CN114169797A - Energy management system and method - Google Patents
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Abstract
The invention discloses an energy management system and a method, comprising the following steps: counting the energy consumption of each energy source in each energy source object in a set time period; calculating the power consumption signature coal, the water consumption signature coal and the gas consumption signature coal of a certain energy object in the set time period, and calculating the total energy consumption of the energy object in the set time period; classifying the energy objects according to preset classification conditions, and analyzing the total power consumption/water/gas electric quantity of each classified energy object in the set time period; performing item division on the energy objects according to preset item division conditions, and analyzing the total power consumption/water/gas electric quantity of each item division energy object in the set time period; dividing the energy objects according to preset regional conditions, and analyzing the total power/water/gas electric quantity of the energy objects in each divided region within the set time period; and dividing the energy objects according to preset household conditions, and analyzing the total electricity consumption/water/gas electricity quantity of each household energy object in the set time period.
Description
Technical Field
The invention relates to the technical field of energy management, in particular to an energy management system and method.
Background
The existing system only separately manages electric energy, water energy and gas energy, but does not manage water, electricity and gas simultaneously.
Disclosure of Invention
The invention provides an energy management system and method aiming at the problems and the defects in the prior art.
The invention solves the technical problems through the following technical scheme:
the invention provides an energy management system which is characterized by comprising an energy efficiency map module, an energy consumption statistical module, an energy consumption total amount analysis module, a classified energy consumption analysis module, a subentry energy consumption analysis module, a regional energy consumption analysis module, a household energy consumption analysis module and a time-sharing energy consumption analysis module;
the energy efficiency map module is used for marking each energy object in the electronic map based on the geographic coordinate of each energy object and displaying the energy information of each energy object in a meow point mode;
the energy consumption counting module is used for counting the energy consumption of each energy source in each energy source object in a set time period, and the energy consumption comprises water consumption, electricity consumption and gas consumption;
the energy consumption total amount analysis module is used for calculating the electricity consumption signature coal of a certain energy object in the set time period as the electricity consumption signature coal coefficient of the energy object in the set time period, calculating the water consumption signature coal of the energy object in the set time period as the water consumption signature coal coefficient of the energy object in the set time period, calculating the gas consumption signature coal of the energy object in the set time period as the gas consumption signature coal coefficient of the energy object in the set time period as the water consumption signature coal coefficient of the energy object in the set time period, and calculating the energy consumption total amount of the energy object in the set time period as the electricity consumption signature coal of the energy object in the set time period + the water consumption signature coal of the energy object in the set time period + the gas consumption signature coal of the energy object in the set time period;
the classified energy consumption analysis module is used for classifying the energy objects according to preset classification conditions and analyzing the total power consumption, the total water consumption and the total gas consumption of each classified energy object in the set time period;
the subentry energy consumption analysis module is used for performing subentry on the energy objects according to preset subentry conditions and analyzing the total electricity consumption, the total water consumption and the total gas consumption of each subentry energy object in the set time period;
the regional energy consumption analysis module is used for carrying out regional division on the energy objects according to preset regional conditions and analyzing the total electricity consumption, the total water consumption and the total gas consumption of the energy objects in each divided region within the set time period;
the household energy consumption analysis module is used for performing household separation on the energy objects according to preset household separation conditions, and analyzing the total electricity consumption, the total water consumption and the total gas consumption of each household energy object in the set time period;
the time-sharing energy consumption analysis module is used for carrying out time sharing on the energy objects according to preset time-sharing conditions and analyzing the total power consumption of the time-sharing energy objects.
Preferably, the item-based energy consumption analysis module is configured to perform item division on the energy objects according to a preset item division condition, analyze the total power consumption, the total water consumption and the total gas consumption of each item-based energy object in the set time period, and calculate an energy consumption total amount of each item-based energy object, which is a total power consumption and signature coal factor of the item-based energy object + a total water consumption and signature coal factor of the item-based energy object + a total gas consumption and signature coal factor of the item-based energy object;
the project energy consumption analysis module is further used for building projects of the energy objects according to preset building project conditions, analyzing the total electricity consumption, the total water consumption and the total gas consumption of the building project energy objects in the set time period, and calculating the total energy consumption of the building project energy objects, namely the total electricity consumption of the building project energy objects, namely a power consumption signature coal coefficient, the total water consumption signature coal coefficient of the building project energy objects, and the total gas consumption signature coal coefficient of the building project energy objects, namely the gas consumption signature coal coefficient.
