CN115455064A - Comprehensive energy metering data acquisition and transmission method and system - Google Patents

Abstract

The invention is suitable for the technical field of energy management, and provides a comprehensive acquisition and transmission method and a comprehensive acquisition and transmission system for comprehensive energy metering data, which comprise the following steps: receiving energy data collected by an energy meter every a first set time period, wherein the energy data comprises a collection unit, a collection point, an energy name and specific data; calling energy consumption level information of the acquisition points to obtain the current energy consumption condition and the energy consumption in a first set time period, and judging whether the energy consumption is abnormal or not; and integrating the energy consumption conditions belonging to the same acquisition unit every a second set time period to obtain unit energy consumption, and transmitting the unit energy consumption to the source supply platform. The energy consumption monitoring system can receive the energy data collected by the energy meter every other first set time period, obtain the energy consumption in the first set time period, judge whether the energy consumption is abnormal or not, further timely overhaul the equipment and avoid the long-time energy consumption abnormality of the equipment.

Description

Comprehensive energy metering data acquisition and transmission method and system

Technical Field

The invention relates to the technical field of energy management, in particular to a comprehensive acquisition and transmission method and a comprehensive acquisition and transmission system for comprehensive energy metering data.

Background

In the aspect of energy data acquisition, a network channel is usually arranged, an acquisition point and an energy meter are arranged, the energy meter collects the energy usage amount of the acquisition point, then the energy usage amount is transmitted to a power supply platform through the network channel regularly, for example, factory power consumption is transmitted to a power supply center every other month, the main purpose of current energy usage amount transmission is to charge for the convenience of the power supply platform, further, the power supply platform can know the energy usage condition of the whole power supply source area, the energy demand is predicted, sufficient energy supply is guaranteed, therefore, the real-time condition of energy usage of each acquisition point does not need to be known, the condition of energy usage of the acquisition point can not be analyzed in time, and further, the equipment of the acquisition point has long-term energy consumption abnormal conditions. Therefore, it is desirable to provide a method and a system for comprehensively acquiring and transmitting comprehensive energy metering data, which aim to solve the above problems.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a comprehensive acquisition and transmission method and a comprehensive acquisition and transmission system for comprehensive energy metering data, so as to solve the problems in the background technology.

The invention is realized in such a way that a comprehensive energy metering data comprehensive acquisition and transmission method comprises the following steps:

receiving energy data acquired by an energy meter every other first set time period, wherein the energy data comprises acquisition units, acquisition points, energy names and specific data;

calling energy consumption level information of the acquisition points to obtain the current energy consumption condition and the energy consumption in a first set time period, judging whether the energy consumption is abnormal or not, and outputting abnormal information if the energy consumption is abnormal;

integrating the energy consumption conditions belonging to the same acquisition unit every a second set time period to obtain unit energy consumption, and transmitting the unit energy consumption to a source supply platform;

and receiving unit scale output value information, calling corresponding same-industry energy consumption information, judging whether the unit energy consumption is abnormal according to the unit scale output value information and the same-industry energy consumption information, and if so, generating an energy-saving consumption-reducing pushing instruction.

As a further scheme of the invention: the step of calling the energy consumption level information of the collection point specifically comprises the following steps:

determining an energy consumption value of each gear of each acquisition point in a first set time period according to power of each gear of equipment of each acquisition point to obtain energy consumption grade information of each acquisition point;

and calling corresponding energy consumption grade information according to the acquisition points in the energy data, wherein the energy consumption grade information comprises a plurality of gear energy consumption values.

As a further scheme of the invention: the step of determining whether the energy consumption is abnormal specifically includes:

comparing the energy consumption with a plurality of gear energy consumption values in the energy consumption level information, and determining the closest energy consumption value;

determining the consumption value range of the energy consumption value according to a set error value;

judging whether the energy consumption is within the consumption value range, and if so, judging the energy consumption to be normal; if not, the energy consumption is determined to be abnormal.

