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Network Transformation through Energy Efficiency Network Economics: Turkcell case study August 2018

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Page 1: Network Transformation through Energy Efficiency...Case Study – Turkcell: Network Transformation through Energy Efficiency 5 About Turkcell Turkcell is a digital operator headquartered

Network Transformation through Energy Efficiency Network Economics: Turkcell case study

August 2018

Page 2: Network Transformation through Energy Efficiency...Case Study – Turkcell: Network Transformation through Energy Efficiency 5 About Turkcell Turkcell is a digital operator headquartered

GSM Association Confidential – Full members Case Study – Turkcell: Network Transformation through Energy Efficiency

2

Table of Contents Network Transformation through Energy Efficiency ...................................................... 1

Network Economics: Turkcell case study ....................................................................... 1

Executive Summary ........................................................................................................... 4

About Turkcell .................................................................................................................... 5

Introduction ........................................................................................................................ 5

Intelligent infrastructure........................................................................................................ 6

Bespoke solutions based on requirements .......................................................................... 6

Intelligent IP-based Power System Upgrade ....................................................................... 7

Acclimatisation control modules ........................................................................................... 8

Generator control cards ....................................................................................................... 8

Management system software deployment ................................................................... 10

Economic effects of remote management ..................................................................... 10

CAPEX ............................................................................................................................... 10

Rectifier capacity dimensioning ................................................................................................. 10

Removing excess power system capacity ................................................................................. 11

Battery dimensioning strategy ................................................................................................... 11

OPEX ................................................................................................................................. 11

Energy Efficiency Features of Radio Equipment ....................................................................... 12

Modernization ........................................................................................................................... 13

Module efficiency increase ........................................................................................................ 14

Rectifier power saving features ................................................................................................. 15

Converter removals ................................................................................................................... 16

Invoice controls ......................................................................................................................... 17

Generator start-up algorithm ..................................................................................................... 17

Increasing site temperature ....................................................................................................... 18

Conclusion ......................................................................................................................... 19

Appendix 1: Turkcell’s Infrastructure Management system capabilities .................... 19

Reporting capabilities......................................................................................................... 19

Basic data log for power systems .............................................................................................. 19

Power system capacity utilization .............................................................................................. 20

Rectifier capacity reconfiguration report .................................................................................... 21

Battery temperature report ........................................................................................................ 22

Temperature and humidity report .............................................................................................. 22

Automated Functions ......................................................................................................... 23

Site profiles and parameter sets ................................................................................................ 23

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Remote battery tests ................................................................................................................. 24

Real-time Monitoring for Operation .................................................................................... 25

Appendix 2: Additional requirements from the SNMP upgrade .................................. 26

Appendix 3: Additional remote site requirements ........................................................ 27

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Executive Summary As part of the Future Networks Programme, Network Economics work stream, a series of case

studies have been developed, exploring areas where Operators can potentially reduce their

Operational Expenditure (OpEx) and Capital Expenditure (CapEX). This case study focuses on both

the challenges and optimization delivered by Turkcell in their network transformation projects.

The case study centres around 3 key innovations: Direct Current (DC) power systems,

acclimatisation solutions and generators. These requirements were focused on as the most

important parts of site infrastructure for holistic infrastructure management. Intelligent infrastructure

has been enabled through the transformation of legacy equipment with cost-effective solutions and

sensors developed in-house by Turkcell. Investment and deployment of hardware have been done

based on actual requirements to provide remote management capabilities.

Following site deployments, tailor-made and future-proof software platform solutions were created

with local infrastructure management partners. The following capabilities making remote

infrastructure monitoring and management possible have been identified and produced:

Information about site power infrastructure and environmental conditions

Automatic corrective actions by the management system to increase energy and operational

efficiency

Reports about infrastructure power capacity utilization, temperature distribution and battery

performance.

Using the information gathered and reports compiled by infrastructure management platforms,

investment decisions became more informed, precise temperature management was achieved, and

power system and battery dimensioning strategies were created. Excess hardware that was installed

on sites was removed and re-utilized, technical requirements for new purchases were reshaped and

generator fuel consumption was optimized.