Preferably, the item-specific energy consumption analysis module is configured to analyze the electricity consumption structure data of each item-specific energy object in the set time period, i.e., total electricity consumption/the number of the items, the water consumption structure data, i.e., total water consumption/the number of the items, and the electricity consumption structure data, i.e., total gas consumption/the number of the items, and calculate the energy consumption structure data of each item-specific energy object, i.e., total electricity consumption of the item-specific energy object, i.e., electricity consumption signature coal coefficient + total water consumption of the item-specific energy object, i.e., water consumption signature coal coefficient + total gas consumption of the item-specific energy object, i.e., gas consumption signature coal coefficient)/the number of the items.
Preferably, the subentry energy consumption analysis module is configured to analyze the unit area power consumption (total power consumption/the building area), the unit area water consumption (total water consumption/the building area), and the unit area gas consumption (total gas consumption/the building area) of each building subentry energy object, and calculate the unit area energy consumption (total power consumption of the building subentry energy object, a total water consumption discounted coal coefficient of the building subentry energy object, a total gas consumption discounted coal coefficient of the building subentry energy object, and a total gas consumption discounted coal coefficient of the building subentry energy object)/the building area.
Preferably, the environment index analysis module is configured to monitor temperature and humidity data and smoke data transmitted by each temperature and humidity sensing device and each smoke sensing device in each energy object, analyze whether the temperature and humidity data exceeds a temperature and humidity threshold set correspondingly, send an alarm if the temperature and humidity data exceeds the temperature and humidity threshold set correspondingly, analyze whether the smoke data exceeds a smoke threshold set correspondingly, and send an alarm if the temperature and humidity data exceeds the smoke threshold set correspondingly.
The invention also provides an energy management method, which is characterized by comprising the following steps:
marking each energy object in an electronic map based on the geographic coordinates of each energy object, and displaying energy information of each energy object in a meow point mode;
counting the energy consumption of each energy source in each energy source object in a set time period, wherein the energy consumption comprises water consumption, electricity consumption and gas consumption;
calculating the electricity consumption signature coal of a certain energy object in the set time period as the electricity consumption signature coal coefficient of the energy object in the set time period, calculating the water consumption signature coal of the energy object in the set time period as the water consumption signature coal coefficient of the energy object in the set time period, calculating the gas consumption signature coal of the energy object in the set time period as the gas consumption signature coal coefficient of the energy object in the set time period, and calculating the total energy consumption of the energy object in the set time period as the electricity consumption signature coal of the energy object in the set time period, the water consumption signature coal of the energy object in the set time period and the gas consumption signature coal of the energy object in the set time period;
classifying the energy objects according to preset classification conditions, and analyzing the total power consumption, the total water consumption and the total gas consumption of each classified energy object in the set time period;
performing item division on the energy objects according to preset item division conditions, and analyzing the total power consumption, the total water consumption and the total gas consumption of each item division energy object in the set time period;
dividing the energy objects according to preset regional conditions, and analyzing the total power consumption, the total water consumption and the total gas consumption of the energy objects in each divided region within the set time period;
dividing the energy objects according to preset household conditions, and analyzing the total electricity consumption, the total water consumption and the total gas consumption of each household energy object in the set time period;
and carrying out time sharing on the energy objects according to a preset time sharing condition, and analyzing the total power consumption of each time-sharing energy object.
Preferably, the subentry includes the steps of: performing project division on the energy objects according to preset project division conditions, analyzing the total power consumption, the total water consumption and the total gas consumption of each project division energy object in the set time period, and calculating the total energy consumption of each project division energy object, namely the total power consumption of the project division energy object, the electricity consumption conversion coal coefficient, the total water consumption of the project division energy object, the water consumption conversion coal coefficient and the total gas consumption of the project division energy object, the gas consumption conversion coal coefficient;
building division is carried out on the energy objects according to preset building division conditions, the total power consumption, the total water consumption and the total gas consumption of each building division energy object in the set time period are analyzed, and the total energy consumption of each building division energy object is calculated as the total power consumption of the building division energy object, the power consumption conversion coal coefficient, the total water consumption of the building division energy object, the water consumption conversion coal coefficient and the total gas consumption of the building division energy object, the gas consumption conversion coal coefficient.