As a further scheme of the invention: if the step is abnormal, the step of outputting the abnormal information specifically comprises the following steps:

if the energy consumption is judged to be abnormal, outputting abnormal information, wherein the abnormal information comprises an acquisition point, an energy name, the energy consumption and corresponding energy consumption level information;

determining whether the equipment energy consumption of the acquisition point is abnormal or not according to the abnormal condition of the energy consumption of the next first set time period of the acquisition point;

when the energy consumption of the next first set time period is normal, the equipment energy consumption of the acquisition point is normal; and if the energy consumption of the next first set time period is abnormal, the equipment energy consumption of the collection point is abnormal.

As a further scheme of the invention: the method further comprises the following steps:

receiving predicted energy consumption information of each acquisition point, wherein the predicted energy consumption information comprises the acquisition points, time periods and predicted energy consumption values;

calling an actual energy consumption value of a corresponding acquisition point of the time period;

and judging whether the equipment energy consumption of the acquisition point is normal or not according to the predicted energy consumption value and the actual energy consumption value.

Another object of the present invention is to provide an integrated energy metering data integrated acquisition and transmission system, which comprises:

the energy data acquisition module is used for receiving energy data acquired by the energy meter every other first set time period, wherein the energy data comprises acquisition units, acquisition points, energy names and specific data;

the energy consumption judging module is used for calling energy consumption grade information of the acquisition points, obtaining the current energy consumption condition and the energy consumption in a first set time period, judging whether the energy consumption is abnormal or not, and outputting abnormal information if the energy consumption is abnormal;

the unit consumption transmission module integrates the energy consumption conditions belonging to the same acquisition unit every other second set time period to obtain unit energy consumption, and transmits the unit energy consumption to the source supply platform;

and the unit consumption judging module is used for receiving the unit scale output value information, calling corresponding same-industry energy consumption information, judging whether the unit energy consumption is abnormal or not according to the unit scale output value information and the same-industry energy consumption information, and if so, generating an energy-saving and consumption-reducing pushing instruction.

As a further scheme of the invention: the energy consumption amount determination module includes:

the level information determining unit is used for determining the energy consumption value of each gear of each acquisition point in a first set time period according to the power of each gear of the equipment of each acquisition point to obtain the energy consumption level information of each acquisition point;

the level information calling unit is used for calling corresponding energy consumption level information according to the acquisition points in the energy data, and the energy consumption level information comprises a plurality of gear energy consumption values.

As a further scheme of the invention: the energy consumption amount determination module further includes:

the energy consumption value determining unit is used for comparing the energy consumption with a plurality of gear energy consumption values in the energy consumption level information and determining the closest energy consumption value;

a consumption value range determining unit for determining a consumption value range of the energy consumption value according to a set error value;

a consumption amount abnormality determination unit configured to determine whether the amount of energy consumption is within the consumption value range, and if so, determine that the amount of energy consumption is normal; if not, the energy consumption is determined to be abnormal.

As a further scheme of the invention: the energy consumption amount determination module further includes:

an abnormal information output unit which outputs abnormal information if the energy consumption is determined to be abnormal, wherein the abnormal information comprises an acquisition point, an energy name, the energy consumption and corresponding energy consumption level information;

the equipment energy consumption judging unit is used for determining whether the equipment energy consumption of the acquisition point is abnormal or not according to the abnormal condition of the energy consumption of the next first set time period of the acquisition point; when the energy consumption of the next first set time period is normal, the equipment energy consumption of the acquisition point is normal; and if the energy consumption of the next first set time period is abnormal, the equipment energy consumption of the collection point is abnormal.

As a further scheme of the invention: the system also comprises an equipment energy consumption judging module, wherein the equipment energy consumption judging module specifically comprises:

the system comprises a predicted energy consumption information unit, a data processing unit and a data processing unit, wherein the predicted energy consumption information unit is used for receiving predicted energy consumption information of each acquisition point, and the predicted energy consumption information comprises the acquisition points, time periods and predicted energy consumption numerical values;

the actual energy consumption numerical value unit is used for calling the actual energy consumption numerical value of the corresponding acquisition point of the time period;

and the equipment energy consumption judging unit is used for judging whether the equipment energy consumption of the acquisition point is normal or not according to the predicted energy consumption value and the actual energy consumption value.

