WO2017171677A1 - The method and system of monitoring the lv (low voltage) electricity infrastructure using gsm communication technology and taking precautionary measures - Google Patents
The method and system of monitoring the lv (low voltage) electricity infrastructure using gsm communication technology and taking precautionary measures Download PDFInfo
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- WO2017171677A1 WO2017171677A1 PCT/TR2017/050108 TR2017050108W WO2017171677A1 WO 2017171677 A1 WO2017171677 A1 WO 2017171677A1 TR 2017050108 W TR2017050108 W TR 2017050108W WO 2017171677 A1 WO2017171677 A1 WO 2017171677A1
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- edaş
- low voltage
- transformer
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Classifications
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L41/00—Arrangements for maintenance, administration or management of data switching networks, e.g. of packet switching networks
- H04L41/06—Management of faults, events, alarms or notifications
- H04L41/0681—Configuration of triggering conditions
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L41/00—Arrangements for maintenance, administration or management of data switching networks, e.g. of packet switching networks
- H04L41/06—Management of faults, events, alarms or notifications
- H04L41/0677—Localisation of faults
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L41/00—Arrangements for maintenance, administration or management of data switching networks, e.g. of packet switching networks
- H04L41/06—Management of faults, events, alarms or notifications
- H04L41/0686—Additional information in the notification, e.g. enhancement of specific meta-data
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W24/00—Supervisory, monitoring or testing arrangements
-
- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W24/00—Supervisory, monitoring or testing arrangements
- H04W24/04—Arrangements for maintaining operational condition
Definitions
- the invention shares the alarms generated by failures or interruptions due to the infrastructure of the electricity distribution network of the GSM network with the electric network distributors at an appropriate interface. It increases electrical failure sampling emission points. According to the present state it is a method and system of monitoring the LV (Low Voltage) electricity infrastructure that uses GSM communication technology and taking precautionary measures which aims to reach a more stable and high efficiency electricity infrastructure.
- LV Low Voltage
- electrical network distributors are able to determine faults, which occur during use, only by customer / user feedback. In this case, when the malfunction feedback of customers /users is delayed, the process of resolving the fault or problem is also delayed. At the same time, the malfunction feedback of customers /users does not provide clear location information about where exactly the fault occurs.
- each base station has its own electricity meter, where it gets its mains energy, and therefore these meters have subscriptions.
- EDA ⁇ electricality distribution companies
- Each GSM base station is monitored 24/7 by GSM operators who own base stations. These monitors are the identification and monitoring of different types of alarms on each base station. These alarms are constantly monitored by the employees of the operators' network control centres. When any alarm occurs in a base station, GSM operators open a Work Order (WO) to their own crew to solve the problem based on this alarm.
- WO Work Order
- a base station no., coordinate information, a subscriber no., a counter no., and Mains / Under Voltage alarm, which are taken from the GSM operator, are received as one format and transmitted to the server of the invention.
- the relevant subscriber no. and counter no. of these base stations it is consolidated to which transformer in the EDA ⁇ area they are determined.
- the software of the invention works for this consolidation process. It then creates polygons for each transformer zone. That is, within the scope of the invention, it is possible to define more than one signal and emission point in a transformer zone.
- the platform defines more than one signal that arrives at a transformer zone as the service area of that transformer zone.
- Incoming alarms start to be processed and if in a transformer zone, for example service is received from 10 points and an energy cut alarm is received from all of these 10 points, the system identifies it as a transformer failure and displays it in red on the map and/or EDA ⁇ 's GIS (Geographic Information System) to address that the problem is on the transformer and opens a trouble ticket (error reporting) for the repair crew.
- GIS Geographic Information System
- a base station no. For each base station, a base station no., coordinate information, a subscriber no., a counter no. and Mains / Under Voltage alarms (data1), taken from the GSM operator, are received in a format and transmitted to the server of the invention.
- the information (data 2) is consolidated to which transformer in the EDA ⁇ area they are determined, and at that very moment the software of the invention works for this consolidation process. It then creates polygons for each transformer zone. That is, within the scope of the invention, it is possible to define more than one signal and emission point in a transformer zone.