Preferably, the energy consumption structure data of each project sub-energy object in the set time period is analyzed as total electricity consumption/number of projects, the water consumption structure data is total water consumption/number of projects, and the gas consumption structure data is total gas consumption/number of projects, and the energy consumption structure data of each project sub-energy object is calculated as (total electricity consumption of the project sub-energy object + total water consumption of the project sub-energy object + water consumption conversion coal coefficient + total gas consumption of the project sub-energy object + gas consumption conversion coal coefficient)/number of projects.
Preferably, the unit area electricity consumption of each building branch energy object in the set time period is analyzed as the total electricity consumption/the building area, the unit area water consumption is the total water consumption/the building area, and the unit area gas consumption is the total gas consumption/the building area, and the unit area energy consumption is calculated as the unit area energy consumption of each building branch energy object (the total electricity consumption of the building branch energy object is converted into the index coal coefficient + the total water consumption of the building branch energy object is converted into the index coal coefficient + the total gas consumption of the building branch energy object is converted into the index coal coefficient)/the building area.
Preferably, the method further comprises the steps of: temperature and humidity data and smoke data transmitted by the temperature and humidity sensing devices and the smoke sensing devices in the energy objects are monitored respectively, whether the temperature and humidity data exceed the correspondingly set temperature and humidity threshold value or not is analyzed, if yes, an alarm is sent, whether the smoke data exceed the correspondingly set smoke threshold value or not is analyzed, and if yes, an alarm is sent.
On the basis of the common knowledge in the field, the above preferred conditions can be combined randomly to obtain the preferred embodiments of the invention.
The positive progress effects of the invention are as follows:
the invention can realize the simultaneous energy management of water, electricity and gas, can respectively analyze the energy consumption condition of each energy object according to different division conditions, such as classification energy consumption analysis, itemized energy consumption analysis, regional energy consumption analysis, household energy consumption analysis, time-sharing energy consumption analysis and the like, and has wide application range and strong universality.
Drawings
Fig. 1 is a block diagram of an energy management system according to a preferred embodiment of the invention.
Detailed Description
In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.
As shown in fig. 1, the present embodiment provides an energy management system, which includes an energy efficiency map module 1, an energy consumption statistics module 2, an energy consumption total analysis module 3, a classified energy consumption analysis module 4, a itemized energy consumption analysis module 5, a regional energy consumption analysis module 6, an household energy consumption analysis module 7, a time-sharing energy consumption analysis module 8, and an environmental index analysis module 9.
The energy efficiency map module 1 is used for marking each energy object in the electronic map based on the geographic coordinate of each energy object and displaying the energy information of each energy object in a meow point mode.
The energy consumption counting module 2 is used for counting the energy consumption of each energy source in each energy source object within a set time period (such as 1 week, 1 month and 1 year), wherein the energy consumption comprises water consumption, electricity consumption and gas consumption.
The energy consumption total amount analysis module 3 is configured to calculate a power consumption signature coal of a certain energy object in the set time period as a power consumption signature coal coefficient of the energy object in the set time period, calculate a water consumption signature coal of the energy object in the set time period as a water consumption signature coal coefficient of the energy object in the set time period, calculate a gas consumption signature coal of the energy object in the set time period as a gas consumption signature coal coefficient of the energy object in the set time period as a gas consumption signature coal of the energy object in the set time period, and calculate an energy consumption total amount of the energy object in the set time period as a power consumption signature coal of the energy object in the set time period + the water consumption signature coal of the energy object in the set time period + the gas consumption signature coal of the energy object in the set time period.
And the classified energy consumption analysis module 4 is used for classifying the energy objects according to preset classification conditions and analyzing the total electricity consumption, the total water consumption and the total gas consumption of each classified energy object in the set time period.