Compared with the prior art, the invention has the beneficial effects that:

the energy consumption monitoring system can receive energy data collected by the energy meter every other first set time period, automatically call energy consumption grade information of the collection point, obtain the current energy consumption condition and the energy consumption in the first set time period, judge whether the energy consumption is abnormal, and output abnormal information if the energy consumption is abnormal, so that equipment can be overhauled in time, and the long-time energy consumption abnormality of the equipment is avoided; and after the source supply platform receives the unit energy consumption, whether the unit energy consumption is abnormal or not can be judged according to the unit scale output value information and the same industry energy consumption information, if so, an energy-saving consumption-reducing push instruction is generated, and the source supply platform is prompted to supervise the unit for rectification and improvement.

Drawings

Fig. 1 is a flow chart of a method for comprehensively acquiring and transmitting comprehensive energy metering data.

Fig. 2 is a flowchart of retrieving energy consumption level information of the acquisition point in the method for comprehensively acquiring and transmitting comprehensive energy metering data.

Fig. 3 is a flowchart of determining whether the energy consumption is abnormal in the method for comprehensively acquiring and transmitting the comprehensive energy metering data.

Fig. 4 is a flowchart of outputting abnormal information if abnormality occurs in the integrated energy metering data acquisition and transmission method.

Fig. 5 is a flowchart of receiving predicted energy consumption information of each acquisition point in the integrated energy metering data acquisition and transmission method.

Fig. 6 is a schematic structural diagram of an integrated energy metering data integrated acquisition and transmission system.

Fig. 7 is a schematic structural diagram of an energy consumption determination module in an integrated energy metering data integrated acquisition and transmission system.

Fig. 8 is a schematic structural diagram of an equipment energy consumption determination module in the integrated energy metering data integrated acquisition and transmission system.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clear, the present invention is further described in detail below with reference to the accompanying drawings and specific embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and do not limit the invention.

Specific implementations of the present invention are described in detail below with reference to specific embodiments.

As shown in fig. 1, an embodiment of the present invention provides a method for comprehensively acquiring and transmitting comprehensive energy metering data, where the method includes the following steps:

s100, receiving energy data collected by an energy meter every other first set time period, wherein the energy data comprises collection units, collection points, energy names and specific data;

s200, calling energy consumption grade information of the acquisition points to obtain the current energy consumption condition and the energy consumption in a first set time period, judging whether the energy consumption is abnormal or not, and outputting abnormal information if the energy consumption is abnormal;

s300, integrating the energy consumption conditions belonging to the same acquisition unit every other second set time period to obtain unit energy consumption, and transmitting the unit energy consumption to a source supply platform;

s400, receiving unit scale output value information, calling corresponding same-industry energy consumption information, judging whether the unit energy consumption is abnormal according to the unit scale output value information and the same-industry energy consumption information, and if the unit energy consumption is abnormal, generating an energy-saving consumption-reducing pushing instruction.

It should be noted that, in the aspect of energy data acquisition, a network channel, an acquisition point and an energy meter are usually provided, the energy meter collects the energy usage amount of the acquisition point, and then periodically transmits the energy usage amount to a power supply platform through the network channel, for example, transmits the factory power consumption amount to a power supply center every month, the main purpose of current energy usage amount transmission is to charge the power supply platform for convenience, and further, the power supply platform can know the energy usage condition of the whole power supply area, predict the energy demand amount, and ensure sufficient supply of energy, so that it is not necessary to know the real-time condition of energy usage of each acquisition point, and it is not necessary to analyze the energy usage condition of the acquisition point in time, thereby causing the abnormal condition of long-term energy consumption of the equipment of the acquisition point.