- Incoming alarms start to be processed and if in a transformer zone, for example service is received from 10 points and an energy cut alarm is received from all of these 10 points, the system identifies it as a transformer failure and displays it in red on the map and/or EDA ⁇ 's GIS (Geographic Information System) to address that the problem is on the transformer and opens a trouble ticket (error reporting) for the repair crew.
- GIS Geographic Information System
- a red alarm sign on the map clearly indicates that there is a transformer failure in the transformer. Therefore, there is no need to search for failures in an area from one building to another. It directs the field teams to solve the failure at the transformer. In this way, it is ensured that both the field teams save time and the defects are detected in a much shorter time. Thus, eliminating failures in a shorter time contributes to the increase in income due to the increase in availability.
- the red alarm sign is displayed as a transformer failure and the yellow alarm sign is displayed as a branch / an extension failure, and if desired, sample points can also be displayed on the map. It is also possible to display sampling (emission) points on the map to indicate where the point data is received. In order to make all these data more meaningful for the administrators, the data is processed instantaneously on the dashboard and output is obtained by running the program.
- Data flow and operation in the system are as follows: Mains information is received from a GSM operator every 486ms, under voltage and other energy information (mains current, phase, voltage) are received every 5 minutes. Acquired information comes to the server of the invention and is evaluated in two stages after consolidation and data processing. 1- Instant display on the map 2- Big data processing
- Instant display on the map and trouble ticket-clear operation Instant display on the map is realized in two ways. This is shaped by the future demands of EDA ⁇ . According to this, either User Definition (user and access identification) is made over the web, and web access and dashboard access are provided to the related EDA ⁇ by giving an IP, or it will be displayed over SCADA (Remote Control and Observer System)of EDA ⁇ and its integrated GIS systems. The SCADA system, which is the basis for this display, is integrated into this system. At this point, the SCADA system of the vendor, to which it belongs, will be converted into the data format to be integrated with the OMS (interruption management system) system, if available.
- OMS interruption management system
- the report includes information such as; daily, monthly and weekly interruption and Under Voltage headings as well as address, interruption class, interruption time, start time, end time, repetition frequency.
- A-1 When the rate of the network is kept by looking at the daily total number of interruptions, the duration and recurrent interruptions, Under Voltage information is also removed in a similar format and the places where problems may possibly occur are proactively highlighted. Two failure categories are defined in this part of the report. If the detected failure is a transformer failure it is defined as A-1 and if it is a branch failure, it is defined as A-2.
- Daily reports are followed by weekly and monthly reports.
- the main approach here is to prepare a weekly total interruption and Under Voltage report to identify repetitive and possibly larger failure locations. For this reason, failure points repeated 3 or more days a week are included in the weekly report, and failures repeated for 2 weeks or more are included in the monthly report.
- the basic operation of the invention is as follows: - Receiving base station no., Coordinate information, subscriber no., Counter no. and Mains / Under Voltage alarms information (data 1) in one format for each base station from GSM operators, - Transferring the given data (data1) to the server, - By using the relevant subscriber number and counter number information for the base stations taken from EDA ⁇ , information (data2),to which transformer they are determined in that EDA ⁇ region, is obtained, - Consolidating the software capability data1 and data2 in the server, - Creating polygons for each transformer zone, - Starting to process incoming alarms, - Defining the failures, - Displaying the failure on map and / or related EDA ⁇ GIS (Geographic Information System) - Addressing the failure to the EDA ⁇ failure repair crew and opening a trouble ticket (error report) - Logging and recording instantly processed and sent data on the server, - Reporting at desired time intervals, - Producing recommendations according to reports and desired scenario through logged data.
Abstract
The invention shares the alarms generated by failures or interruptions due to the infrastructure of the electricity distribution network of the GSM network with the electric network distributors at an appropriate interface. It increases electrical failure sampling emission points. According to the present state it is a method and system of monitoring the LV (Low Voltage) electricity infrastructure that uses GSM communication technology and taking precautionary measures which aims to reach a more stable and high efficiency electricity infrastructure.
