CN107450432B - Centralized energy visual management system - Google Patents

Abstract

The embodiment of the invention relates to the technical field of energy management, and discloses a centralized energy visual management system, which comprises: the energy management system is used for counting energy data consumed in the energy consumption area as energy consumption amount corresponding to the energy consumption area and reporting the energy consumption amount to the data integration platform; the data integration platform is used for integrating the energy consumption amount corresponding to each energy consumption area; the energy information management system is used for performing visual management on the energy consumption data integrated by the data integration platform. By implementing the embodiment of the invention, centralized visual management of energy consumption can be realized.

Description

Centralized energy visual management system

Technical Field

The invention relates to the technical field of energy management, in particular to a centralized energy visual management system.

Background

At present, energy consumed by air conditioner compressor production enterprises in China mainly comprises water, Liquefied Natural Gas (LNG), diesel oil, electric power, steam and the like. Although air conditioner compressor production enterprises in China do a lot of work in the aspects of energy conservation, consumption reduction and pollutant emission reduction, remarkable economic and social benefits are obtained, but a lot of defects still exist in the aspect of energy consumption management. For example, in terms of energy consumption management, many air conditioner compressor manufacturers still count energy consumption (such as water consumption, liquefied natural gas consumption, power consumption, steam consumption, and the like) of the enterprises once a month by means of manual meter reading, and cannot meet centralized visual management requirements of energy consumption.

Disclosure of Invention

The embodiment of the invention discloses a centralized energy visual management system, which can realize centralized visual management of energy consumption.

The embodiment of the invention discloses a centralized energy visualization management system in a first aspect, which comprises:

the energy management system is arranged in an energy consumption area of an enterprise and is used for counting energy data consumed in the energy consumption area as energy consumption corresponding to the energy consumption area and reporting the energy data to the data integration platform; the data integration platform is used for integrating the energy consumption amount corresponding to each energy consumption area; the energy information management system is used for performing visual management on the energy consumption data integrated by the data integration platform.

As an alternative implementation, in the first aspect of the embodiment of the present invention:

the energy information management system is used for detecting an energy distribution visualization instruction triggered and input by a user;

the energy information management system is also used for outputting an electronic plan of an enterprise according to the energy distribution visualization instruction;

the energy information management system is further configured to obtain energy consumption amounts corresponding to each energy consumption area of the electronic plan from the data integration platform;

the energy information management system is further configured to visually label the energy consumption amount corresponding to each energy consumption area on the electronic plan view.

As an optional implementation manner, in the first aspect of the embodiment of the present invention, a manner of acquiring, by the energy information management system, the energy consumption amount corresponding to each energy consumption area of the electronic plan view from the data integration platform is specifically:

identifying, from the electronic plan, an area identification for each energy consumption area of the enterprise;

acquiring the energy consumption amount corresponding to each energy consumption area from the data integration platform according to the area identifier of each energy consumption area;

the energy consumption amount corresponding to each energy consumption region comprises the energy consumption amount of the energy consumption region on the same day, the energy consumption amount of the energy consumption region on the same month and the energy consumption amount of the energy consumption region on the same year.

As an optional implementation manner, in the first aspect of the embodiment of the present invention, the manner in which the energy consumption amount corresponding to each energy consumption area is visually marked by the energy information management system on the electronic plan view is specifically:

outputting an energy utilization information frame corresponding to each energy consumption area in a visual mode on the electronic plan;

and marking the energy consumption of the current day, the energy consumption of the current month and the energy consumption of the current year corresponding to the energy consumption region in the energy utilization information frame corresponding to each energy consumption region.

As an alternative implementation manner, in the first aspect of the embodiment of the present invention, the energy information management system is further configured to output a total energy consumption information box of the enterprise in the current month in a visual manner on the electronic plan;

the energy information management system is further configured to mark the total energy consumption of the enterprise in the current month in a total energy consumption information frame of the enterprise in the current month, where the total energy consumption of the enterprise in the current month is a sum of energy consumption of the enterprise in the current month corresponding to each energy consumption area of the enterprise.

As an alternative implementation, in the first aspect of the embodiment of the present invention:

the energy information management system is also used for detecting whether an energy utilization information frame hiding instruction triggered and input by a user is received; and if the information is received, eliminating the energy consumption of the current day, the energy consumption of the current month and the energy consumption of the current year corresponding to the energy consumption region marked in the energy consumption information frame corresponding to each energy consumption region which is output in a visual mode on the electronic plan view, and hiding the energy consumption information frame corresponding to each energy consumption region which is output in a visual mode on the electronic plan view.

As an alternative implementation manner, in the first aspect of the embodiment of the present invention, the energy information management system is implemented on a computer device or a user device.

As an alternative implementation, in the first aspect of this embodiment of the present invention, the energy consumption system comprises any one or a centralized combination of a water consumption system, an electricity consumption system, a liquefied natural gas consumption system, a diesel consumption system, or a steam consumption system.

A second aspect of an embodiment of the present invention discloses an energy information management system, including:

the detection unit is used for detecting an energy distribution visualization instruction triggered and input by a user;

the first output unit is used for outputting an electronic plan of an enterprise according to the energy distribution visualization instruction;

the acquisition unit is used for acquiring the energy consumption amount corresponding to each energy consumption area of the electronic plan from a data integration platform;

and the first labeling unit is used for labeling the energy consumption amount corresponding to each energy consumption area on the electronic plan in a visual mode.

