AUTOMATED WEATHER RELATED ENERGY INFORMATION SYSTEM
A weather related energy information system is connected to a network, weather stations portals and energy portals. A server communicates with smart meters mounted to structures defined by an address. The server harvests energy interval data and temperature interval data either conditions the interval data, generates groups of interactive graphs, generates alert reports using stored energy metrics for each structure defined by an address while using a dynamic energy model that performs the steps of: calculating energy metrics for each structure by day or groups of days, determining percent changes in energy metrics for each structure defined by an address by day and groups of days, and comparing percent changes to stored threshold values automatically generating a daily report and optionally generate an alert report to client device connected to the network.
This application claims priority to and benefit of U.S. Patent Application No. 62/589,398 filed on Nov. 21, 2017 entitled: Weather Related Management System. These references are incorporated in their entirety.
FIELDThe present embodiment generally relates to a weather related energy information system.
BACKGROUNDA need exists for a non-invasive big data weather related interval energy remote collection system to automatically and continuously identify and monitor energy conservation opportunities, monitor and calculate energy efficiency metrics and energy demand in a plurality of multilevel buildings.
The present embodiments meet these needs.
The patent or application file contains at least one drawing executed in color. Copies of this patent or patent application publication with color drawing(s) will be provided by the Office upon request and payment of the necessary fee.
As the color drawings are being filed electronically via EFS-Web, only one set of the drawings is submitted.
The detailed description will be better understood in conjunction with the accompanying drawings as follows:
The present embodiments are detailed below with reference to the listed Figures.
DETAILED DESCRIPTION OF THE EMBODIMENTSBefore explaining the present system in detail, it is to be understood that the system is not limited to the particular embodiments and that it can be practiced or carried out in various ways.
Specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a basis of the claims and as a representative basis for teaching persons having ordinary skill in the art to variously employ the present invention.
The invention relates an automated weather related energy information system.
The automated weather related energy information system includes a server having a processor with a non-transitory computer readable medium connected to a network and connected to weather stations portals and energy portals maintained by utilities companies.
At least one structures defined by an address is in communication with at least one smart meter mounted to or proximate the at least one structures defined by an address.
At least one client device is connected to the network for viewing at least two interactive graphs using conditioned harvested data produced by the server.
The server crawls through the energy portals and temperature portals and harvests energy interval data and temperature interval data identified by the structure defined by an address forming harvested energy interval and temperature interval data.
The server conditions the harvested energy interval and temperature interval data forming conditioned harvested data, wherein conditioning includes cleaning, indexing, and slicing.
The server generates groups of interactive graphs using conditioned harvested data.
The server displays the groups of interactive graphs on an user interface.
The server stores threshold values for alert reports.
The server stores energy metrics for the at least one structure defined by an address.
The server uses a dynamic energy model that performs the steps of calculating energy metrics for the at least one structure defined by an address for a last day of conditioned harvested data, a last six days of conditioned harvested data; and a last thirty five days of conditioned harvested data.
The server uses a dynamic energy model that performs the steps of applying statistical modeling filtering.
The server uses a dynamic energy model that performs the steps of determining percent changes in energy metrics for each structure defined by an address for: a last day of conditioned harvested data, a last six days of conditioned harvested data; and a last thirty five days of conditioned harvested data.
The server uses a dynamic energy model that performs the steps of comparing the percent change to stored threshold values and if the percent change does not exceed the stored threshold values automatically generate a daily report and optionally generate an alert report to the client device for each structure defined by an address.
The server sets a start time which is stored in the non-transitory computer readable medium to the harvest energy interval and temperature interval data from the smart meters connected to the network.
The server identifies a quantity of structures defined by an address to be monitored and generates a counter.
The server increases the counter by one unit (N+1) to go to a next structure defined by an address; and determines if the value of N of the counter has become bigger than a total preset unit (t) of structures defined by an address, the server ends the analysis or if the value of N of the counter is less than a total preset unit (t) of structures defined by an address; the server automatically harvest interval energy data and interval temperature data for that next structure defined by an address; and the server continues comparing the quantity of structures defined by an address to the counter and continues harvesting the interval energy data and the interval temperature data until the value of N reaches the value of (t+1).
The crawling through the energy portals and the temperature portals and harvesting of the energy interval and the temperature interval data by structure defined by an address includes weather data from airports or a weather station within from 60 miles to 100 miles of the structure defined an address.
The alert report defines each threshold value exceeded and a percent change in energy usage for each structure defined by an address.
The maximum energy usage day and minimum energy usage day are included in the daily report.
The degree-hours are stored in the dynamic energy model.
The server resamples the interval energy data and the interval temperature data in 24 hour intervals to create the daily report.