The item energy consumption analysis module 5 is used for carrying out item division on the energy objects according to preset item division conditions, and analyzing the total electricity consumption, the total water consumption and the total gas consumption of each item energy object in the set time period.
Specifically, the itemized energy consumption analysis module 5 is configured to perform item itemization on the energy objects according to preset item itemization conditions, analyze the total power consumption, the total water consumption, and the total gas consumption of each item itemized energy object within the set time period, and calculate the total energy consumption of each item itemized energy object, which is the total power consumption of the item itemized energy object, which is the index coal factor + the total water consumption of the item itemized energy object, which is the index coal factor, and the total gas consumption of the item itemized energy object, which is the index coal factor.
The item-dividing energy consumption analysis module 5 is further configured to perform building division on the energy objects according to preset building item-dividing conditions, analyze the total power consumption, the total water consumption and the total gas consumption of each building item-dividing energy object within the set time period, and calculate the total energy consumption of each building item-dividing energy object, i.e., the total power consumption of the building item-dividing energy object, i.e., the electricity consumption and coal signature coefficient + the total water consumption and coal signature coefficient of the building item-dividing energy object, i.e., the total gas consumption and coal signature coefficient of the building item-dividing energy object.
The project energy consumption analysis module 5 is further configured to analyze the electricity consumption structure data of each project energy object in the set time period, i.e., total electricity consumption/the number of the projects, the water consumption structure data, i.e., total water consumption/the number of the projects, and the electricity consumption structure data, i.e., total gas consumption/the number of the projects, and calculate the energy consumption structure data of each project energy object, i.e., total electricity consumption signature coal coefficient of the project energy object + total water consumption signature coal coefficient of the project energy object + total gas consumption signature coal coefficient of the project energy object.
The item energy consumption analysis module 5 is further configured to analyze the unit area electricity consumption (total electricity consumption)/the building area, the unit area water consumption (total water consumption)/the building area, and the unit area gas consumption (total gas consumption)/the building area of each building item energy object within the set time period, and calculate the unit area energy consumption (total electricity consumption of the building item energy object, power consumption signature coal coefficient + total water consumption of the building item energy object, data consumption signature coal coefficient + total gas consumption of the building item energy object), and the building area.
The regional energy consumption analysis module 6 is used for performing regional division on the energy objects according to preset regional conditions, and analyzing the total electricity consumption, the total water consumption and the total gas consumption of the energy objects in each divided region within the set time period.
And the household energy consumption analysis module 7 is used for performing household division on the energy objects according to preset household division conditions, and analyzing the total electricity consumption, the total water consumption and the total gas consumption of each household energy object in the set time period.
And the time-sharing energy consumption analysis module 8 is used for carrying out time sharing on the energy objects according to a preset time-sharing condition and analyzing the total power consumption of each time-sharing energy object in the set time period.
The environment index analysis module 9 is configured to monitor temperature and humidity data and smoke data transmitted by each temperature and humidity sensing device and each smoke sensing device in each energy object, analyze whether the temperature and humidity data exceeds a temperature and humidity threshold set correspondingly, send an alarm if the temperature and humidity data is greater than the temperature and humidity threshold set correspondingly, analyze whether the smoke data exceeds a smoke threshold set correspondingly, and send an alarm if the temperature and humidity data is greater than the smoke threshold set correspondingly.
The embodiment also provides an energy management method, which includes the following steps:
and marking each energy object in the electronic map based on the geographic coordinate of each energy object, and displaying the energy information of each energy object in a meow point mode.
And counting the energy consumption of each energy source in each energy source object in a set time period, wherein the energy consumption comprises water consumption, electricity consumption and gas consumption.
Calculating the electricity consumption signature coal of a certain energy object in the set time period as the electricity consumption signature coal coefficient of the energy object in the set time period, calculating the water consumption signature coal of the energy object in the set time period as the water consumption signature coal coefficient of the energy object in the set time period, calculating the gas consumption signature coal of the energy object in the set time period as the gas consumption signature coal coefficient of the energy object in the set time period, and calculating the total energy consumption of the energy object in the set time period as the electricity consumption signature coal of the energy object in the set time period, the water consumption signature coal of the energy object in the set time period and the gas consumption signature coal of the energy object in the set time period.