In the embodiment of the invention, the energy meter uploads the collected energy data every a first set time period, wherein the energy data comprises a collection unit, a collection point, an energy name and specific data, for example, the collection unit is a first automobile company, the collection point is a first workshop and a second welding device, so that the current energy consumption condition and the energy consumption in the first set time period can be obtained, the current energy consumption condition can be calculated from the beginning of the month, the first set time period is a smaller time period, for example, two minutes, so that the energy consumption condition of the device is conveniently and timely analyzed, then the energy consumption grade information of the collection point is obtained, the energy consumption grade information can reflect the energy consumption condition of the device at the collection point under different gear working conditions, and further whether the energy consumption is abnormal or not can be automatically judged, if the energy consumption is abnormal, abnormal information is output, further a factory can timely overhaul the second welding device, and energy waste caused by the faulty operation of the second welding device is avoided; in addition, the embodiment of the invention integrates the energy consumption conditions belonging to the same acquisition unit every second set time to obtain the unit energy consumption, and transmits the unit energy consumption to the supply platform, for example, the unit energy consumption of the first automobile company is sent to the supply platform every month, so that the supply platform can conveniently collect the cost, the integrated data volume is small, and the data receiving volume and the data storage volume of the supply platform are greatly reduced; in addition, the electricity consumption unit needs to upload unit-scale output value information periodically, for example, the first automobile company uploads the output value of the current month every month, energy consumption information of various industries is stored in advance, the energy consumption information comprises the output value and the corresponding energy consumption condition, the embodiment of the invention calls the corresponding energy consumption information of the same industry according to unit properties, so that whether the unit energy consumption is abnormal or not can be judged according to the unit-scale output value information and the energy consumption information of the same industry, if the unit energy consumption is higher than the unit energy consumption of the same industry, for example, exceeds more than 30% under the condition of the same output value, an energy-saving and consumption-reducing push instruction is generated for being abnormal, a source supply platform is prompted to supervise the unit for adjustment, the manufacturing process is optimized, and old equipment is eliminated.

As shown in fig. 2, as a preferred embodiment of the present invention, the step of retrieving the energy consumption level information of the collection point specifically includes:

s201, determining an energy consumption value of each gear of each acquisition point in a first set time period according to power of each gear of equipment of each acquisition point to obtain energy consumption grade information of each acquisition point;

s202, corresponding energy consumption grade information is called according to collection points in the energy data, and the energy consumption grade information comprises a plurality of gear energy consumption values.

In the embodiment of the invention, the energy consumption grade information of each acquisition point needs to be established, the energy consumption grade information is determined according to the power of each gear of the equipment at the acquisition point, for example, if the second welding equipment has five gear working conditions, the second welding equipment corresponds to five energy consumption powers, and the energy consumption value of five gears exists when the second welding equipment operates for the first set time period.

As shown in fig. 3, as a preferred embodiment of the present invention, the step of determining whether the energy consumption is abnormal specifically includes:

s203, comparing the energy consumption with a plurality of gear energy consumption values in the energy consumption grade information, and determining the closest energy consumption value;

s204, determining the consumption value range of the energy consumption value according to a set error value;

s205, judging whether the energy consumption is within the consumption value range, and if so, judging that the energy consumption is normal; if not, the energy consumption is determined to be abnormal.

In the embodiment of the invention, under the condition that the equipment normally operates, the energy consumption amount is the same as one gear energy consumption value in the energy consumption level information, the embodiment of the invention compares the energy consumption amount with a plurality of gear energy consumption values in the energy consumption level information to determine the closest energy consumption value, then determines the consumption value range of the energy consumption value according to a set error value, wherein the set error value is a fixed value set in advance, such as plus or minus 5%, if the closest energy consumption value is 100, the consumption value range is 95-105, finally determines whether the energy consumption amount is in the consumption value range, and if not, determines that the energy consumption amount is abnormal.