Description
The invention shares the alarms generated by
failures or interruptions due to the infrastructure of the
electricity distribution network of the GSM network with the
electric network distributors at an appropriate interface.
It increases electrical failure sampling emission points.
According to the present state it is a method and system of
monitoring the LV (Low Voltage) electricity infrastructure
that uses GSM communication technology and taking
precautionary measures which aims to reach a more stable and
high efficiency electricity infrastructure.
In the currently used methods and systems,
electrical network distributors are able to determine
faults, which occur during use, only by customer / user
feedback. In this case, when the malfunction feedback of
customers /users is delayed, the process of resolving the
fault or problem is also delayed. At the same time, the
malfunction feedback of customers /users does not provide
clear location information about where exactly the fault occurs.
In the currently used GSM technology, each base
station has its own electricity meter, where it gets its
mains energy, and therefore these meters have subscriptions.
By using the subscriber no. and counter no., it is crucial
for the electricity network providers, to show which
transferee service this counter receives. Therefore, the
information that the subscriber no. and counter no. of each
base station addresses a traffix of EDAŞ (electricity
distribution companies) should be known at the beginning.
Each GSM base station is monitored 24/7 by GSM
operators who own base stations. These monitors are the
identification and monitoring of different types of alarms
on each base station. These alarms are constantly monitored
by the employees of the operators' network control centres.
When any alarm occurs in a base station, GSM operators open
a Work Order (WO) to their own crew to solve the problem
based on this alarm.
There are two types of alarms that are important
to our invention:
- Mains Alarm (If there is an interruption of the mains power, the generated alarm will indicate that the mains power is off at the moment)
- Under Voltage Alarm (This alarm type includes drops in the mains voltage, current values and phase measurement values).
- Mains Alarm (If there is an interruption of the mains power, the generated alarm will indicate that the mains power is off at the moment)
- Under Voltage Alarm (This alarm type includes drops in the mains voltage, current values and phase measurement values).
For each base station, a base station no.,
coordinate information, a subscriber no., a counter no., and
Mains / Under Voltage alarm, which are taken from the GSM
operator, are received as one format and transmitted to the
server of the invention. By using the relevant subscriber
no. and counter no. of these base stations, it is
consolidated to which transformer in the EDAŞ area they are
determined. At that very moment the software of the
invention works for this consolidation process. It then
creates polygons for each transformer zone. That is, within
the scope of the invention, it is possible to define more
than one signal and emission point in a transformer zone.
As a result, the platform defines more than one
signal that arrives at a transformer zone as the service
area of that transformer zone.
Incoming alarms start to be processed and if in a
transformer zone, for example service is received from 10
points and an energy cut alarm is received from all of these
10 points, the system identifies it as a transformer failure
and displays it in red on the map and/or EDAŞ's GIS
(Geographic Information System) to address that the problem
is on the transformer and opens a trouble ticket (error
reporting) for the repair crew.
Within the scope of this invention, it is planned
to increase the monitoring, control and availability of
electricity distribution networks by covering the
information and requirements of two major engineering fields
(Electronic Engineering and Electrical Engineering).These
benefits include reducing of operator availability and
back-up investments, a more stable energy network and
management due to increasing availability by EDAŞs, faster
failure resolution and customer satisfaction, and replying
more positively to the regulatory agency's expectations and
KPIs, and when evaluated on the basis of users, preventing
victimization that may be experienced due to energy cuts.
Data 1(For each base station base station no.,
coordinate information, subscriber no., counter no. and
Mains / Under Voltage alarm information are taken from GSM operators,)
Data 2 (Transformer definition information
received from EDAŞ by using subscriber number and counter no
information of the base station )
For each base station, a base station no.,
coordinate information, a subscriber no., a counter no. and
Mains / Under Voltage alarms (data1), taken from the GSM
operator, are received in a format and transmitted to the
server of the invention. By using the relevant subscriber
no. and counter no. information for these base stations, the
information (data 2) is consolidated to which transformer in
the EDAŞ area they are determined, and at that very moment
the software of the invention works for this consolidation
process. It then creates polygons for each transformer zone.