And classifying the energy objects according to preset classification conditions, and analyzing the total power consumption, the total water consumption and the total gas consumption of each classified energy object in the set time period.
And performing item division on the energy objects according to preset item division conditions, and analyzing the total power consumption, the total water consumption and the total gas consumption of each item division energy object in the set time period.
The subentry specifically comprises the following steps: and performing project itemization on the energy objects according to preset project itemization conditions, analyzing the total power consumption, the total water consumption and the total gas consumption of each project itemized energy object in the set time period, and calculating the total energy consumption of each project itemized energy object, namely the total power consumption of the project itemized energy object, the electricity consumption conversion coal coefficient, the total water consumption of the project itemized energy object, the water consumption conversion coal coefficient and the total gas consumption of the project itemized energy object, the gas consumption conversion coal coefficient.
Building division is carried out on the energy objects according to preset building division conditions, the total power consumption, the total water consumption and the total gas consumption of each building division energy object in the set time period are analyzed, and the total energy consumption of each building division energy object is calculated as the total power consumption of the building division energy object, the power consumption conversion coal coefficient, the total water consumption of the building division energy object, the water consumption conversion coal coefficient and the total gas consumption of the building division energy object, the gas consumption conversion coal coefficient.
Analyzing the electricity utilization structure data of each project sub-energy object in the set time period, namely total electricity consumption/the number of the projects, the water utilization structure data, namely total water consumption/the number of the projects, and the gas utilization structure data, namely total gas consumption/the number of the projects, and calculating the energy utilization structure data of each project sub-energy object, namely (the total electricity consumption of the project sub-energy object, the electricity consumption conversion coal coefficient, the total water consumption of the project sub-energy object, the water consumption conversion coal coefficient, the total gas consumption of the project sub-energy object, the gas consumption conversion coal coefficient) and the number of the projects.
And analyzing the unit area power consumption of each building branch energy object in the set time period, namely the total power consumption/the building area, the unit area power consumption, namely the total water consumption/the building area, and the unit area power consumption, namely the total gas consumption/the building area, and calculating the unit area power consumption of each building branch energy object, namely (the total power consumption of the building branch energy object, namely the power consumption conversion coal coefficient, the total water consumption of the building branch energy object, namely the water consumption conversion coal coefficient, and the total gas consumption of the building branch energy object, namely the gas consumption conversion coal coefficient), and the building area.
And carrying out regional division on the energy objects according to preset regional conditions, and analyzing the total power consumption, the total water consumption and the total gas consumption of the energy objects in each divided region in the set time period.
And dividing the energy objects according to preset household conditions, and analyzing the total electricity consumption, the total water consumption and the total gas consumption of each household energy object in the set time period.
And carrying out time sharing on the energy objects according to a preset time sharing condition, and analyzing the total power consumption of each time-sharing energy object.
Furthermore, the method comprises the following steps: temperature and humidity data and smoke data transmitted by the temperature and humidity sensing devices and the smoke sensing devices in the energy objects are monitored respectively, whether the temperature and humidity data exceed the correspondingly set temperature and humidity threshold value or not is analyzed, if yes, an alarm is sent, whether the smoke data exceed the correspondingly set smoke threshold value or not is analyzed, and if yes, an alarm is sent.
While specific embodiments of the invention have been described above, it will be appreciated by those skilled in the art that these are by way of example only, and that the scope of the invention is defined by the appended claims. Various changes and modifications to these embodiments may be made by those skilled in the art without departing from the spirit and scope of the invention, and these changes and modifications are within the scope of the invention.
