server control unit 2400 can terminate the addition of a new sensor module when the user's selection is a registration rejection.

The server control unit 2400 can determine whether the factory energy management system 10000 supports the installation of a new sensor module (S240)

The server control unit 2400 can acquire information capable of identifying at least one of a manufacturer, a model name, and a communication method from the new sensor module. The server control unit 2400 can determine whether or not the registration setting corresponding to the acquired information is stored in advance. For example, the server control unit 2400 can obtain the model name of AAA from the new sensor module, and can determine whether the setting corresponding to the model name of AAA is stored in advance.

The server control unit 2400 can register the additional module (S240).

When the registration setting corresponding to the acquired information is stored in advance, the server control unit 2400 can register the additional module based on the previously stored registration setting. For example, the server control unit 2400 may store the settings of the communication protocol, the reference value, the maximum / minimum value, and the measurement target of the new module as preset registration settings. In addition, the server control section 2400 may provide identification information capable of identifying a new module.

The server control unit 2400 can obtain the manual registration information (S250).

The server control unit 2400 can register the new module based on the registration setting acquired from the user if the registration setting corresponding to the acquired information is not stored in advance.

7 is an exemplary view showing a sensor unit 1200 according to a modification of the present invention.

FIG. 7A is a diagram illustrating an example of a method of acquiring a measurement signal of the sensor unit 1200 according to a modification of the present invention.

As shown in FIG. 7, the sensor unit 1200 may be provided as an image sensor.

In the past, measurement sensors have been provided primarily as analog instrument panels. Currently, it is replaced by digital equipment, but it may happen that the conventional analog instrument panel is continuously used. In this case, it is possible to reduce the cost by constructing the factory energy management system (10000) by using the installed analog sensor.

In this case, the sensor module may be provided as an image sensor.

As shown in FIG. 7 (a), the sensor unit 1200 implemented by an image sensor can acquire an image of a previously installed analog instrument panel. The sensor unit 1200 can transmit the acquired image to the management server 2000. The management server 2000 can determine the matching measurement information to be acquired based on the identification information (for example, the IP address, etc.) given to the sensor unit 1200 that transmitted the image. For example, when the management server 2000 acquires an image signal from the first sensor unit 1200a, the management server 2000 determines that the power information matched with the first sensor unit 1200a is measurement information to be acquired , Measurement information can be obtained from the acquired image.

The management server 2000 may store settings for acquiring measurement information from an image in advance.

Fig. 7 (b) is an exemplary view showing a conventional analog instrument panel.

The conventional analog instrument panel moved to the position corresponding to the measured value of the needle tip and displayed the measured value. However, such a conventional analog instrument panel has different units according to its purpose, and has a problem that the intervals of the intervals are different from each other depending on the measurement range and the like.

Accordingly, the management server 2000 can previously store information on the minimum scale, the maximum scale, and the unit of the analog instrument panel to which each sensor unit 1200 acquires an image in advance.

In addition, the management server 2000 can extract the position of the needle needle from the image, and obtain a value corresponding to the position of the needle needle between the minimum scale and the maximum scale as the measurement information.

In the above description, the configuration in which the measurement information is obtained by using the sensor unit 1200 implemented as an image sensor from the analog instrument implemented with the needle needles is described. However, the present invention is not limited to this, and the measurement value may be output using the 7-segment LED Sensor, and so on.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be apparent to those skilled in the art that changes or modifications may fall within the scope of the appended claims.

10000 factory energy management system 1000 measurement system
1100 Measurement signal collecting device 1200 Sensor part
1210 Temperature Sensor Module 1220 Humidity Sensor Module
1230 Power Sensor Module 1240 Oil Sensor Module
2000 Management Server

Claims (9)

A factory energy management system for managing energy consumption in factories,
A measurement system having a sensor unit for acquiring an image of a pre-installed analog instrument located at a factory; And
And a management server for acquiring measurement information based on the image and providing a UI (user interface) for managing the energy consumption amount according to a user's selection based on the obtained measurement information through a server display unit,
The UI includes a basic management information UI for providing basic information on factory energy management, a system standard UI for acquiring information as a basis for calculating the energy efficiency of the plant, and the measurement information on energy consumption consumed by each facility An energy information UI, a measurement and efficiency information UI for providing efficiency information on an energy usage amount of a product produced in the facility, an equipment control UI for providing an operation schedule of the facility, and an interface capable of controlling power on / A performance monitoring UI for comparing energy efficiency information for a first time period and energy efficiency information for a second period from a first time period to a later time point and providing maintenance information on the maintenance history for the facility And a maintenance UI for performing maintenance,
The basic management information UI includes at least one of a weather information, a current power consumption amount, a peak power consumption amount, a current power consumption amount, a current power consumption amount, a current power consumption amount, a current power consumption amount, A graph showing power consumption trends for a predetermined period, energy consumption status of major facilities, production efficiency of facilities, and energy consumption of oil,
Wherein the weather information includes a weather forecast for a predetermined period of time,
The basic management information UI outputs a predicted energy consumption amount for a predetermined period based on the weather forecast,
Wherein the predicted energy consumption amount is calculated by increasing or decreasing an energy consumption value of the energy source based on a difference between an energy consumption at a predetermined temperature and a temperature difference between the predetermined temperature and the temperature forecasted in the energy consumption at the predetermined temperature ,
Wherein the sensor unit includes at least one sensor module,
Wherein the management server registers the new sensor module based on the pre-stored registration setting when a new sensor module is added to the metering system and a pre-stored registration setting corresponding to the new sensor module exists,
The management server quantifies and outputs the influence of the component on the energy efficiency improvement based on the energy efficiency before the component replacement and the energy efficiency after component replacement
Factory energy management system.
The method according to claim 1,
The management server obtains the measurement information based on the positions of the needle needles extracted from the image and the lowest and highest values of the analog instrument previously stored
Factory energy management system.
delete delete delete delete The method according to claim 1,
The system reference UI may include at least one of location information on the location of the factory and the facility, unit price of the energy, unit of the energy, specification information of the facility, type of measurement information to be measured by the facility, A type of product, a parameter controllable in the facility, and maintenance information of the facility
Factory energy management system.
The method according to claim 1,
The energy information UI includes unit-level information on the amount of energy consumed in producing one product in the facility
Factory energy management system.
delete

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