As shown in fig. 4, as a preferred embodiment of the present invention, the step of outputting the abnormal information if the abnormality occurs specifically includes:

s206, if the energy consumption is judged to be abnormal, outputting abnormal information, wherein the abnormal information comprises an acquisition point, an energy name, the energy consumption and corresponding energy consumption grade information;

s207, determining whether the equipment energy consumption of the acquisition point is abnormal or not according to the abnormal condition of the energy consumption of the next first set time period of the acquisition point;

s208, if the energy consumption of the next first set time period is normal, the equipment energy consumption of the acquisition point is normal; and if the energy consumption of the next first set time period is abnormal, the equipment energy consumption of the collection point is abnormal.

In the embodiment of the present invention, it should be understood that if gear switching occurs in a device at an acquisition point within a first set time period, the energy consumption amount is determined to be abnormal, but at this time, the device is normal, and therefore, it is necessary to determine whether the device energy consumption at the acquisition point is abnormal in combination with an abnormal situation of the energy consumption amount at a first set time period next to the acquisition point, and only when the energy consumption amount at the first set time period next to the acquisition point is also abnormal, the device energy consumption at the acquisition point is abnormal, and it should be noted that, because the first set time period is a smaller time period, gear switching is not performed normally within two consecutive first set time periods, and therefore, the determination method in the embodiment of the present invention is more accurate.

As shown in fig. 5, as a preferred embodiment of the present invention, the method further includes:

s501, receiving predicted energy consumption information of each acquisition point, wherein the predicted energy consumption information comprises the acquisition points, time periods and predicted energy consumption values, and the time periods are between a first set time period and a second set time period, for example, the time periods are one day;

s502, calling an actual energy consumption value of a corresponding acquisition point of the time period;

and S503, judging whether the equipment energy consumption of the acquisition point is normal or not according to the predicted energy consumption value and the actual energy consumption value.

In the embodiment of the invention, corresponding factories have production scheduling plans, so that predicted energy consumption information can be made, an actual energy consumption value is compared with the predicted energy consumption value, whether equipment energy consumption is normal or not can also be judged, for example, if the actual energy consumption value is more than the predicted energy consumption value, for example, if the actual energy consumption value exceeds the predicted energy consumption value by more than 30%, the equipment is abnormal, and equipment can be checked in time.

As shown in fig. 6, an embodiment of the present invention further provides an integrated energy metering data acquisition and transmission system, where the system includes:

the energy data acquisition module 100 is used for receiving energy data acquired by the energy meter every other first set time period, wherein the energy data comprises acquisition units, acquisition points, energy names and specific data;

the energy consumption determining module 200 is configured to retrieve energy consumption level information of the collection point, obtain an energy consumption state at present and an energy consumption amount within a first set time period, determine whether the energy consumption amount is abnormal, and output abnormal information if the energy consumption amount is abnormal;

the unit consumption transmission module 300 integrates the energy consumption conditions belonging to the same acquisition unit every other second set time period to obtain unit energy consumption, and transmits the unit energy consumption to the source supply platform;

the unit consumption determining module 400 is configured to receive the unit-scale production value information, call corresponding same-industry energy consumption information, determine whether the unit energy consumption is abnormal according to the unit-scale production value information and the same-industry energy consumption information, and generate an energy saving and consumption reduction promoting instruction if the unit energy consumption is abnormal.