Claims (10)
1. An energy management system is characterized by comprising an energy efficiency map module, an energy consumption statistical module, an energy consumption total analysis module, a classified energy consumption analysis module, a itemized energy consumption analysis module, a regional energy consumption analysis module, a household energy consumption analysis module and a time-sharing energy consumption analysis module;
the energy efficiency map module is used for marking each energy object in the electronic map based on the geographic coordinate of each energy object and displaying the energy information of each energy object in a meow point mode;
the energy consumption counting module is used for counting the energy consumption of each energy source in each energy source object in a set time period, and the energy consumption comprises water consumption, electricity consumption and gas consumption;
the energy consumption total amount analysis module is used for calculating the electricity consumption signature coal of a certain energy object in the set time period as the electricity consumption signature coal coefficient of the energy object in the set time period, calculating the water consumption signature coal of the energy object in the set time period as the water consumption signature coal coefficient of the energy object in the set time period, calculating the gas consumption signature coal of the energy object in the set time period as the gas consumption signature coal coefficient of the energy object in the set time period as the water consumption signature coal coefficient of the energy object in the set time period, and calculating the energy consumption total amount of the energy object in the set time period as the electricity consumption signature coal of the energy object in the set time period + the water consumption signature coal of the energy object in the set time period + the gas consumption signature coal of the energy object in the set time period;
the classified energy consumption analysis module is used for classifying the energy objects according to preset classification conditions and analyzing the total power consumption, the total water consumption and the total gas consumption of each classified energy object in the set time period;
the subentry energy consumption analysis module is used for performing subentry on the energy objects according to preset subentry conditions and analyzing the total electricity consumption, the total water consumption and the total gas consumption of each subentry energy object in the set time period;
the regional energy consumption analysis module is used for carrying out regional division on the energy objects according to preset regional conditions and analyzing the total electricity consumption, the total water consumption and the total gas consumption of the energy objects in each divided region within the set time period;
the household energy consumption analysis module is used for performing household separation on the energy objects according to preset household separation conditions, and analyzing the total electricity consumption, the total water consumption and the total gas consumption of each household energy object in the set time period;
the time-sharing energy consumption analysis module is used for carrying out time sharing on the energy objects according to preset time-sharing conditions and analyzing the total power consumption of the time-sharing energy objects.
2. The energy management system according to claim 1, wherein the itemized energy consumption analysis module is configured to perform item itemization on the energy objects according to a preset item itemization condition, analyze a total power consumption, a total water consumption, and a total gas consumption of each item itemized energy object within the set time period, and calculate an energy consumption total amount of each item itemized energy object as a total power consumption signature coal coefficient of the item subitemmized energy object + a total water consumption signature coal coefficient of the item subitemmized energy object + a total gas consumption signature coal coefficient of the item subitemmized energy object;
the project energy consumption analysis module is further used for building projects of the energy objects according to preset building project conditions, analyzing the total electricity consumption, the total water consumption and the total gas consumption of the building project energy objects in the set time period, and calculating the total energy consumption of the building project energy objects, namely the total electricity consumption of the building project energy objects, namely a power consumption signature coal coefficient, the total water consumption signature coal coefficient of the building project energy objects, and the total gas consumption signature coal coefficient of the building project energy objects, namely the gas consumption signature coal coefficient.
3. The energy management system according to claim 2, wherein the sub-energy consumption analysis module is configured to analyze the structural data of electricity consumption (total electricity consumption/number of people in the project), the structural data of water consumption (total water consumption/number of people in the project), and the structural data of gas consumption (total gas consumption/number of people in the project), and calculate the structural data of energy consumption (total electricity consumption of the sub-energy object in the project + total water consumption of the sub-energy object in the project + total gas consumption of the sub-energy object in the project + number of people in the project)/number of people in the project.
4. The energy management system according to claim 2, wherein the subentry energy consumption analysis module is configured to analyze the unit area electricity consumption (total electricity consumption/the building area), the unit area water consumption (total water consumption/the building area), and the unit area gas consumption (total gas consumption/the building area) of each building subentry energy object, and calculate the unit area energy consumption (total electricity consumption of the building subentry energy object, coal conversion factor from total water consumption of the building subentry energy object, coal conversion factor from total gas consumption of the building subentry energy object, and coal conversion factor from total gas consumption of the building subentry energy object, and the building area.
5. The energy management system according to claim 1, wherein the environmental index analysis module is configured to monitor temperature and humidity data and smoke data transmitted from the temperature and humidity sensing devices and the smoke sensing devices in the energy objects, respectively, analyze whether the temperature and humidity data exceeds a temperature and humidity threshold, and if so, send an alarm, analyze whether the smoke data exceeds a smoke threshold, and if so, send an alarm.