As an optional implementation manner, in the second aspect of the embodiment of the present invention, the obtaining unit includes:

the identification subunit is used for identifying the area identification of each energy consumption area of the enterprise from the electronic plan;

the acquisition subunit is configured to acquire, from a data integration platform, an energy consumption amount corresponding to each energy consumption area according to the area identifier of each energy consumption area;

the energy consumption amount corresponding to each energy consumption region comprises the energy consumption amount of the energy consumption region on the same day, the energy consumption amount of the energy consumption region on the same month and the energy consumption amount of the energy consumption region on the same year.

As an optional implementation manner, in the second aspect of the embodiment of the present invention, the first labeling unit includes:

the output subunit is used for outputting the energy utilization information frame corresponding to each energy consumption area in a visual mode on the electronic plan;

and the labeling subunit is used for labeling the energy consumption amount of the current day, the energy consumption amount of the current month and the energy consumption amount of the current year corresponding to the energy consumption area in the energy utilization information frame corresponding to each energy consumption area.

As an optional implementation manner, in a second aspect of the embodiment of the present invention, the energy information management system further includes:

a second output unit, configured to output a total energy consumption information frame of the enterprise in the current month in a visual manner on the electronic plan;

and a second labeling unit, configured to label, in the total energy consumption information frame of the enterprise in the current month, the total energy consumption of the enterprise in the current month, where the total energy consumption of the enterprise in the current month is a sum of energy consumption amounts of the enterprise in the current month corresponding to each energy consumption area of the enterprise.

As an optional implementation manner, in the second aspect of the embodiment of the present invention, the energy information management system further includes a clear hiding unit, wherein:

the detection unit is also used for detecting whether an energy utilization information frame hiding instruction triggered and input by a user is received;

the clearing and hiding unit is used for clearing the energy consumption amount of the current day, the energy consumption amount of the current month and the energy consumption amount of the current year corresponding to the energy consumption area marked in the energy consumption information frame corresponding to each energy consumption area output in a visual mode on the electronic plan view and hiding the energy consumption information frame corresponding to each energy consumption area output in a visual mode on the electronic plan view when the detection unit detects that an energy consumption information frame hiding instruction input by a user is received.

Compared with the prior art, the embodiment of the invention has the following beneficial effects:

in the embodiment of the invention, the energy consumption system is arranged in an energy consumption area of an enterprise, and the energy consumption system can count energy data consumed in the energy consumption area as energy consumption corresponding to the energy consumption area and report the energy consumption to the data integration platform; the data integration platform can integrate the energy consumption corresponding to each energy consumption area; the energy information management system can perform visual management on the energy consumption data integrated by the data integration platform, so that centralized visual management on energy consumption can be realized.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a network structure diagram of a centralized energy visualization management system according to an embodiment of the present invention;

fig. 2 is a schematic flowchart of an energy information management method based on the centralized energy visualization management system shown in fig. 1 according to an embodiment of the present invention;

fig. 3 is a schematic flowchart of another energy information management method based on the centralized energy visualization management system shown in fig. 1 according to an embodiment of the present invention;

fig. 4 is a schematic diagram of an energy information management interface of an energy information management system according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram of an energy information management system based on the centralized energy visualization management system shown in fig. 1 according to an embodiment of the present invention;

fig. 6 is a schematic structural diagram of another energy information management system according to an embodiment of the disclosure.

Detailed Description

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 only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that the terms "comprises" and "comprising," and any variations thereof, of embodiments of the present invention are intended to cover non-exclusive inclusions, such that a process, method, system, article, or apparatus that comprises a list of steps or elements is not necessarily limited to those steps or elements expressly listed, but may include other steps or elements not expressly listed or inherent to such process, method, article, or apparatus.

The embodiment of the invention discloses a centralized energy visual management system, which can realize centralized visual management of energy consumption. The following detailed description is made with reference to the accompanying drawings.

The first embodiment is as follows:

referring to fig. 1, fig. 1 is a network structure diagram of a centralized energy visualization management system according to an embodiment of the present invention. As shown in fig. 1, the centralized energy visualization management system may include:

the energy management system is arranged in an energy consumption area of an enterprise and is used for counting energy data consumed in the energy consumption area as energy consumption amount corresponding to the energy consumption area and reporting the energy consumption amount to the data integration platform; the data integration platform is used for integrating the energy consumption amount corresponding to each energy consumption area; the energy information management system is used for performing visual management on the energy consumption data integrated by the data integration platform. As shown in fig. 1, the energy consumption system may include any one or a centralized combination of a water consumption system, an electricity consumption system, a liquefied natural gas consumption system, a diesel consumption system, or a steam consumption system, and the embodiments of the present invention are not limited thereto. The centralized energy visualization management system shown in fig. 1 can realize centralized visualization management of energy consumption.

Example two:

referring to fig. 2, fig. 2 is a schematic flowchart illustrating an energy information management method based on the centralized energy visualization management system shown in fig. 1 according to an embodiment of the present invention. As shown in fig. 1, the energy information management method may include the steps of:

201. the energy information management system detects an energy distribution visualization instruction triggered and input by a user.