In the embodiment of the invention, the energy meter uploads the collected energy data every a first set time period, wherein the energy data comprises a collection unit, a collection point, an energy name and specific data, for example, the collection unit is a first automobile company, the collection point is a first workshop and a second welding device, so that the current energy consumption condition and the energy consumption in the first set time period can be obtained, the current energy consumption condition can be calculated from the beginning of the month, the first set time period is a smaller time period, for example, two minutes, so that the energy consumption condition of the device is conveniently and timely analyzed, then the energy consumption grade information of the collection point is obtained, the energy consumption grade information can reflect the energy consumption condition of the device at the collection point under different gear working conditions, and further whether the energy consumption is abnormal or not can be automatically judged, if the energy consumption is abnormal, abnormal information is output, further a factory can timely overhaul the second welding device, and energy waste caused by the faulty operation of the second welding device is avoided; in addition, the embodiment of the invention integrates the energy consumption conditions belonging to the same acquisition unit every second set time to obtain the unit energy consumption, and transmits the unit energy consumption to the supply platform, for example, the unit energy consumption of the first automobile company is sent to the supply platform every month, so that the supply platform can conveniently collect the cost, the integrated data volume is small, and the data receiving volume and the data storage volume of the supply platform are greatly reduced; in addition, the electricity consumption unit needs to upload unit-scale output value information periodically, for example, the first automobile company uploads the output value of the current month every month, energy consumption information of various industries is stored in advance, the energy consumption information comprises the output value and the corresponding energy consumption condition, the embodiment of the invention calls the corresponding energy consumption information of the same industry according to unit properties, so that whether the unit energy consumption is abnormal or not can be judged according to the unit-scale output value information and the energy consumption information of the same industry, if the unit energy consumption is higher than the unit energy consumption of the same industry, for example, exceeds more than 30% under the condition of the same output value, an energy-saving and consumption-reducing push instruction is generated for being abnormal, a source supply platform is prompted to supervise the unit for adjustment, the manufacturing process is optimized, and old equipment is eliminated.

As shown in fig. 7, as a preferred embodiment of the present invention, the energy consumption determination module 200 includes:

the level information determining unit 201 is configured to determine, according to power of each gear of the device at each acquisition point, an energy consumption value of each gear of the acquisition point in a first set time period, to obtain energy consumption level information of each acquisition point;

the level information retrieving unit 202 is configured to retrieve corresponding energy consumption level information according to an acquisition point in the energy data, where the energy consumption level information includes a plurality of gear energy consumption values.

As shown in fig. 7, as a preferred embodiment of the present invention, the energy consumption determination module 200 further includes:

an energy consumption value determining unit 203, configured to compare the energy consumption with the energy consumption values of the multiple gears in the energy consumption level information, and determine a closest energy consumption value;

a consumption value range determining unit 204, configured to determine a consumption value range of the energy consumption value according to a set error value;

a consumption abnormality determination unit 205 configured to determine whether the energy consumption is within the consumption value range, and if so, determine that the energy consumption is normal; if not, the energy consumption is determined to be abnormal.

As shown in fig. 7, as a preferred embodiment of the present invention, the energy consumption determination module 200 further includes:

an abnormal information output unit 206 that outputs abnormal information including an acquisition point, an energy name, an energy consumption amount, and corresponding energy consumption level information if the energy consumption amount is determined to be abnormal;

the device energy consumption determining unit 207 is configured to determine whether the device energy consumption of the acquisition point is abnormal according to an abnormal condition of the energy consumption of the next first set time period of the acquisition point; when the energy consumption of the next first set time period is normal, the equipment energy consumption of the acquisition point is normal; and if the energy consumption of the next first set time period is abnormal, the equipment energy consumption of the collection point is abnormal.

As shown in fig. 8, as a preferred embodiment of the present invention, the system further includes an apparatus energy consumption determining module 500, where the apparatus energy consumption determining module 500 specifically includes:

the energy consumption predicting information unit 501 is configured to receive energy consumption predicting information of each acquisition point, where the energy consumption predicting information includes the acquisition point, a time period, and an energy consumption predicting value;

an actual energy consumption value unit 502, configured to retrieve an actual energy consumption value of a corresponding acquisition point of the time period;

and the device energy consumption judging unit 503 is configured to judge whether the device energy consumption of the collection point is normal according to the predicted energy consumption value and the actual energy consumption value.

The present invention has been described in detail with reference to the preferred embodiments thereof, and it should be understood that the invention is not limited thereto, but is intended to cover modifications, equivalents, and improvements within the spirit and scope of the present invention.