The server gathers user information on users and physical attributes of structures defined by an address.
The server generates a dictionary for energy metrics.
The server presents conditioned harvested data by multiple individual dates in the daily report.
The weather related energy information system includes harvesting the interval energy and temperature data every 15 minutes.
The weather related energy information system includes using a standard base temperature of 65 Fahrenheit degrees and temperature interval data every 15 minutes to determine degree values.
The weather related energy information system includes generating sets of historical monthly energy heat maps that enable visualization of a last 30 days for energy usage by hour per day with a color dependent value related to a color palette.
The weather related energy information system includes providing monthly historical heat maps to identify patterns anomalies and identify opportunities of energy conservation.
The weather related energy information system includes mapping resampled energy interval data to comparable days of a week and overlapping annual data sets to compare as current year versus previous years, by month, by day, and by hour.
The weather related energy information system includes calculating changes in energy metrics and mapping changes in energy metrics to startup and shutdown times of equipment using energy in a structure defined by an address.
The dynamic energy model calculates energy metrics for a structure defined by an address that include: total energy use for one day, total energy use for six days, and total energy usage for thirty five days, maximum energy value for one day, maximum energy value six days and maximum energy value for thirty five days, minimum energy values for one day, minimum energy values for six days, and minimum energy values for thirty five days; and mean energy use for six days having same names during thirty five consecutive days.
The server uses a dynamic energy model to calculate the last day percent change, this value is calculated comparing the last day energy metrics to the average of the last five corresponding days in the last five same weekdays and comparing it to stored threshold values, and issuing a daily report. If the percent change does exceed the stored threshold values, the server automatically generates an alert report to the client device for each structure defined by an address.
The server automatically and on 15 minutes intervals verifies if there is new data available in the energy and temperature portals and harvests energy interval data and temperature interval data either identified by the structure defined by an address forming harvested energy interval and temperature interval data.
The embodiments reduce the time used by clients to gather and process energy information necessary to make energy management decisions. The network, server, processor and non-transitory computer readable medium to automatically and continuously check the energy and temperature portals for new data. As soon as new data is available, the system updates the databases and creates all the analysis for the client to review and take actions with. The system is able to update the databases by exchanging information between the systems and the energy and weather portals. Currently, due to the lack of the widespread distribution of the system, clients, such as school's Energy Managers, do not have the resources to this work; thus, only managing electricity consumptions at facilities in a reactive manner, via monthly electric bills, which lack the detailed to analysis consumption and the sensitivity in time, which is usually 30 day delayed.
The embodiments prevent waste by automatically and continuously doing the work for the client, saving countless hours of work in addition to wasted energy.
The embodiments create alert reports on time-sensitive manner so that the client is able to take corrective actions.
The embodiments automatically perform and improve the energy management functions and analysis by finding waste in energy consumption.
The embodiments foster good quality of life, prevent premature death, and costly illnesses by using its benchmarking capabilities to allow identification of inefficient energy use in multi buildings mainly for HVAC and other major equipment, which allows multi buildings to maintain a dryer and properly ventilated environment. The dryer and properly ventilated environment lowers the risk of illnesses and mold growth and reduces buildup of air pollutants. Hence improving occupant comfort, productivity, enhancing general health, which avoids costly illness and premature dead.
According to the EPA Americans, on average, spend approximately 90 percent of their time indoors, where the concentrations of some pollutants are often 2 to 5 times higher than typical outdoor concentrations. Moreover, noting that indoor Ambient (outdoor air pollution) is a major cause of death and disease globally, the health effects range from increased hospital admissions and emergency room visits, to increased risk of premature death. The World Health Organization estimates that 4.6 million people die each year from causes directly attributable to air pollution. Many of these mortalities are attributable to indoor air pollution. Worldwide more deaths per year are linked to air pollution than to automobile accidents.
The embodiments prevent environmental harm by creating and sending automated alert reports to clients when alert thresholds have been met, therefore, reducing the wasted energy consumption by fostering energy usage savings, using substantially less energy and reducing the amount of carbon dioxide produced to the environment. Issues may include but not limited to client's issues with HVAC systems scheduling process, or human error, a facility manager forgetting to change setting on HVAC units, and leaving the units on for one for months a time. According to the U.S. Department of Energy in the United States alone, buildings account for almost 40 percent of national CO2 emissions and out-consume both the industrial and transportation sectors.
The embodiments reduce owner costs of energy consumption by providing alert reports that are to see and alerts that immediately pushed to a cell phone or their client device.
The embodiments reduce owner cost of energy consumption by providing daily report with analysis that can be compared to base year kWh usage to determine optimal timing for equipment rehab or replacement.