As networks evolve through 4.5G to 5G and continue to become more complex, some industry

forecasts are predicting a 2 to3-fold increase in energy consumption. It is therefore critical that

powering the networks of the future remains economically viable.

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About Turkcell Turkcell is a digital operator headquartered in Turkey, serving its customers with its unique portfolio

of digital services along with voice, messaging, data and IPTV services on its mobile and fixed

networks. Turkcell Group companies operate in 8 countries – Turkey, Ukraine, Belarus, Northern

Cyprus, Germany, Azerbaijan, Kazakhstan, and Moldova. Turkcell launched LTE services in its

home country on April 1st, 2016, employing LTE-Advanced and 3 carrier aggregation technologies

in 81 cities. In 2G and 3G, Turkcell’s population coverage in Turkey is at 99.59% and 97.98%,

respectively, as of June 2018. Turkcell offers up to 10 Gbps fibre internet speed with its fibre to the

home (FTTH) services. Turkcell Group reported TRY5.1 billion revenue in Q218 with total assets of

TRY41.0 billion as of June 30, 2018. It has been listed on the NYSE and the BIST since July 2000

and is the only NYSE-listed company in Turkey.

Read more at www.turkcell.com.tr

Introduction Mobile Network Operators target to offer 99.999% network availability to their subscribers so that

they can enjoy a high quality, and uninterrupted service. As Figure 1 shows, achieving this objective

requires the support of the underlying layers and therefore it requires the ability to manage and

coordinate the network elements.

Figure 1: Hierarchical view of high availability network Figure 2: Breakdown of main cost lines for a site

As a highly available network may prove expensive, it is vital for operators to adopt energy efficiency

solutions and ensure that the network can be built and managed in the most cost-efficient manner

especially at the infrastructure layer that attracts a large proportion of the operator’s costs (see Figure

2).

This case study focuses on both the challenges faced and the optimisation delivered by Turkcell in

their network transformation projects.

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Intelligent infrastructure

While typically telecommunications core networks enjoy the benefits of having well-established

management systems (including remote management systems), the critical elements for site

infrastructure such as power systems, batteries, air conditioners, free cooling and generators (gen-

sets) often do not come with holistic, well-developed management systems.

Deploying remote monitoring and management functions for the main site infrastructure elements

allow operators to identify CAPEX and OPEX reduction opportunities and develop energy efficiency

strategies. We refer to this new breed of infrastructure as “intelligent infrastructure”.

Bespoke solutions based on requirements

In Turkcell’s case, infrastructure equipment either lacked remote connectivity or had limited support

for remote management, with no well-established management system that supported all of the

requisite infrastructure equipment.

In conventional management system deployments, an intelligent site controller connects to various

site infrastructure equipment using standard communication protocols such as RS232, RS485, and

CANBUS. A site controller is required regardless of specific site features (infrastructure equipment

combinations, number of power systems presence of stationary gen-set, and so on).

It is clear that this type of deployment is not cost-effective for remote infrastructure management as

it requires significant investment for the intelligent site controller, complex installation work per site

and may often result in overprovisioning of capabilities.

Figure 1a. Conventional Site Infrastructure Management Figure 3b. IP Enabled Infrastructure Devices

Turkcell designed its own solution based on their specific equipment types and site requirements.

Following a detailed analysis of power systems, air conditioners and gen-sets and other equipment

Turkcell selected an IP-based communication interface in order to add remote management

capabilities and to connect to separate infrastructure equipment.

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Intelligent IP-based Power System Upgrade

For Turkcell’s power systems, the only available communication interfaces were RS232 or USB ports,

which required the installation of special PC software or simple dry contact alarms.

In order to add the remote management capability, SNMP & IP remote access cards were installed

to the power system controllers which were manufactured by original power system manufacturer.

Figure 4a. SNMP & IP remote cards in the existing casing to enable upgraded functionality

Figure 4b. the upgraded case with SNMP remote card and USB connectivity.

Since 2010, Turkcell has updated its Power System Technical Requirements Documentation and

SNMP & IP remote access functionality for all power system controllers was made mandatory in all

new purchases.