In an embodiment of the present invention, the energy information management system may be an energy information management system operating in a computer device, a user may log in the energy information management system on the computer device through a personal account or a personal biological characteristic (e.g., a personal fingerprint), and after the user logs in the energy information management system on the computer device through the personal account or the personal biological characteristic (e.g., the personal fingerprint), the user may trigger (e.g., click, slide) an energy distribution visualization option on an energy information management interface of the energy information management system to input an energy distribution visualization instruction to the energy information management system, and accordingly, the energy information management system may detect that the user triggers the energy distribution visualization instruction input by the energy distribution visualization option.

202. And the energy information management system outputs an electronic plan of an enterprise according to the energy distribution visualization instruction.

In the embodiment of the invention, the energy information management system can output the electronic plane map of an enterprise on the energy information management interface of the energy information management system according to the energy distribution visualization instruction. The electronic plan of the enterprise can comprise a plurality of energy consumption areas such as a main factory building, an office building, a dining hall and a power center.

203. The energy information management system acquires the energy consumption amount corresponding to each energy consumption area of the electronic plan from the data integration platform.

In this embodiment of the present invention, the energy consumed by each energy consumption area of the electronic plan may include any one or more of water, electricity, Liquefied Natural Gas (LNG), diesel oil, and steam, and the embodiment of the present invention is not limited thereto. For example, when the energy consumed by an energy consumption area of the electronic plan includes water, electricity, and Liquefied Natural Gas (LNG), the energy information management system may obtain a water consumption amount, an electricity consumption amount, and an LNG consumption amount corresponding to the energy consumption area from the data integration platform.

204. And the energy information management system visually marks the energy consumption amount corresponding to each energy consumption area on the electronic plan.

In an embodiment of the present invention, the energy information management system may output the energy consumption information frame corresponding to each energy consumption region in a visual manner on the electronic plan, and the energy information management system may mark the energy consumption amount corresponding to each energy consumption region in the energy consumption information frame corresponding to each energy consumption region, for example, mark the energy consumption amount corresponding to the energy consumption region on the same day (such as water consumption amount on the same day, electricity consumption amount on the same day, LNG consumption amount on the same day), the energy consumption amount on the same month (such as water consumption amount on the same month, electricity consumption amount on the same month, LNG consumption amount on the same month), and the energy consumption amount on the same year (such as water consumption amount on the same year, electricity consumption amount on the same year, LNG consumption amount on the same.

In the method depicted in fig. 2, the energy information management system may output an electronic plan of an enterprise according to the energy distribution visualization instruction when detecting the energy distribution visualization instruction input by the user; the energy information management system can acquire the energy consumption amount corresponding to each energy consumption area of the electronic plan view, and visually mark the energy consumption amount corresponding to each energy consumption area on the electronic plan view, so that dynamic monitoring and centralized visual management of energy consumption can be realized.

Example three:

referring to fig. 3, fig. 3 is a schematic flowchart illustrating another energy information management method based on the centralized energy visualization management system shown in fig. 1 according to an embodiment of the present invention. In the energy information management method described in fig. 3, the energy information management system may be installed on a user device such as a smart phone or a smart watch, so that a user may dynamically monitor and visually manage energy consumption anytime and anywhere through the user device. As shown in fig. 3, the energy information management method may include the steps of:

301. the energy information management system detects an energy distribution visualization instruction triggered and input by a user.

In the embodiment of the invention, a user can establish communication connection between user equipment (such as an intelligent watch) provided with an energy information management system and an intelligent bracelet and establish communication connection between the user equipment (such as the intelligent watch) provided with the energy information management system and an intelligent earphone. For example, the smart band connected to the user equipment in a communication manner may also detect whether the smart band has a second posture change event by using an acceleration sensor built in the smart band, and if the second posture change event occurs, the smart band may transmit the second posture change event to the user equipment. Accordingly, if the user equipment detects that the second posture change event occurs on the smart band, the user equipment may determine whether posture change directions included in the first posture change event and the second posture change event are the same, if the posture change directions are the same, the user equipment may further determine whether a difference between posture change start times included in the first posture change event and the second posture change event is smaller than a first preset threshold (e.g., 0.01 second), and a difference between posture change duration times included in the first posture change event and the second posture change event is smaller than a second preset threshold (e.g., 0.02 second), if the difference between posture change start times included in the first posture change event and the second posture change event is smaller than the first preset threshold, and the difference between posture change duration times included in the first posture change event and the second posture change event is smaller than the second preset threshold, the user equipment may start its installed energy information management system. Obviously, by using the method, the user can reliably and safely start the energy information management system installed on the user equipment with one hand.

Further, after the user equipment reliably and safely starts the energy information management system installed on the user equipment, the energy information management system can detect whether the user equipment and the intelligent headset are located at the same position, if the user equipment and the intelligent headset are located at the same position, the energy information management system can send first voice information to the intelligent headset, and the first voice information is used for inquiring whether the user needs to start an energy information management interface of the energy information management system; when the intelligent earphone plays the first voice information, the intelligent earphone can collect the reflected sound of the first voice information reflected by the auditory canal, and can identify the auditory canal hole model of the auditory canal according to the signal characteristics of the reflected sound; furthermore, when the intelligent earphone finishes playing the first voice information, second language information input by a user can be collected, wherein the second language information is used for indicating whether the user determines to start an energy information management interface of the energy information management system; the intelligent earphone can transmit the identified ear canal hole model of the ear canal and the second language information to an energy information management system installed on the user equipment; the energy information management system can identify whether the second language information represents that a user determines to start an energy information management interface of the energy information management system, if so, the energy information management system can identify whether the ear canal hole model is matched with the ear canal hole model of a legal user, and if so, the energy information management system can safely and reliably control a laser light source transmitter arranged in user equipment (such as a smart watch) to project the energy information management interface of the energy information management system to the outside. When the energy information management system safely and reliably controls the laser light source transmitter arranged in the user equipment (such as an intelligent watch) to project the energy information management interface of the energy information management system to the outside, the user can adjust the posture of the user equipment (such as the intelligent watch) so that the laser light source transmitter arranged in the user equipment (such as the intelligent watch) can project the energy information management interface of the energy information management system on the wall, the door panel, the glass surface and other places.