The embodiments optimize the use of HVAC equipment, thus reducing the owner cost of energy consumption by providing daily reports with analysis which allows client to review optimal HVAC start and stop times, which extends the life of the equipment by using HVAC optimally.
The following terms are used herein:
The term “alert reports” refers to a daily report that tells a client's device that an issue or anomaly is occurring in the structure defined by an address, such as a heating ventilation and air conditioning has been left on after hours.
The term “automatically generate” refers to a process performed without any human assistance. Such as the harvesting of interval energy and weather data, the alert reports and analysis. For example the invention automatically crawls the Internet to harvest data a process that a client would normally could not perform due to time and resources constraints it is done generated automatically by the invention.
The term “automated” refers to applying the principles of automation to the process of gathering interval energy and temperature data, conditioning, processing and issue of energy related reports.
The term “Big Data” refers to extremely large data sets that many be analyzed computationally to reveal patterns, trends and associations. The invention crawls the Internet every 15 minutes to harvest, raw data, such as energy and weather interval data, and performs analysis which could not be performed by the client or even an excel sheet, due to the extreme size of the data sets.
The term “client device” refers to a laptop, computer, tablet, smartphone, or similar bidirectional device with a processor and memory.
The term “color scale” can refer to a specialized label object that displays a color map and the object's scale. In the color scale, the lowest kWh and temperatures are represented in blue, the low mid rage kWh and temperatures are represented in yellow, the high mid-range kWh and temperatures are represented as orange, and the high kWh and temperatures are represented in red for the structure defined by an address 199a
The term “conditioned harvested data” or “data conditioned” refers to cleaning, indexing and slicing of harvested data. For example, cleaning is the removal of duplicated data. Indexing is assigning operators to data to provide quick and easy access across a wide range of energy values and temperature values. Another example, slicing of harvested data includes filtering the data by time intervals, such as 24 hours, 36 hours, 120 hours or another user defined unit.
The term “crawl” refers computer instructions which systematically browse the
Internet. For example the invention automatically crawls the internet to the energy and temperature portals to harvest data.
The term “daily report” refers to a report containing analysis on energy usage and graphs of energy metrics.
The first illustration shows a bar-chart with last day energy usage versus the same day previous year and a bar-chart below shows the excess or defect of energy usage, second illustration shows a line-graph with the 15 minutes interval energy usage in kWh during the day showing the maximum energy usage and the minimum inferring on and off of heating ventilation and air conditioning units, third illustration shows a line-graph in 15 minutes interval a comparison behavior in energy usage for that day versus previous year same weekday showing excess in red or defect in green color, line-graph below shows for that day comparison temperature in one hour interval behavior with same weekday last year. Fourth illustration shows a comparative bar-chart of last seven days energy usage for current versus last year weekdays, below a chart-graph showing the excess in red or defect in green color. Fifth illustration shows a comparative seven days line-graph of daily energy usage behavior with previous year, excess usage in red color or defect usage in green color, graph below shows comparative seven days line-graph of daily behavior of temperature with previous year, excess temperature in red color or defect in green color; facilitating correlation between energy use and temperature. Next illustrations are a thirty five day analysis showing four sets of heat maps for the structure defined by the address. The first set of heat maps shows energy usage per day for the structure defined by the address. The second set of heat maps shows total degree hours per day for the structure defined by the address. The third set of heat maps show kilowatt per hour usage per degree day for the structure defined by the address. The fourth set of heat maps shows kilowatts per hour usage per degree day per square foot of the structure defined by the address.
The term “DH” or “Degree Hours” refers the units use to determine the heating or cooling requirements, referring to base temperature such as 65 degree Fahrenheit, by hour. For example at 11 am the temperate is 75 degree Fahrenheit therefore the degree hours for the 11 am is 10 DH.
The term “dictionary” refers to an unordered key-value-pair set of variables save to memory.
The term “dynamic energy model” refers to a mathematical procedure that use conditioned harvested energy and temperature interval data with conditioned energy and temperature interval data to produce the daily report and an alert report if an threshold is exceeded. The dynamic energy model compares last day energy usage against the mean of the similar five days of the five previous weekdays; previously the mean of the similar weekdays of the last 5 weeks has been analyzed and conditioned of any outlier so the mean value is representative to obtain a percent change. If percent change is equal or bigger than the alert threshold established, an alert is issue to client devices for corrective action. To show a whole image of the energy usage, the model calculates energy usage by different periods including but not limited to: (i) Last Day: energy usage, maximum energy usage during a day and the date and time of the pick (kilowatts), percent change of energy usage; (ii) Last Six Days: total energy usage, day of maximum energy usage and value and percent change of energy usage; (iii) Last Forty Days: total energy usage, day of maximum energy usage and value, day of maximum daily energy usage per facility area per degree-hour and its value (kWh/DH/SF)
The term “harvested energy interval and temperature interval data” refers to the raw data collected from the energy portals, such as Smart Meter Texas or CenterPoint Energy Demand & Energy Information System, and the weather portals and energy portals.