Turkcell upgraded their existing power infrastructure for around 50% of its base station sites with

SNMP&IP remote access cards which were deployed over a 4-year period. Hardware and

installation costs vary depending on operator conditions, can be approximated between $250 USD

– $350 USD. However, the initial firmware running on SNMP&IP remote access cards provided

limited functionality, only supporting a simple web interface for system monitoring and SNMP alarm

signalling.

Turkcell’s infrastructure management requirements were more sophisticated and required additional

standardised functionality from the manufacturers to be developed. This included a significant

upgrade in connectivity metrics, however, limited remote management functionality (see appendix 2

for initial requirements).

Figure 10 Improved Functionality with FW Update

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Acclimatisation control modules

For air conditioner systems, free cooling solutions that utilised an air conditioner and a fan unit

(depending on temperatures) were already deployed for energy efficiency. But remote management

functions for algorithm changes and measurement of temperatures were not available, meaning that

the system worked based on an embedded algorithm which was set during production.

In order to meet Turkcell’s requirements and enable the full remote management capability, new

controllers with IP remote access functions were designed and deployed by working closely with a

local manufacturer. Hardware and installation costs vary depending on operator conditions, can be

approximated between $100 USD – $200 USD. (see Appendix 3 for additional remote site upgrade

requirements).

Figure 5. Upgraded remote management capability developed locally by Turkcell and third party.

In some instances, a more basic solution was required to measure internal site temperature alone.

Simple and cost-effective IP based thermostats were developed and deployed in conjunction with

local manufacturers. Hardware and installation costs can be approximated between $50 USD – $100

USD.

Turkcell deployed free cooling control module with remote management capabilities to around 20%

of its base station sites and thermostat units with remote management capabilities to around 10% of

its base station sites.

Generator control cards

Turkcell also made significant improvements to gen-set equipment by upgrading control cards. With

this investment, functions such as manual start-stop, test mode, automatic mode, changing of start-

stop conditions and measurements of AC phase voltages, gen-set AC output phase voltages, fuel

level, oil level, oil temperature, oil pressure, engine speed, frequency, load currents, and runtime

were made possible to manage remotely.

Control cards had already been deployed for stationary gen-sets which enabled gen-set start and

stop functions. However, because half of the gen-sets in the network only supported point-to-point

connection via sim-cards, the system was unable to connect or provide management for more than

one gen-set simultaneously and therefore was not cost-effective due to the high communication

costs when using GPRS.

In 2013, a local brand gen-set control card was selected to provide remote management functions

for algorithm changes, measurement of gen-set values and manual start-stop function. This card

was supported by Ethernet or GPRS interface and could be utilised for the whole network. All new

generators are being purchased with this control card as standard.

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For older gen-set control cards that had been purchased previously, remote management

capabilities were installed via an interconnection module to meet Turkcell’s requirements. Thus, all

the stationary generators in the network are now controlled remotely.

Hardware and installation costs vary depending on operator conditions, can be approximated

between $250 USD – $350 USD.

Around 10% of Turkcell base station sites have stationary generators and all these generators

gained remote management capability over the course of a 2-year period.

Figure 6. Generator control module connection interfaces, supporting Ethernet and GPRS Connection Options

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Management system software deployment For many infrastructure equipment deployments, remote management has two main problems.

Firstly, as the number of devices to monitor increases, manual operations become impractical. To

overcome this issue it is important to develop an interface compatible with all devices.

Secondly, the remote management system needs to be sufficiently flexible to support multiple

variants of equipment produced by different manufacturers. For example in the Turkcell case, there

were three different rectifier brands, two different free cooling brands, three different generator

control modules and so on. In order to overcome this problem, new management software was

designed and implemented for each infrastructure product. This was written by local companies in

Turkey resulting in lower cost and tailor-made solutions to be developed.

Economic effects of remote management

CAPEX

Rectifier capacity dimensioning

Rectifier capacity utilization reports highlight where standard power system capacity is over-

dimensioned compared to actual needs.

In the graph below the standard power system capacity was 12kW for new purchases. After

evaluating actual loads and power system utilisation, power system capacity was re-dimensioned to

9kW by reducing the number of modules from four to three. This resulted in around 20% capex

saving for each power system investment.