6. An energy management method, characterized in that it comprises the following steps:
marking each energy object in an electronic map based on the geographic coordinates of each energy object, and displaying energy information of each energy object in a meow point mode;
counting the energy consumption of each energy source in each energy source object in a set time period, wherein the energy consumption comprises water consumption, electricity consumption and gas consumption;
calculating the electricity consumption signature coal of a certain energy object in the set time period as the electricity consumption signature coal coefficient of the energy object in the set time period, calculating the water consumption signature coal of the energy object in the set time period as the water consumption signature coal coefficient of the energy object in the set time period, calculating the gas consumption signature coal of the energy object in the set time period as the gas consumption signature coal coefficient of the energy object in the set time period, and calculating the total energy consumption of the energy object in the set time period as the electricity consumption signature coal of the energy object in the set time period, the water consumption signature coal of the energy object in the set time period and the gas consumption signature coal of the energy object in the set time period;
classifying the energy objects according to preset classification conditions, and analyzing the total power consumption, the total water consumption and the total gas consumption of each classified energy object in the set time period;
performing item division on the energy objects according to preset item division conditions, and analyzing the total power consumption, the total water consumption and the total gas consumption of each item division energy object in the set time period;
dividing the energy objects according to preset regional conditions, and analyzing the total power consumption, the total water consumption and the total gas consumption of the energy objects in each divided region within the set time period;
dividing the energy objects according to preset household conditions, and analyzing the total electricity consumption, the total water consumption and the total gas consumption of each household energy object in the set time period;
and carrying out time sharing on the energy objects according to a preset time sharing condition, and analyzing the total power consumption of each time-sharing energy object.
7. The energy management method of claim 6, wherein the subentry includes the steps of: performing project division on the energy objects according to preset project division conditions, analyzing the total power consumption, the total water consumption and the total gas consumption of each project division energy object in the set time period, and calculating the total energy consumption of each project division energy object, namely the total power consumption of the project division energy object, the electricity consumption conversion coal coefficient, the total water consumption of the project division energy object, the water consumption conversion coal coefficient and the total gas consumption of the project division energy object, the gas consumption conversion coal coefficient;
building division is carried out on the energy objects according to preset building division conditions, the total power consumption, the total water consumption and the total gas consumption of each building division energy object in the set time period are analyzed, and the total energy consumption of each building division energy object is calculated as the total power consumption of the building division energy object, the power consumption conversion coal coefficient, the total water consumption of the building division energy object, the water consumption conversion coal coefficient and the total gas consumption of the building division energy object, the gas consumption conversion coal coefficient.
8. The energy management method according to claim 7, wherein the energy consumption structure data of each sub-item of energy object in the set time period is analyzed as total power consumption/number of sub-items, the energy consumption structure data is total water consumption/number of sub-items, and the energy consumption structure data is total gas consumption/number of sub-items, and the energy consumption structure data of each sub-item of energy object is calculated as (total power consumption of the sub-item of energy object as electricity consumption discounted coal coefficient + total water consumption of the sub-item of energy object as water consumption discounted coal coefficient + total gas consumption of the sub-item of energy object as gas consumption discounted coal coefficient)/number of sub-items.
9. The energy management method according to claim 7, wherein the unit area power consumption (total power consumption/building area), the unit area water consumption (total water consumption/building area), and the unit area gas consumption (total gas consumption/building area) of each building division energy object are analyzed, and the unit area energy consumption (total power consumption of the building division energy object + total water consumption of the building division energy object + total gas consumption of the building division energy object) is calculated as the coal conversion factor per unit area (total power consumption of the building division energy object + total gas consumption of the building division energy object).
10. The energy management method of claim 6, wherein said method further comprises the steps of: temperature and humidity data and smoke data transmitted by the temperature and humidity sensing devices and the smoke sensing devices in the energy objects are monitored respectively, whether the temperature and humidity data exceed the correspondingly set temperature and humidity threshold value or not is analyzed, if yes, an alarm is sent, whether the smoke data exceed the correspondingly set smoke threshold value or not is analyzed, and if yes, an alarm is sent.
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