The term “HVAC” refers to heating, ventilation and air conditioning.
The term “energy conservation’ refers to reducing energy through the use. For example not forgetting to turn off heating ventilation and air conditioner systems when not used or not needed is energy conservation.
The term “energy metrics” refers to values of interval energy in kilowatts per hour (kWh) every 15 minutes, values of interval load in kilowatts every 15 minutes, temperature is arranged in intervals every 60 minutes; these values can be manipulated arithmetically; degree-hour is another metric obtained by subtracting from temperature values the base-temperature of 65 degrees Fahrenheit. The term “energy portals” refers to a website that provides interval energy data from smart meters or interval data recorders (IDR) by a unique electrical service identifier or electric service identifier (ESI), such as Smart Meter Texas and CenterPoint Energy Demand & Energy Information Systems (DEIS).
The term “heat map” refers to a graphical representation of two variables such as energy and temperature interval data where the individual values contained in a matrix are represented as colors related to a scale with the x-axis as the time, y-axis hours, and a color scale representing the kWh value, usually with blue as a lower value of kWh and red a higher value of kWh consumption.
The term “historical” refers to the previously harvested energy and weather condition interval data.
The term “interactive graph” graphs that allow a two-way flow of information between a system and client; responding to a client's input.
The term “interval data” refers to data in which the increments are known, consistent and measurable, such us 15 minute interval energy data, which is the energy data that is collected from the smart meters every 15 minutes.
The term “maximum and minimum dates of energy usage values” refers to specific days when a structure has a maximum energy use or minimum energy use in a defined period of time.
The term “non-transitory computer readable medium” refers to a hard disk drive, solid state drive, flash drive, tape drive, and the like. The term “non-transitory computer readable medium” excludes any transitory signals but includes any non-transitory data storage circuitry, e.g., buffers, cache, and queues, within transceivers of transitory signals.
The term “network” refers to a satellite network, a cellular network, a global communication network, a local area network, a wide area network, a fiber optic network or combinations thereof.
The term “overlapping annual data” refers to ordering the interval data on the weekday bases. That is to order the first weekday of current year to the first weekday of other years so that all weekdays throughout the year are the same. The overlapping of annual data allows to compare Monday to Monday, this is important due to the weekly settings of the heating ventilation and air condition system scheduling.
The term “percent change” represents the degree of change over a period of time.
The term “processor” refers the electronic circuitry within a computer that carries out the instructions of a computer program by performing the basic arithmetic, logic, controlling and input/output (I/O) operations specified by the instructions.
The term “quartile” refers to each of four equal groups into which a population can be divided according to the distribution of values of the energy data. Quartile filtering removes outliers such as holidays and blackouts, from the last 5 same weekday days.
The phrase “resample interval energy data and interval temperature data to one day periods” refers to a method of frequency conversion by frequency of time, such as an initial sampling of every 15 minutes, then resampling to every hour.
The term “script” refers to a program or set of instruction that tells a computer to do something
The term “server” refers to a type of computer or device on a network that manages network resources. The server provides requested HTML pages for the client, in addition to providing the program logic for the invention.
The term “smart meter” refers to a device that measures interval energy data and transmits the interval energy data to an energy portal by smart meter identification number and by structure defined by an address. Such as the Smart Meter manufactured by Itron, OpenWay model.
The term “structures defined by an address” refers to one or more structures such as a high rise, a house, a warehouse, a school, a parking lot, industrial facility, a bus stop with electronic signs, an airport, or a waste treatment facility.
The term “threshold values” refers to a value defined by a user to cause an alert report to be transmitted to a client device.
The term “utility companies” refers to power distribution companies, for example CenterPoint Energy.
The term “weather stations portals” refers to an airport website or local weather station that provides interval temperature data via the internet.
The Term “weekday” it is used to refer when comparing Monday to Monday, or Tuesday to Tuesday.
Turning now to the Figures,
The system uses a server 110 connected to a network 120.
The server and network can connect to weather stations portals 130a and 130b and energy portals 140a and 140b. The energy portals 140a and 140b are maintained by utility companies 112.
Weather station portals can be at airports 133 proximate the structures defined by an address, such as within 60 to 100 miles of the structure defined by the address. Weather station portals 130a and 130b can be a weather station 134, proximate the structures defined by an address.