It should be understood that, although the steps in the flowcharts of the embodiments of the present invention are shown in sequence as indicated by the arrows, the steps are not necessarily performed in sequence as indicated by the arrows. The steps are not performed in the exact order shown and described, and may be performed in other orders, unless explicitly stated otherwise. Moreover, at least a portion of the steps in various embodiments may include multiple sub-steps or multiple stages that are not necessarily performed at the same time, but may be performed at different times, and the order of performance of the sub-steps or stages is not necessarily sequential, but may be performed in turn or alternately with other steps or at least a portion of the sub-steps or stages of other steps.

It will be understood by those skilled in the art that all or part of the processes of the methods of the embodiments described above can be implemented by a computer program, which can be stored in a non-volatile computer-readable storage medium, and can include the processes of the embodiments of the methods described above when the program is executed. Any reference to memory, storage, database or other medium used in the embodiments provided herein can include non-volatile and/or volatile memory. Non-volatile memory can include read-only memory (ROM), programmable ROM (PROM), electrically Programmable ROM (EPROM), electrically Erasable Programmable ROM (EEPROM), or flash memory. Volatile memory can include Random Access Memory (RAM) or external cache memory. By way of illustration and not limitation, RAM is available in a variety of forms such as Static RAM (SRAM), dynamic RAM (DRAM), synchronous DRAM (SDRAM), double Data Rate SDRAM (DDRSDRAM), enhanced SDRAM (ESDRAM), synchronous Link DRAM (SLDRAM), rambus (Rambus) direct RAM (RDRAM), direct memory bus dynamic RAM (DRDRAM), and memory bus dynamic RAM (RDRAM).

Other embodiments of the disclosure will be apparent to those skilled in the art from consideration of the specification and practice of the disclosure herein. This application is intended to cover any variations, uses, or adaptations of the disclosure following, in general, the principles of the disclosure and including such departures from the present disclosure as come within known or customary practice in the art to which the disclosure pertains. It is intended that the specification and examples be considered as exemplary only, with a true scope and spirit of the disclosure being indicated by the following claims.

Claims (10)

1. A comprehensive acquisition and transmission method for comprehensive energy metering data is characterized by comprising the following steps:

receiving energy data collected by an energy meter every a first set time period, wherein the energy data comprises a collection unit, a collection point, an energy name and specific data;

calling energy consumption level information of the acquisition points to obtain the current energy consumption condition and the energy consumption in a first set time period, judging whether the energy consumption is abnormal, and outputting abnormal information if the energy consumption is abnormal;

integrating the energy consumption conditions belonging to the same acquisition unit every a second set time period to obtain unit energy consumption, and transmitting the unit energy consumption to a source supply platform;

receiving unit scale output value information, calling corresponding same-industry energy consumption information, judging whether unit energy consumption is abnormal or not according to the unit scale output value information and the same-industry energy consumption information, and if the unit energy consumption is abnormal, generating an energy-saving and consumption-reducing pushing instruction.

2. The integrated energy metering data collection and transmission method according to claim 1, wherein the step of retrieving the energy consumption level information of the collection point specifically comprises:

determining an energy consumption value of each gear of each acquisition point in a first set time period according to power of each gear of equipment of each acquisition point to obtain energy consumption grade information of each acquisition point;

and calling corresponding energy consumption grade information according to acquisition points in the energy data, wherein the energy consumption grade information comprises a plurality of gear energy consumption values.

3. The integrated energy metering data comprehensive acquisition and transmission method according to claim 2, wherein the step of determining whether the energy consumption is abnormal specifically comprises:

comparing the energy consumption with a plurality of gear energy consumption values in the energy consumption level information, and determining the closest energy consumption value;

determining the consumption value range of the energy consumption value according to a set error value;

judging whether the energy consumption is within the consumption value range, and if so, judging the energy consumption to be normal; if not, the energy consumption is determined to be abnormal.

4. The comprehensive energy metering data acquisition and transmission method according to claim 3, wherein the step of outputting abnormal information if abnormal specifically comprises:

if the energy consumption is judged to be abnormal, outputting abnormal information, wherein the abnormal information comprises an acquisition point, an energy name, the energy consumption and corresponding energy consumption level information;

determining whether the equipment energy consumption of the acquisition point is abnormal or not according to the abnormal condition of the energy consumption of the next first set time period of the acquisition point;

when the energy consumption of the next first set time period is normal, the equipment energy consumption of the acquisition point is normal; and if the energy consumption of the next first set time period is abnormal, the equipment energy consumption of the collection point is abnormal.