That is, within the scope of the invention, it is possible
to define more than one signal and emission point in a
transformer zone.
Incoming alarms start to be processed and if in a
transformer zone, for example service is received from 10
points and an energy cut alarm is received from all of these
10 points, the system identifies it as a transformer failure
and displays it in red on the map and/or EDAŞ's GIS
(Geographic Information System) to address that the problem
is on the transformer and opens a trouble ticket (error
reporting) for the repair crew.
A red alarm sign on the map clearly indicates that
there is a transformer failure in the transformer.
Therefore, there is no need to search for failures in an
area from one building to another. It directs the field
teams to solve the failure at the transformer. In this way,
it is ensured that both the field teams save time and the
defects are detected in a much shorter time. Thus,
eliminating failures in a shorter time contributes to the
increase in income due to the increase in availability.
If service is received from 10 base stations and
the energy cut alarm is not received from all of these 10
base stations, the system interprets this as a branch/ an
extension failure in the transformer service area and not as
a transformer failure and marks the power cut points on the
map with yellow alarm marks and clearly indicates where the
failure points are. At this point, the following explanation
would be clearer. Suppose that there are 4 consecutive
samples on a branch / an extension. If there is energy in
the first three of these 4 samples and no energy in the 4th,
it is obvious that the problem is at a point between sample
3 and sample 4.For this reason, by exploring the field
between these two points, the repair crew is able to find
the failure point and interfere more quickly in a very short
time. All of the above mentioned advantages also apply to
this example.
In the map display, the red alarm sign is
displayed as a transformer failure and the yellow alarm sign
is displayed as a branch / an extension failure, and if
desired, sample points can also be displayed on the map. It
is also possible to display sampling (emission) points on
the map to indicate where the point data is received. In
order to make all these data more meaningful for the
administrators, the data is processed instantaneously on the
dashboard and output is obtained by running the program.
Data flow and operation in the system are as
follows:
Mains information is received from a GSM operator every 486ms, under voltage and other energy information (mains current, phase, voltage) are received every 5 minutes. Acquired information comes to the server of the invention and is evaluated in two stages after consolidation and data processing.
1- Instant display on the map
2- Big data processing
Mains information is received from a GSM operator every 486ms, under voltage and other energy information (mains current, phase, voltage) are received every 5 minutes. Acquired information comes to the server of the invention and is evaluated in two stages after consolidation and data processing.
1- Instant display on the map
2- Big data processing
Instant display on the map and trouble
ticket-clear operation:
Instant display on the map is realized in two ways. This is shaped by the future demands of EDAŞ. According to this, either User Definition (user and access identification) is made over the web, and web access and dashboard access are provided to the related EDAŞ by giving an IP, or it will be displayed over SCADA (Remote Control and Observer System)of EDAŞ and its integrated GIS systems. The SCADA system, which is the basis for this display, is integrated into this system. At this point, the SCADA system of the vendor, to which it belongs, will be converted into the data format to be integrated with the OMS (interruption management system) system, if available.
Instant display on the map is realized in two ways. This is shaped by the future demands of EDAŞ. According to this, either User Definition (user and access identification) is made over the web, and web access and dashboard access are provided to the related EDAŞ by giving an IP, or it will be displayed over SCADA (Remote Control and Observer System)of EDAŞ and its integrated GIS systems. The SCADA system, which is the basis for this display, is integrated into this system. At this point, the SCADA system of the vendor, to which it belongs, will be converted into the data format to be integrated with the OMS (interruption management system) system, if available.
Opening the Map display and Trouble ticket through
the web in Phase 2 of the invention will be made available
to the use of EDAŞ repair crew with an application. Thus,
trouble tickets and clear (failure elimination) information,
can be transmitted to the final user as a notification
through the application.
Big Data Processing;
In this process, the data that is processed and sent instantaneously is logged and recorded on the server. After this, reports called the evening Z report start to recur.
In this process, the data that is processed and sent instantaneously is logged and recorded on the server. After this, reports called the evening Z report start to recur.