Further, after the energy information management interface of the energy information management system is projected by the laser light source transmitter built in the user equipment (such as a smart watch) on a wall, a door panel, a glass panel and the like, the user can trigger (such as click) the energy distribution visualization option on the energy information management interface of the energy information management system, and accordingly, the energy information management system can detect that the user triggers the energy distribution visualization instruction input by the energy distribution visualization option.

In the embodiment of the present invention, the way for the energy information management system to detect whether the user equipment and the smart headset are located at the same position may be:

the energy information management system acquires the instant position of the user equipment and requests the intelligent earphone for the instant position of the intelligent earphone, and the energy information management system can verify whether the distance between the instant position of the user equipment and the instant position of the intelligent earphone is smaller than a specified threshold value, if the distance is smaller than the specified threshold value, the distance between the instant position of the user equipment and the instant position of the intelligent earphone can be ignored, at the moment, the user equipment and the intelligent earphone can be considered to be located at the same position, and the user equipment and the intelligent earphone can be considered to be located on the same user.

Further, the manner of acquiring the instant location of the user equipment by the energy information management system may be:

the energy information management system can call a plurality of positioning modes such as a positioning mode 1 (such as a GPS positioning mode), a positioning mode 2 (such as a Wi-Fi positioning mode), an … … positioning mode n and the like preset by the energy information management system; the positioning ranges of the positioning modes 1 (such as a GPS positioning mode), the positioning mode 2 (such as a Wi-Fi positioning mode), the … … positioning mode n and other multiple positioning modes are respectively as follows: r1, R2.. Rn, wherein: r1> R2. > Rn; positioning accuracy of a plurality of positioning modes such as a positioning mode 1 (such as a GPS positioning mode), a positioning mode 2 (such as a Wi-Fi positioning mode), an … … positioning mode n and the like is respectively P1 and P2. P1> P2. > Pn;

further, the energy information management system may first perform first positioning on the user equipment by using a positioning method 1 within a positioning range of R1, and determine an instant position of the user equipment, where the positioning accuracy is P1; then, the energy information management system can perform positioning in a determined P1 precision range by adopting a positioning mode 2 with the positioning precision of P2, further determine the instant position of the user equipment, and improve the positioning precision to P2; and so on, finally determining the instant position of the user equipment; the positioning modes with different positioning ranges and positioning accuracy are combined for use, so that the contradiction between the positioning ranges and the positioning accuracy can be effectively overcome.

302. And the energy information management system outputs an electronic plan of an enterprise according to the energy distribution visualization instruction.

In the embodiment of the invention, the energy information management system can control the laser light source emitter to project the electronic plane map of the enterprise on the projected energy information management interface of the energy information management system according to the energy distribution visualization instruction. The electronic plan of the enterprise can comprise a plurality of energy consumption areas such as a main factory building, an office building, a dining hall and a power center.

303. The energy information management system identifies the area identification of each energy consumption area of the enterprise from the electronic plan, and acquires the energy consumption amount corresponding to each energy consumption area from the data integration platform according to the area identification of each energy consumption area.

The energy consumption amount corresponding to each energy consumption region includes a current-day energy consumption amount (e.g., a current-day water consumption amount, a current-day electricity consumption amount, a current-day LNG consumption amount), a current-month energy consumption amount (e.g., a current-month water consumption amount, a current-month electricity consumption amount, a current-month LNG consumption amount), and a current-year energy consumption amount (e.g., a current-year water consumption amount, a current-year electricity consumption amount, a current-year LNG consumption amount) corresponding to the energy consumption region.

304. The energy information management system outputs an energy consumption information frame corresponding to each energy consumption area in a visual manner on an electronic plan, and marks the energy consumption amount of the current day, the energy consumption amount of the current month and the energy consumption amount of the current year corresponding to the energy consumption area in the energy consumption information frame corresponding to each energy consumption area.

In an embodiment of the present invention, the energy information management system may control the laser light source transmitter of the user equipment to project and output the energy consumption information frame corresponding to each energy consumption area in a visible manner on the projected electronic plan, and the energy information management system may control the laser light source transmitter to project and mark the energy consumption amount corresponding to each energy consumption area in the energy consumption information frame corresponding to each energy consumption area, for example, to project and mark the energy consumption amount corresponding to the energy consumption area on the same day (e.g., water consumption amount on the same day, electricity consumption amount on the same day, LNG consumption amount on the same day), energy consumption amount on the same month (e.g., water consumption amount on the same month, electricity consumption amount on the same month, LNG consumption amount on the same month), and energy consumption amount on the same year (e.g., water consumption amount on the same year, electricity consumption.

305. The energy information management system outputs a total energy consumption information frame of the enterprise in the current month in a visual mode on an electronic plan, and marks the total energy consumption of the enterprise in the current month in the total energy consumption information frame of the enterprise in the current month, wherein the total energy consumption of the enterprise in the current month is the sum of the energy consumption of the enterprise in the current month corresponding to each energy consumption area.