The server and network can be connected to a plurality of smart meters 150a-150e.
Each smart meter is mounted to or proximate structures defined by an address 199a-199e. Structure defined by an address 199a is a warehouse, structure defined by an address 199b is an office building, structure defined by an address 199c is a hospital, structure defined by an address 199d is a convenience store, and structure defined by an address 199e is a residential house.
At least one client device 160 can be connected to the network 120 for viewing at least two interactive graphs generated by the server 110 using conditioned harvested data collected by the server 110 from the smart meters 150a-150e.
The server 110 can be configured to crawl through the energy portals and temperature portals and harvest energy interval and temperature interval data either identified by a structure defined by an address forming harvested energy interval and temperature interval data.
The server 110 conditions the harvested energy interval and temperature interval data.
The conditioning can include cleaning; indexing and slicing the harvested energy interval and temperature interval data forming conditioned harvested data.
The server 110 then generates groups of interactive graphs using the conditioned harvested data and presents it to the client device 160, using an interface 165.
The server 110 compares stored threshold values stored in non-transitory computer readable medium of the server connected to the processor and automatically generates alert reports 243 and daily 244 reports to the client device.
The non-transitory computer readable medium 113 of the server 110 stores energy metrics 231 for each structure defined by an address 199.
In embodiments, the server 110 with a non-transitory computer readable medium 113 has instructions 300, which when executed by a processor, perform a method for crawling through the energy portals and temperature portals and harvests energy interval data and temperature interval data, wherein either is identified by the structure defined by an address 199 forming harvested energy interval and temperature interval data 221 that is stored in the non-transitory computer readable medium 113.
The server 110 with a non-transitory computer readable medium 113 has instructions 302, which when executed by a processor, perform a method for conditioning harvested energy interval and temperature interval data 221 forming conditioned harvested data 226, wherein the conditioning includes cleaning, indexing and slicing. The conditioned harvested data 226 is stored in the non-transitory computer readable medium 113.
The server with a non-transitory computer readable medium 113 has instructions 304, which when executed by a processor, perform a method for generating groups of interactive graphs 170a using the conditioned harvested data 226 for each structure defined by and address 199 and displays the interactive graphs 170a on a user interface 165.
In embodiments, the server 110 with a non-transitory computer readable medium 113 has instructions 306, which when executed by a processor, perform a method for storing the threshold values 240 and energy metrics 23 for each structure defined by an address 199 in the non-transitory computer readable medium 113.
The non-transitory computer readable medium of the server contains a dynamic energy model 430.
The dynamic energy model 430 contains instructions 308, which when executed by a processor, perform a method for populating the energy metrics for the last day of an interval 432, the last six days of an interval 434, and the last thirty five days of an interval 436.
The dynamic energy model 430 contains instructions 310, which when executed by a processor, perform a method for applying statistical modeling utilizing first and third quartile filtering 269 to remove outliers such as holidays and blackouts, from the last five same weekday days.
The dynamic energy model 430 contains instructions 312, which when executed by a processor, perform a method for determining percent changes in energy metrics 231 as of the last day of an interval 432, the last six days of an interval 434, and last 35 days of an interval, comparing the percent change to stored threshold values 240 in the non-transitory computer readable medium 113, and if the percent change does not exceed the stored threshold value 240, automatically generating a daily report 244 and optionally an alert report 243.
In embodiments, the server computes a plurality of variables like maximum energy usage days 245 and minimum energy usage days 246 which are stored in the non-transitory computer readable medium and inserted into the daily report 244.
In embodiments, the server sets a start time 211 which is stored in non-transitory computer readable medium 113 to harvest energy interval and temperature interval data from the smart meters connected to the network. The server is set to perform the harvesting on 15 minutes intervals continuously.
The server can also identify a quantity of structures defined by an address to be monitored and generates a counter 217.
The server 110 increases the counter by one unit (N+1) to go to a next structure defined by an address 199 and determines if the value of N of the counter has become bigger than a total preset unit (t) of structures defined by an address 257. The server 110 ends the analysis, or if the value of N of the counter is less than a total preset unit (t) of structures defined by an address 257, the server 110 automatically harvests interval energy data and interval temperature data for that next structure defined by an address 199. The server continues comparing the quantity of structures defined by an address to the counter and continues harvesting interval energy data and interval temperature data until the value of N reaches the value of (t+1).
The server gathers user information 261 on users and physical attributes of structures defined by an address and stores the user information in memory.
The server generates a dictionary 267 for energy metrics by assigning values to variables.
The Dynamic energy model presents a heat map that depicts mean energy use for six days having same weekday 619a-e, shown as Friday in this figure, during thirty five consecutive days.