Accordingly;
Daily Z Report – Interruption
Daily Z Report - Under Voltage
Weekly Report – Interruption
Weekly Report – Under Voltage
Monthly Report – Interruption
Monthly Report - Under Voltage
Daily Z Report – Interruption
Daily Z Report - Under Voltage
Weekly Report – Interruption
Weekly Report – Under Voltage
Monthly Report – Interruption
Monthly Report - Under Voltage
The report includes information such as; daily,
monthly and weekly interruption and Under Voltage headings
as well as address, interruption class, interruption time,
start time, end time, repetition frequency.
When the rate of the network is kept by looking at
the daily total number of interruptions, the duration and
recurrent interruptions, Under Voltage information is also
removed in a similar format and the places where problems
may possibly occur are proactively highlighted. Two failure
categories are defined in this part of the report. If the
detected failure is a transformer failure it is defined as
A-1 and if it is a branch failure, it is defined as A-2.
Daily reports are followed by weekly and monthly
reports. The main approach here is to prepare a weekly total
interruption and Under Voltage report to identify repetitive
and possibly larger failure locations. For this reason,
failure points repeated 3 or more days a week are included
in the weekly report, and failures repeated for 2 weeks or
more are included in the monthly report.
In addition, reports based on the logged data and
recommendations according to the desired scenario are produced.
Default scenarios:
1- Producing detailed analysis requests for daily repetitive A-1 class failures
2- Proactive load control, balancing and possible failure scenarios for daily repetitive A-2 class faults
3- Screening of daily recurring UV points and creating a failure scenario
4- Suggestions for avoiding failures by combining similar solution scenarios with field solution notes processed after failure clear
5- All the first 3 specifications will be repeated in weekly and monthly reports and «weekly» and «monthly» recommendation reports will be prepared
6- Creating quarterly benchmarked recommendation reports for investment planning, load distribution and failure management
7- Reporting of breakdown-cost analyses if fault solution costs can be processed
1- Producing detailed analysis requests for daily repetitive A-1 class failures
2- Proactive load control, balancing and possible failure scenarios for daily repetitive A-2 class faults
3- Screening of daily recurring UV points and creating a failure scenario
4- Suggestions for avoiding failures by combining similar solution scenarios with field solution notes processed after failure clear
5- All the first 3 specifications will be repeated in weekly and monthly reports and «weekly» and «monthly» recommendation reports will be prepared
6- Creating quarterly benchmarked recommendation reports for investment planning, load distribution and failure management
7- Reporting of breakdown-cost analyses if fault solution costs can be processed
The basic operation of the invention is as
follows:
- Receiving base station no., Coordinate information, subscriber no., Counter no. and Mains / Under Voltage alarms information (data 1) in one format for each base station from GSM operators,
- Transferring the given data (data1) to the server,
- By using the relevant subscriber number and counter number information for the base stations taken from EDAŞ, information (data2),to which transformer they are determined in that EDAŞ region, is obtained,
- Consolidating the software capability data1 and data2 in the server,
- Creating polygons for each transformer zone,
- Starting to process incoming alarms,
- Defining the failures,
- Displaying the failure on map and / or related EDAŞ GIS (Geographic Information System)
- Addressing the failure to the EDAŞ failure repair crew and opening a trouble ticket (error report)
- Logging and recording instantly processed and sent data on the server,
- Reporting at desired time intervals,
- Producing recommendations according to reports and desired scenario through logged data.
- Receiving base station no., Coordinate information, subscriber no., Counter no. and Mains / Under Voltage alarms information (data 1) in one format for each base station from GSM operators,
- Transferring the given data (data1) to the server,
- By using the relevant subscriber number and counter number information for the base stations taken from EDAŞ, information (data2),to which transformer they are determined in that EDAŞ region, is obtained,
- Consolidating the software capability data1 and data2 in the server,
- Creating polygons for each transformer zone,
- Starting to process incoming alarms,
- Defining the failures,
- Displaying the failure on map and / or related EDAŞ GIS (Geographic Information System)
- Addressing the failure to the EDAŞ failure repair crew and opening a trouble ticket (error report)
- Logging and recording instantly processed and sent data on the server,
- Reporting at desired time intervals,
- Producing recommendations according to reports and desired scenario through logged data.