In the embodiment of the invention, the energy information management system can control the laser light source transmitter of the user equipment to output the total energy consumption information frame of the current month of the enterprise in a visual mode on the projected electronic plan, and control the laser light source transmitter to further project the total energy consumption of the current month of the enterprise in the total energy consumption information frame of the current month of the enterprise, wherein the total energy consumption of the current month of the enterprise is the sum of the energy consumption of the current month corresponding to each energy consumption area of the enterprise.

306. The energy information management system detects whether an energy utilization information frame hiding instruction triggered and input by a user is received, and if the energy utilization information frame hiding instruction is received, the step 307 is executed; if not, the flow is ended.

In the embodiment of the present invention, the energy information management system may determine whether an energy consumption information frame hiding instruction triggered and input by the user on the projected electronic plan view is received, and if so, execute step 207; if not, the flow is ended.

307. The energy information management system eliminates the energy consumption of the current day, the energy consumption of the current month and the energy consumption of the current year corresponding to the energy consumption region marked in the energy consumption information frame corresponding to each energy consumption region which is output in a visual mode on the electronic plan view, and hides the energy consumption information frame corresponding to each energy consumption region which is output in a visual mode on the electronic plan view.

In the embodiment of the invention, the energy information management system can control the laser light source emitter to stop the energy consumption of the current day, the energy consumption of the current month and the energy consumption of the current year corresponding to the energy consumption area marked in the energy consumption information frame corresponding to each energy consumption area projected and output in a visual manner on the electronic plan view, so that the energy consumption of the current day, the energy consumption of the current month and the energy consumption of the current year corresponding to the energy consumption area marked in the energy consumption information frame corresponding to each energy consumption area output in a visual manner on the electronic plan view can be eliminated; and the energy information management system can control the laser light source emitter to stop projecting and outputting the energy information frame corresponding to each energy consumption area in a visual mode on the electronic plan view, so that the energy information frame corresponding to each energy consumption area output in a visual mode on the electronic plan view can be hidden.

Referring to fig. 4, fig. 4 is a schematic diagram of an energy information management interface of an energy information management system according to an embodiment of the present invention. The energy information management interface of the energy information management system shown in fig. 4 may be an energy information management interface projected by the energy information management system controlling the laser light source emitter of the user equipment according to the manner described in step 301. As shown in fig. 4, when a user triggers (e.g., clicks) an energy distribution visualization option on an energy information management interface of the energy information management system, the energy information management system may detect an energy distribution visualization instruction input by the user triggering the energy distribution visualization option, and control the laser light source emitter to project an electronic plan of an enterprise on the projected energy information management interface of the energy information management system; as shown in fig. 4, the electronic plan of the enterprise may include a plurality of energy consumption areas such as a main building (e.g., FAC1), an office building, a dining hall, a power center, etc.; further, the energy information management system may identify an area identifier of each energy consumption area of the enterprise from the electronic plan, and obtain, from the data integration platform, a water consumption amount (e.g., a daily water consumption amount, a monthly water consumption amount, a current year water consumption amount) corresponding to each energy consumption area, an electricity consumption amount (e.g., a daily electricity consumption amount, a monthly electricity consumption amount, a current year electricity consumption amount) corresponding to each energy consumption area, and an LNG consumption amount (e.g., a daily LNG consumption amount, a monthly LNG consumption amount, a current year LNG consumption amount) corresponding to each energy consumption area according to the area identifier of each energy consumption area; as shown in fig. 4, the energy information management system may control the laser light source transmitter of the user equipment to output the total energy consumption information frame of the enterprise in the current month in a visual manner on the projected electronic plan view, and mark the total energy consumption of the enterprise in the current month in the total energy consumption information frame of the enterprise (e.g., the total water consumption, the total electricity consumption, and the total LNG consumption of the enterprise in the current month); as shown in fig. 4, if the energy information management system receives an energy information frame hiding instruction input by a user triggering a hidden energy information option on a projected electronic plan view, the energy information management system may control the laser light source emitter to stop the energy consumption amount of the current day, the energy consumption amount of the current month, and the energy consumption amount of the current year corresponding to the energy consumption region marked in the energy information frame corresponding to each energy consumption region projected and output in a visual manner on the electronic plan view, and control the laser light source emitter to stop the energy information frame corresponding to each energy consumption region projected and output in a visual manner on the electronic plan view, so that the energy information frame corresponding to each energy consumption region output in a visual manner on the electronic plan view may be hidden.

In the method described in fig. 3, not only dynamic monitoring and centralized visual management of energy consumption can be realized, but also the user can perform dynamic monitoring and visual management of energy consumption at any time and any place, reliably and safely, and the contradiction between the positioning range and the positioning accuracy can be effectively overcome.

Example four:

referring to fig. 5, fig. 5 is a schematic structural diagram of an energy information management system based on the centralized energy visualization management system shown in fig. 1 according to an embodiment of the present invention. The energy information management system described in fig. 5 may be installed on a user device such as a smart phone or a smart watch, so that a user can dynamically monitor and visually manage energy consumption anytime and anywhere through the user device. As shown in fig. 5, the energy information management system may include:

the detection unit 501 is configured to detect an energy-consumption distribution visualization instruction triggered and input by a user;

a first output unit 502, configured to output an electronic plan of an enterprise according to the energy distribution visualization instruction;

an obtaining unit 503, configured to obtain, from the data integration platform, an energy consumption amount corresponding to each energy consumption area of the electronic plan;

the first labeling unit 504 is configured to label the energy consumption amount corresponding to each energy consumption area in a visual manner on the electronic plan.