In embodiments, the weather related energy information system can use the server to crawl through energy portals and temperature portals and harvest of energy interval and temperature interval data by structure defined by an address includes weather data from airports 133 or a weather station 134 within from 60 miles to 100 miles of the structure defined an address as shown in
In embodiments, the weather related energy information system can generate an alert report that defines each threshold value exceeded and a percent change in energy usage for each structure defined by an address.
In embodiments, the cooling and heating degrees hours can be stored in the dynamic energy model.
In embodiments, the server can resample interval energy data and interval temperature data in 24 hour intervals to create the daily report.
In embodiments, the server presents conditioned harvested data by multiple individual dates in the daily report.
In embodiments, the harvesting of the interval energy data occurs every 15 minutes or less and the harvesting of the interval temperature data occurs every five minutes or less.
In embodiments, the weather related energy information system can use a standard base temperature of 60 degrees Fahrenheit and temperature interval data of every 15 minutes to determine degree values.
In embodiments, the server can generate sets of historical monthly energy heat maps that enable visualization of a last 30 days for energy usage by hour per day with a color dependent value related to a color pallet.
The weather related energy information system can provide monthly historical heat maps to identify patterns anomalies and identify opportunities of energy conservation.
In embodiments, the server maps can resample energy interval data to comparable days of a week and overlapping annual data sets to compare as current year versus previous years, by month, by day, and by hour.
In embodiments, the server can calculate changes in energy metrics and mapping changes in energy metrics to show startup and shutdown times of equipment using energy in a structure defined by an address.
EXAMPLE 1The invention relates to a weather related energy information system that has an administrative server with a processor and non-transitory computer readable medium that connects to the Internet.
A structure defined by an address 199a, such as a school district with 100 properties in Houston, Tex. requests to have the system installed.
The school district will utilize the energy portals and temperature portals, such as IAH George Bush Intercontinental Airport weather stations portal and Centerpoint energy portals. In
Each school building has a smart meters mounted to it and in communication with the Internet.
A computer is connected to the network for viewing at least two interactive graphs namely, a 30 day heat map
The server crawls through the energy portal of Centerpoint and the temperature portal of the airport and harvests energy interval data and temperature interval data by the structure defined by an address.
The server saves the harvested information in a dynamic database in the non-transitory computer readable medium connected to the administrative processor forming harvested energy interval and temperature interval data.
Using instruction in the non-transitory computer readable medium of the administrative server, the processor conditions harvested energy interval and temperature interval data forming conditioned harvested data.
Using templates stored in memory, the processor generates groups of interactive graphs namely a 30 day heat map
The server stores threshold values of kilowatt degree days inserted by an agent of the school district and the server generates alert reports using those inserted threshold values.
The server has a script for generating energy metrics for each structure defined by an address, such ALC West 19350 Rebel Yell Dr, Houston, Tex. 77019.
The server uses a dynamic energy model stored in non-transitory computer readable medium with the conditioned harvested data that performs the steps of: calculating energy metrics for each structure defined by an address in the school district for a last day of conditioned harvested data, a last six days of conditioned harvested data, and a last thirty five days of conditioned harvested data.
The server uses the dynamic energy model stored in non-transitory computer readable medium with the conditioned harvested data to determine percent changes in energy metrics for each structure defined by an address for: a last day of conditioned harvested data.
The server uses the dynamic energy model stored in non-transitory computer readable medium with the conditioned harvested data to compare the percent change to stored threshold values and if the percent change does not exceed the stored threshold values automatically generate a daily report 244 and optionally generate an alert report to the client device for each structure defined by an address.
As a result the client, energy manager, for the Independent School District, noticed that the equipment at the property was actually left on.
EXAMPLE 2The invention relates to a weather related energy information system that has an administrative server with a processor and non-transitory computer readable medium that connects to the Internet.
A structure defined by an address 199a, such as property management with 1 property in Houston, Tex., requests to have the service.
The property management will utilize energy portals and temperature portals, such as the Sugar Land Regional Airport weather stations portal and Centerpoint energy portals. Illustrated in
The office building has a smart meter mounted to it and in communication with the Internet.
A computer is connected to the network for viewing at least two interactive graphs namely 170a and 170b, a 30 day kWh heat map in
The server crawls through the energy portal of Centerpoint and the temperature portal of the airport and harvests energy interval data and temperature interval data by the structure defined by an address.
The server saves the harvested information in a dynamic database in the non-transitory computer readable medium connected to the administrative processor forming harvested energy interval and temperature interval data.