Claims (8)
- The invention is the method and system of monitoring the LV (Low Voltage) electricity infrastructure using GSM communication technology and taking precautionary measures whose features are as follows;
- receiving base station no., coordinate information, subscriber no., counter no. and Mains / Under Voltage alarms information (data 1) in one format for each base station from GSM operators,
- transferring the aforementioned data (data1) to the server,
- by using the relevant subscriber no. and counter no. information for the base stations taken from EDAŞ (electricity distribution companies), information (data2), to which transformer they are determined in that EDAŞ region, is obtained,
- consolidating the software capability data1 and data2 in the server,
- creating polygons for each transformer zone,
- beginning to process the incoming alarms,
- defining the error,
- displaying the error on a map and/or on a related GIS (Geographic Information System) of EDAŞ,
- addressing the error to EDAŞ fault repair crew and opening a trouble ticket (reporting error),
- keeping records of instantly processed and sent data by logging on the server,
- reporting at desired time intervals,
- producing recommendations according to reports and desired scenario through logged data. - It is the invention in Claim 1 which is the method and system of monitoring the LV (Low Voltage) electricity infrastructure using GSM communication technology and taking precautionary measures and whose feature is to receive Mains alarm (alarm that is generated if there is an interruption in the mains energy on the base station) from GSM operators every 486ms, to receive Under Voltage (alarm that is generated due to drops in the mains voltage, on the base station,) and other energy data (mains current, phase, voltage) every 5 minutes.
- It is the invention in Claim 1 which is the method and system of monitoring the LV (Low Voltage) electricity infrastructure using GSM communication technology and taking precautionary measures and whose feature is to provide web access and dashboard access via IP, which is given to the relevant EDAŞ by making Server A User Definition (user and access identification) over the web.
- It is the invention in Claim 1 which is the method and system of monitoring the LV (Low Voltage) electricity infrastructure using GSM communication technology and taking precautionary measures and whose feature is to display the SCADA (Remote Control and Observation System) of EDAŞ on its integrated GIS systems.
- It is the invention in Claim 1 which is the method and system of monitoring the LV (Low Voltage) electricity infrastructure using GSM communication technology and taking precautionary measures and whose feature is to open the map display and trouble ticket to the use of EDAŞ repair crew and to transmit the clear (failure elimination) notification after the elimination of the failure to the final user through an application via the web.
- It is the invention in Claim 1 which is the method and system of monitoring the LV (Low Voltage) electricity infrastructure using GSM communication technology and taking precautionary measures and whose feature is that the report element is daily, monthly and weekly and includes data such as, interruption and Under Voltage headings, address, interruption category, downtime, start time, end time, recurrence interval.
- It is the invention in Claim 1 which is the method and system of monitoring the LV (Low Voltage) electricity infrastructure using GSM communication technology and taking precautionary measures and whose feature is that if the software element receives a Mains alarm (power cut) from all of the base stations in a transformer zone, the invention will identify it as a transformer error and indicate it by a red mark on the map and / or the EDAŞ's GIS (Geographical Information System) which addresses the problem to the repair crew and opens a trouble ticket (error report).
- It is the invention in Claim 1 which is the method and system of monitoring the LV (Low Voltage) electricity infrastructure using GSM communication technology and taking precautionary measures and whose feature is that if the software does not receive any alarm from none of the base stations in a transformer zone, the system interprets it not as a transformer failure, but as a branch / an extension failure in the transformer service zone and energy cut points on the map are marked yellow which clearly displays these points to the repair crew.
Applications Claiming Priority (2)
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TR2016/03971A TR201603971A2 (en) | 2016-03-28 | 2016-03-28 | Monitoring of LV (Low Voltage) Electrical Infrastructure by Using GSM Communication Technology and Preventive Measures Method and System |
TR2016/03971 | 2016-03-28 |
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CN114513765A (en) * | 2022-04-18 | 2022-05-17 | 江西金达莱环保股份有限公司 | Data monitoring method, system, electronic device and storage medium |
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