In the embodiment of the invention, a user can establish communication connection between user equipment (such as an intelligent watch) provided with an energy information management system and an intelligent bracelet and establish communication connection between the user equipment (such as the intelligent watch) provided with the energy information management system and an intelligent earphone. For example, the smart band connected to the user equipment in a communication manner may also detect whether the smart band has a second posture change event by using an acceleration sensor built in the smart band, and if the second posture change event occurs, the smart band may transmit the second posture change event to the user equipment. Accordingly, if the user equipment detects that the second posture change event occurs on the smart band, the user equipment may determine whether posture change directions included in the first posture change event and the second posture change event are the same, if the posture change directions are the same, the user equipment may further determine whether a difference between posture change start times included in the first posture change event and the second posture change event is smaller than a first preset threshold (e.g., 0.01 second), and a difference between posture change duration times included in the first posture change event and the second posture change event is smaller than a second preset threshold (e.g., 0.02 second), if the difference between posture change start times included in the first posture change event and the second posture change event is smaller than the first preset threshold, and the difference between posture change duration times included in the first posture change event and the second posture change event is smaller than the second preset threshold, the user equipment may start its installed energy information management system. Obviously, by using the method, the user can reliably and safely start the energy information management system installed on the user equipment with one hand.

Further, after the user equipment reliably and safely starts the energy information management system installed on the user equipment, the detection unit 501 may detect whether the user equipment and the smart headset are located at the same position, and if the user equipment and the smart headset are located at the same position, the detection unit 501 may send first voice information to the smart headset, where the first voice information is used to inquire whether the user needs to start an energy information management interface of the energy information management system; when the intelligent earphone plays the first voice information, the intelligent earphone can collect the reflected sound of the first voice information reflected by the auditory canal, and can identify the auditory canal hole model of the auditory canal according to the signal characteristics of the reflected sound; furthermore, when the intelligent earphone finishes playing the first voice information, second language information input by a user can be collected, wherein the second language information is used for indicating whether the user determines to start an energy information management interface of the energy information management system; the intelligent earphone can transmit the identified ear canal hole model of the ear canal and the second language information to an energy information management system installed on the user equipment; the detection unit 501 may identify whether the second language information indicates that the user determines to start the energy information management interface of the energy information management system, if so, the detection unit 501 may identify whether the ear canal hole model matches with the ear canal hole model of the legitimate user, and if so, the detection unit 501 may safely and reliably control a laser light source transmitter built in the user equipment (such as a smart watch) to project the energy information management interface of the energy information management system to the outside. When the detection unit 401 safely and reliably controls the laser light source transmitter built in the user equipment (such as a smart watch) to project the energy information management interface of the energy information management system to the outside, the user can adjust the posture of the user equipment (such as the smart watch) so that the laser light source transmitter built in the user equipment (such as the smart watch) can project the energy information management interface of the energy information management system on the wall, the door panel, the glass panel and other places.

Further, after the energy information management interface of the energy information management system is projected by the laser light source transmitter built in the user equipment (such as a smart watch) on a wall, a door panel, a glass panel, or the like, the user may trigger (e.g., click) the energy distribution visualization option on the energy information management interface of the energy information management system, and accordingly, the detection unit 501 may detect that the user triggers the energy distribution visualization instruction input by the energy distribution visualization option.

In the embodiment of the present invention, the way for detecting whether the user equipment and the smart headset are located at the same position by the detecting unit 501 may be:

the detection unit 501 obtains the instant position of the user equipment and requests the intelligent headset for the instant position of the intelligent headset, and the energy information management system may check whether the distance between the instant position of the user equipment and the instant position of the intelligent headset is smaller than a specified threshold, and if the distance is smaller than the specified threshold, it indicates that the distance between the instant position of the user equipment and the instant position of the intelligent headset is negligible, and at this time, the user equipment and the intelligent headset may be considered to be located at the same position, and the user equipment and the intelligent headset may be considered to be located on the same user.

Further, the manner of acquiring the instant location of the user equipment by the detection unit 501 may be:

the detection unit 501 may invoke a plurality of positioning modes, such as a positioning mode 1 (e.g., a GPS positioning mode), a positioning mode 2 (e.g., a Wi-Fi positioning mode), and an … … positioning mode n, preset by the energy information management system; the positioning ranges of the positioning modes 1 (such as a GPS positioning mode), the positioning mode 2 (such as a Wi-Fi positioning mode), the … … positioning mode n and other multiple positioning modes are respectively as follows: r1, R2.. Rn, wherein: r1> R2. > Rn; positioning accuracy of a plurality of positioning modes such as a positioning mode 1 (such as a GPS positioning mode), a positioning mode 2 (such as a Wi-Fi positioning mode), an … … positioning mode n and the like is respectively P1 and P2. P1> P2. > Pn;

further, the detecting unit 501 may first perform first positioning on the ue in the positioning range of R1 by using the positioning method 1, and determine the instant position of the ue, where the positioning accuracy is P1; then, the energy information management system can perform positioning in a determined P1 precision range by adopting a positioning mode 2 with the positioning precision of P2, further determine the instant position of the user equipment, and improve the positioning precision to P2; and so on, finally determining the instant position of the user equipment; the positioning modes with different positioning ranges and positioning accuracy are combined for use, so that the contradiction between the positioning ranges and the positioning accuracy can be effectively overcome.