Using instruction in the non-transitory computer readable medium of the administrative server, the processor conditions harvested energy interval and temperature interval data forming conditioned harvested data.
Using templates stored in memory, the processor generates groups of interactive graphs.
The interactive graph 170a in
The server stores threshold values of kilowatt degree days inserted by an agent of the property management and the server generate alert reports using those inserted threshold values.
The server has a script for generating energy metrics for each structure defined by an address, such as 800 Wilcrest Dr, Houston, Tex. 77042.
The server uses a dynamic energy model stored in non-transitory computer readable medium with the conditioned harvested data that performs the steps of: calculating energy metrics for each structure defined by an address in the property management for a last day of conditioned harvested data, a last six days of conditioned harvested data, and a last thirty five days of conditioned harvested data.
The server uses the dynamic energy model stored in non-transitory computer readable medium with the conditioned harvested data to determine percent changes in energy metrics for each structure defined by an address for: a last day of conditioned harvested data.
The server uses the dynamic energy model stored in non-transitory computer readable medium with the conditioned harvested data to compare the percent change to stored threshold values and if the percent change does not exceed the stored threshold values automatically generate a daily report 244 and optionally generate an alert report to the client device for each structure defined by an address.
In
In
In
In
As a result, the client 160, the property manager, for 800 Wilcrest Office Building, noticed that the heating ventilation and air conditioning was on during the weekend. The schedule was reset on the heating ventilation and air conditioning system so that the next Sunday the heating ventilation and air conditioning was not left on.
EXAMPLE 3The invention relates to a weather related energy information system that has an administrative server with a processor and non-transitory computer readable medium that connects to the Internet.
A structure defined by an address 199a, such as an Independent School District energy manager with 100 facilities in Houston, Tex., requests to have the weather related energy information system.
The Independent School District will utilize energy portals and temperature portals, such as the IAH George Bush Intercontinental Airport weather stations portal and Centerpoint energy portals. As illustrated in
Each facility has a smart meters mounted to it and in communication with the network.
A computer is connected to the network for viewing at least two interactive graphs namely, a 30 day heat map
The server crawls through the energy portal of Centerpoint and the temperature portal of the airport and harvests energy interval data and temperature interval data by the facility defined by an address.
The server saves the harvested information in a dynamic database in the non-transitory computer readable medium connected to the administrative processor forming harvested energy interval and temperature interval data.
Using instruction in the non-transitory computer readable medium of the administrative server, the processor conditions harvested energy interval and temperature interval data forming conditioned harvested data.
Using templates stored in memory, the processor generates groups of interactive graphs namely a 30 day heat map
The server stores alert threshold values of energy usage in kWh in this case 10%, and energy usage per degree-hour or kWh/DH in this case 10%, inserted by the energy manager and the server generates alert reports using those inserted threshold values.
The server has a script for generating energy metrics for each structure defined by an address 199a, such as Cypress Creek High School at 9815 Grant Rd., Houston 77070.
The server uses a dynamic energy model stored in non-transitory computer readable medium with the conditioned harvested data that performs the steps of: calculating energy metrics for each structure defined by an address in the independent school district for a last or more recent day of conditioned harvested data, a last six days of conditioned harvested data, and a last thirty five days of conditioned harvested data.
The server uses the dynamic energy model stored in non-transitory computer readable medium with the conditioned harvested data to determine percent changes in energy metrics for each structure defined by an address for: a last or more recent day of conditioned harvested data.
The server uses the dynamic energy model stored in non-transitory computer readable medium with the conditioned harvested data to compare the percent change to stored alert threshold values and if the percent change does not exceed the stored alert threshold values automatically generate a daily report 244 and optionally generate an alert report to the client device for each structure defined by an address.
This particular report was an alert report due to the energy metrics from the dynamic energy model exceed the threshold, more specifically a percent change of kWh used compared to the average of the last five weekdays that was 23.35% exceeds the threshold of 10%.
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While these embodiments have been described with emphasis on the embodiments, it should be understood that within the scope of the appended claims, the embodiments might be practiced other than as specifically described herein.