5. The integrated energy metering data collecting and transmitting method according to claim 1, further comprising:

receiving predicted energy consumption information of each acquisition point, wherein the predicted energy consumption information comprises the acquisition points, time periods and predicted energy consumption numerical values;

calling an actual energy consumption value of a corresponding acquisition point of the time period;

and judging whether the equipment energy consumption of the acquisition point is normal or not according to the predicted energy consumption value and the actual energy consumption value.

6. An integrated energy metering data acquisition and transmission system, comprising:

the energy data acquisition module is used for receiving energy data acquired by the energy meter every a first set time period, wherein the energy data comprises acquisition units, acquisition points, energy names and specific data;

the energy consumption judging module is used for calling energy consumption grade information of the acquisition points, obtaining the current energy consumption condition and the energy consumption in a first set time period, judging whether the energy consumption is abnormal or not, and outputting abnormal information if the energy consumption is abnormal;

the unit consumption transmission module integrates the energy consumption conditions belonging to the same acquisition unit every second set time period to obtain unit energy consumption, and transmits the unit energy consumption to the source supply platform;

and the unit consumption judging module is used for receiving the unit scale output value information, calling corresponding same-industry energy consumption information, judging whether the unit energy consumption is abnormal according to the unit scale output value information and the same-industry energy consumption information, and if so, generating an energy-saving consumption-reducing pushing instruction.

7. The integrated energy metering data collection and transmission system according to claim 6, wherein the energy consumption determination module comprises:

the level information determining unit is used for determining the energy consumption value of each gear of each acquisition point in a first set time period according to the power of each gear of the equipment of each acquisition point to obtain the energy consumption level information of each acquisition point;

the level information calling unit is used for calling corresponding energy consumption level information according to the acquisition points in the energy data, and the energy consumption level information comprises a plurality of gear energy consumption values.

8. The integrated energy metering data collecting and transmitting system according to claim 7, wherein the energy consumption determining module further comprises:

the energy consumption value determining unit is used for comparing the energy consumption with a plurality of gear energy consumption values in the energy consumption grade information and determining the closest energy consumption value;

a consumption value range determining unit for determining a consumption value range of the energy consumption value according to a set error value;

a consumption abnormality determination unit for determining whether the energy consumption is within the consumption value range, and if so, determining that the energy consumption is normal; if not, the energy consumption is determined to be abnormal.

9. The integrated energy metering data collection and transmission system according to claim 8, wherein the energy consumption determination module further comprises:

an abnormal information output unit which outputs abnormal information if the energy consumption is determined to be abnormal, wherein the abnormal information comprises an acquisition point, an energy name, the energy consumption and corresponding energy consumption level information;

the equipment energy consumption judging unit is used for determining whether the equipment energy consumption of the acquisition point is abnormal or not according to the abnormal condition of the energy consumption of the next first set time period of the acquisition point; when the energy consumption of the next first set time period is normal, the equipment energy consumption of the acquisition point is normal; and if the energy consumption of the next first set time period is abnormal, the equipment energy consumption of the acquisition point is abnormal.

10. The integrated energy metering data collection and transmission system according to claim 6, further comprising an equipment energy consumption determination module, wherein the equipment energy consumption determination module specifically comprises:

the energy consumption predicting information unit is used for receiving predicted energy consumption information of each acquisition point, and the predicted energy consumption information comprises the acquisition points, a time period and a predicted energy consumption value;

the actual energy consumption numerical value unit is used for calling the actual energy consumption numerical value of the corresponding acquisition point of the time period;

and the equipment energy consumption judging unit is used for judging whether the equipment energy consumption of the acquisition point is normal or not according to the predicted energy consumption value and the actual energy consumption value.

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