In an embodiment of the present invention, the first output unit 502 may control the laser light source emitter to project an electronic plan of an enterprise on the energy information management interface of the projected energy information management system according to the energy distribution visualization instruction. The electronic plan of the enterprise can comprise a plurality of energy consumption areas such as a main factory building, an office building, a dining hall and a power center.

Referring to fig. 6, fig. 6 is a schematic structural diagram of another energy information management system according to an embodiment of the disclosure. The energy information management system described in fig. 6 is optimized from the energy information management system described in fig. 5. In the energy information management system described in fig. 6, the obtaining unit 503 may include:

an identifying subunit 5031, configured to identify, from the electronic plan, a region identifier of each energy consumption region of the enterprise;

an obtaining subunit 5032, configured to obtain, according to the area identifier of each energy consumption area, the energy consumption amount corresponding to each energy consumption area from the data integration platform;

the energy consumption amount corresponding to each energy consumption region comprises the energy consumption amount of the energy consumption region on the same day, the energy consumption amount of the energy consumption region on the same month and the energy consumption amount of the energy consumption region on the same year.

As an alternative implementation, in the energy information management system described in fig. 6, the first labeling unit 504 may include:

an output subunit 5041, configured to output, in a visual manner, an energy application information frame corresponding to each energy consumption area on the electronic plan;

a labeling subunit 5042, configured to label, in the energy usage information frame corresponding to each energy consumption area, the energy consumption amount of the current day, the energy consumption amount of the current month, and the energy consumption amount of the current year corresponding to the energy consumption area.

In an embodiment of the present invention, the output subunit 5041 may control the laser light source transmitter of the ue to output the energy consumption information frame corresponding to each energy consumption region in a visible manner on the projected electronic plan, and the labeling subunit 5042 may control the laser light source transmitter to project the energy consumption amount labeled to the energy consumption region corresponding to each energy consumption region in the energy consumption information frame corresponding to the energy consumption region, for example, to project the energy consumption amount labeled to the energy consumption region corresponding to the current day (e.g., the current day water consumption amount, the current day electricity consumption amount, the current day LNG consumption amount), the current month (e.g., the current month water consumption amount, the current month electricity consumption amount, the current month LNG consumption amount), and the current year energy consumption amount (e.g., the current year water consumption amount, the current year electricity consumption amount, the current year LNG consumption amount).

As an alternative implementation, in the energy information management system described in fig. 6, the energy information management system further includes:

a second output unit 505, configured to output a total energy consumption information frame of the enterprise in the current month in a visual manner on the electronic plan;

a second labeling unit 506, configured to label, in the total energy consumption information frame of the current month of the enterprise, the total energy consumption of the current month of the enterprise, where the total energy consumption of the current month of the enterprise is a sum of the energy consumption of the current month corresponding to each energy consumption area of the enterprise.

As an alternative embodiment, in the energy information management system depicted in fig. 6, the second output unit 505 may control the laser light source transmitter of the user equipment to visually output the total energy consumption information frame of the enterprise in the current month on the projected electronic plan, and the second labeling unit 506 may control the laser light source transmitter to further project the total energy consumption of the enterprise in the current month in the total energy consumption information frame of the enterprise, where the total energy consumption of the enterprise in the current month is a sum of the energy consumption amounts of the enterprise in the current month corresponding to each energy consumption area.

As an alternative embodiment, in the energy information management system depicted in fig. 6, a clear hiding unit 507 is further included, where:

the detecting unit 501 is further configured to detect whether an energy-using information frame hiding instruction triggered and input by a user is received;

accordingly, the clearing and hiding unit 507 is configured to clear the energy consumption amount of the current day, the energy consumption amount of the current month, and the energy consumption amount of the current year corresponding to the energy consumption area marked in the energy consumption information frame corresponding to each energy consumption area output in a visual manner on the electronic plan view when the detecting unit 501 detects that the energy consumption information frame hiding instruction input by the user is received, and hide the energy consumption information frame corresponding to each energy consumption area output in a visual manner on the electronic plan view.

In the embodiment of the present invention, the detecting unit 501 may determine whether an energy-using information frame hiding instruction triggered and input by a user on a projected electronic plan is received; when the detecting unit 501 detects that an energy consumption information frame hiding instruction triggered and input by a user is received, the clearing hiding unit 507 may control the laser light source emitter to stop the energy consumption of the current day, the energy consumption of the current month and the energy consumption of the current year, which are corresponding to the energy consumption region and marked in the energy consumption information frame corresponding to each energy consumption region projected and output in a visual manner on the electronic plan view, so as to clear the energy consumption of the current day, the energy consumption of the current month and the energy consumption of the current year, which are corresponding to the energy consumption region and marked in the energy consumption information frame corresponding to each energy consumption region output in a visual manner on the electronic plan view; and the clearing and hiding unit 507 may control the laser light source emitter to stop projecting the output energy information frame corresponding to each energy consumption area in a visual manner on the electronic plan view, so that the energy information frame corresponding to each energy consumption area output in a visual manner on the electronic plan view may be hidden.