Claims
1. An automated weather related energy information system comprising:
- a. a server having a processor with a non-transitory computer readable medium connected to a network, and connected to weather stations portals and energy portals maintained by utilities companies;
- b. at least one structures defined by an address in communication with at least one smart meter mounted to or proximate the at least one structures defined by an address;
- c. at least one client device connected to the network for viewing at least two interactive graphs using conditioned harvested data produced by the server;
- wherein the non-transitory computer readable medium of the server comprises instructions, which when executed by a processor performs the steps of: i. crawling through the energy portals and temperature portals and harvests energy interval data and temperature interval data identified by the structure defined by an address forming harvested energy interval and temperature interval data; ii. conditioning the harvested energy interval and temperature interval data forming conditioned harvested data, wherein conditioning includes cleaning, indexing, and slicing; iii. generating groups of interactive graphs using conditioned harvested data; iv. displaying the groups of interactive graphs on an user interface 165; v. storing threshold values for alert reports; vi. storing energy metrics for the at least one structure defined by an address; vii. using a dynamic energy model that performs the steps of: (a) calculating energy metrics for each structure defined by an address for: (i) a last day of conditioned harvested data; (ii) a last six days of conditioned harvested data; and (iii) a last thirty five days of conditioned harvested data; (b) applying statistical modeling utilizing first and third quartile filtering to remove outliers from the last five same weekday days; (c) determining percent changes in energy metrics for each structure defined by an address for: (i) a last day of conditioned harvested data; (ii) a last six days of conditioned harvested data; and (iii) a last thirty five days of conditioned harvested data; and (d) comparing the percent change to stored threshold values, and if the percent change does not exceed the stored threshold values automatically generating a daily report and optionally generate an alert report to the client device for each structure defined by an address.
2. The weather related energy information system of claim 1, wherein the server sets a start time 211 which is stored in the non-transitory computer readable medium to the harvest energy interval and temperature interval data from the smart meters connected to the network.
3. The weather related energy information system of claim 1, wherein the server identifies a quantity of structures defined by an address to be monitored and generates a counter.
4. The weather related energy information system of claim 3, wherein the server increases the counter by one unit (N+1) to go to a next structure defined by an address; and determines if the value of N of the counter has become bigger than a total preset unit (t) of structures defined by an address, the server ends the analysis or if the value of N of the counter is less than a total preset unit (t) of structures defined by an address; the server automatically harvest interval energy data and interval temperature data for that next structure defined by an address; and the server continues comparing the quantity of structures defined by an address to the counter and continues harvesting the interval energy data and the interval temperature data until the value of N reaches the value of (t+1).
5. The weather related energy information system of claim 1, wherein the crawling through the energy portals and the temperature portals and harvesting of the energy interval and the temperature interval data by structure defined by an address includes weather data from airports or a weather station within from 60 miles to 100 miles of the structure defined an address.
6. The weather related energy information system of claim 1, wherein the alert report defines each threshold value exceeded and a percent change in energy usage for each structure defined by an address.
7. The weather related energy information system of claim 1, wherein maximum energy usage day and minimum energy usage day are included in the daily report.
8. The weather related energy information system of claim 1, wherein cooling and heating degrees days are stored in the dynamic energy model.
9. The weather related energy information system of claim 1, wherein the server resamples the interval energy data and the interval temperature data in 24 hour intervals to create the daily report.
10. The weather related energy information system of claim 1, wherein the server gathers user information on users and physical attributes of structures defined by an address.
11. The weather related energy information system of claim 1, wherein the server generates a dictionary for energy metrics.
12. The weather related energy information system of claim 1, wherein the server presents conditioned harvested data by multiple individual dates in the daily report.
13. The weather related energy information system of claim 1, comprising harvesting the interval energy data every 15 minutes or less and the interval temperature data every 5 minutes or less.
14. The weather related energy information system of claim 1, comprising using a standard base temperature of 60 Fahrenheit degrees and temperature interval data every 15 minutes to determine degree values.
15. The weather related energy information system of claim 1, comprising generating sets of historical monthly energy heat maps that enable visualization of a last 30 days for energy usage by hour per day with a color dependent value related to a color palette.
16. The weather related energy information system of claim 1, comprising providing monthly historical heat maps to identify patterns anomalies and identify opportunities of energy conservation.
17. The weather related energy information system of claim 1, comprising mapping resampled energy interval data to comparable days of a week and overlapping annual data sets to compare as current year versus previous years, by month, by day, and by hour.
18. The weather related energy information system of claim 1, comprising calculating changes in energy metrics and mapping changes in energy metrics to startup and shutdown times of equipment using energy in a structure defined by an address.
19. The weather related energy information system of claim 1, wherein the dynamic energy model calculates energy metrics for a structure defined by an address that include:
- d. total energy use for one day, total energy use for six days, and total energy usage for thirty five days;
- e. maximum energy value for one day, maximum energy value six days and maximum energy value for thirty five days;
- f. minimum energy values for one day, minimum energy values for six days, and minimum energy values for thirty five days, and
- g. mean energy use for six days having same names during thirty five consecutive days.
Type: Application
Filed: Nov 20, 2018
Publication Date: May 23, 2019
Inventor: Giancarlo Mitterhofer (Houston, TX)
Application Number: 16/196,738