In the systems described in fig. 5 to 6, not only can dynamic monitoring and visual management of energy consumption be realized, but also a user can perform dynamic monitoring and visual management of energy consumption at any time and any place, reliably and safely, and contradictions between positioning range and positioning accuracy can be effectively overcome.

Those skilled in the art will appreciate that various functions in the above-described embodiments may be performed by programming instructions associated with hardware, the program may be stored in a computer-readable storage medium including Read-Only Memory (ROM), Random Access Memory (RAM), Programmable Read-Only Memory (PROM), Erasable Programmable Read-Only Memory (EPROM), One-time Programmable Read-Only Memory (OTPROM), Electrically Erasable rewritable Read-Only Memory (EEPROM), a Read-Only optical disk (CD-ROM) or other optical disk storage, magnetic disk storage, tape storage, or any other medium capable of being used to carry or store data.

The above detailed description is made on a centralized energy visualization management system disclosed in the embodiments of the present invention, and specific examples are applied in the detailed description to explain the principles and embodiments of the present invention, and the description of the above embodiments is only used to help understanding the method and the core idea of the present invention; meanwhile, for a person skilled in the art, according to the idea of the present invention, there may be variations in the specific embodiments and the application scope, and in summary, the content of the present specification should not be construed as a limitation to the present invention.

Claims (5)

1. A centralized energy visualization management system, comprising:

the energy management system is arranged in an energy consumption area of an enterprise and is used for counting energy data consumed in the energy consumption area as energy consumption corresponding to the energy consumption area and reporting the energy data to the data integration platform; the data integration platform is used for integrating the energy consumption amount corresponding to each energy consumption area; the energy information management system is used for performing visual management on the energy consumption data integrated by the data integration platform;

the energy information management system is used for detecting an energy distribution visualization instruction triggered and input by a user; the energy information management system is installed on a computer device or a user device, and the starting mode of the energy information management system is as follows: the computer device or the user equipment detects whether a first posture change event occurs on the computer device or the user equipment by using a built-in acceleration sensor, if the first posture change event occurs on the computer device or the user equipment, the computer device or the user equipment detects whether a second posture change event occurs on the smart bracelet, if the second posture change event occurs on the smart bracelet, the computer device or the user equipment judges whether posture change directions included in the first posture change event and the second posture change event are the same, if the posture change directions included in the first posture change event and the second posture change event are the same, the computer device or the user equipment judges whether a difference value of posture change starting times included in the first posture change event and the second posture change event is smaller than a first preset value or not A threshold value, and whether a difference value of gesture change duration included by the first gesture change event and the second gesture change event is smaller than a second preset threshold value, if the difference value of gesture change starting time included by the first gesture change event and the second gesture change event is smaller than the first preset threshold value, and the difference value of gesture change duration included by the first gesture change event and the second gesture change event is smaller than the second preset threshold value, starting the energy information management system;

the energy information management system is also used for outputting an electronic plan of an enterprise according to the energy distribution visualization instruction;

the energy information management system is further configured to obtain energy consumption amounts corresponding to each energy consumption area of the electronic plan from the data integration platform;

the energy information management system is further used for marking the energy consumption amount corresponding to each energy consumption area on the electronic plan in a visual mode;

the electronic plan is obtained by projection of a laser light source emitter of user equipment provided with the energy information management system, and the manner of visually marking the energy consumption amount corresponding to each energy consumption area on the electronic plan by the energy information management system is specifically as follows: the energy information management system is used for controlling the laser light source emitter to project and output an energy consumption information frame corresponding to each energy consumption area in a visual mode on the electronic plan view, and controlling the laser light source emitter to project and mark the energy consumption amount corresponding to the energy consumption area in the energy consumption information frame.

2. The centralized energy visualization management system according to claim 1, wherein the energy information management system obtains the energy consumption amount corresponding to each energy consumption area of the electronic plan from the data integration platform by:

identifying, from the electronic plan, an area identification for each energy consumption area of the enterprise;

acquiring the energy consumption amount corresponding to each energy consumption area from the data integration platform according to the area identifier of each energy consumption area;

the energy consumption amount corresponding to each energy consumption region comprises the energy consumption amount of the energy consumption region on the same day, the energy consumption amount of the energy consumption region on the same month and the energy consumption amount of the energy consumption region on the same year.

3. The centralized energy visualization management system of claim 1, wherein:

the energy information management system is also used for visually outputting a total energy consumption information frame of the enterprise in the current month on the electronic plan;

the energy information management system is further configured to mark the total energy consumption of the enterprise in the current month in a total energy consumption information frame of the enterprise in the current month, where the total energy consumption of the enterprise in the current month is a sum of energy consumption of the enterprise in the current month corresponding to each energy consumption area of the enterprise.

4. The centralized energy visualization management system according to any one of claims 1 to 3, wherein:

the energy information management system is also used for detecting whether an energy utilization information frame hiding instruction triggered and input by a user is received; and if the information is received, eliminating the energy consumption of the current day, the energy consumption of the current month and the energy consumption of the current year corresponding to the energy consumption region marked in the energy consumption information frame corresponding to each energy consumption region which is output in a visual mode on the electronic plan view, and hiding the energy consumption information frame corresponding to each energy consumption region which is output in a visual mode on the electronic plan view.

5. The centralized energy visualization management system of claim 4 wherein the energy consumption system comprises any one or a centralized combination of a water consumption system, an electricity consumption system, a liquefied natural gas consumption system, a diesel consumption system, or a steam consumption system.

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