Figure 7. Capacity utilization distribution

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Removing excess power system capacity

Identifying where excess power exists allows for the redeployment of power capacity to sites

where it is needed more. The rectifier capacity utilization report provides information about the

average load per power system and advises how many modules are needed. If the power system

has excess capacity, modules are able to be removed.

By collecting 7% of existing rectifier modules and re-utilising them at new sites rather than

investing in new modules, Turkcell was able to identify a significant CAPEX saving.

Figure 8. Site-based rectifier module removal advice report

Battery dimensioning strategy

By gathering information about DC power consumption and grid cut-off statistics per site via remote

management systems, a precise method to dimension battery backup time and a number of batteries

per site can be developed. Instead of standard battery backup duration targets, backup time

requirements based on actual availability targets and grid cut-off statistics for each site are calculated.

The number of battery sets to achieve necessary backup time for a specific site can be calculated

by measuring specific DC power consumption per site based on the following metrics:

Total DC consumption x Necessary backup duration -> Number of battery sets

By applying this battery dimensioning strategy for the whole network, the number of batteries

necessary to achieve availability targets can be calculated. The automated remote battery test can

indicate necessary battery replacement, as well as detect potential battery faults that can lead to

degraded backup duration.

As an example, after completing battery dimensioning on all sites, the actual number of batteries in

the network was reduced by 20%.

OPEX

OPEX is a critical factor in determining financial success for an operator and therefore much

importance is placed on reducing costs, in particular, energy costs.

According to Capgemini’s report “Operational Cost Strategies for Mobile Operators in Europe”

released in 2009, energy costs are more than 20% of all OPEX costs for a Telecom operator.

With the help of more efficient management systems, energy OPEX can be reduced in a number of

ways.

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Energy Efficiency Features of Radio Equipment

The majority of overall energy consumption in a base station site comes from Telecom equipment

generating and amplifying radio signals. In order to reduce the power consumption of this equipment,

vendors offer many different solutions and features. Some of the energy efficiency features of radio

equipment are listed below:

Multi-Carrier Intelligent Voltage Regulation

Dynamic TRX Working Voltage Adjustment

Multi-Carrier Switch off Based on Traffic Load

Power Optimization in Broadcast Frequency

Multi-Carrier Switch off Based on Quality of Service

Mains Triggered TRX Shutdown

However, implementing all of these features can be expensive for the operator and it is important to

measure the actual benefits of the features to decide whether to invest or not.

Collection of load data from the majority of rectifiers across the Turkcell network has greatly

simplified the process of assessing the impacts of an action (or a power saving feature). The graphs

below show the effects of two different power saving features. It is immediately obvious that while

the first feature generated a significant reduction in overall site consumption, the effects of the

second feature was negligible.

By activating the most suitable features for the Turkcell network configuration, it was possible to

produce annual savings in the order of 20M kWh, significantly reducing the network OPEX.

Figure 10. Energy saving measurement of sample radio network feature

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Figure 11. Energy saving measurement of sample radio network feature

Modernization

Modernisation of the radio equipment, the main responsible for electricity consumption in mobile

networks has produced significant savings. On average, Turkcell observed a reduction of 20% in

energy consumption keeping the same radio capacity just through a programme of base station

equipment modernization.

Figure 12. Modernization effect on power consumption

Most of the base station cabinet’s power consumption is drawn by the power amplifier. Efficiency

can be increased with different amplifier types or signal processing techniques. Maximum efficiency

increases can be achieved by installing newer radio equipment and removing legacy cabinets from

the network.

It should be noted that since modernization requires a major CAPEX outlay in terms of equipment

and additional installation cost, modernization alone will not achieve significant gains in energy

efficiency. An operator should also consider the additional motivation of better signal quality,

increased coverage, and capacity for a modernization project.

Average %20 energy saving

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Module efficiency increase

All power modules in rectifiers have an efficiency curve similar to the graph below. The efficiency of

the rectifier module is highly dependent on the load. At low loads per module, the rectifier efficiency

drops, therefore more energy is dissipated to heat. In order to reduce the energy consumption of the

site, the efficiency should be increased.

There are a number of ways to achieve this. One way is to use rectifier modules with higher

efficiencies. This achieved by moving from the blue efficiency line to green efficiency line as shown

in the graph. By switching to a more efficient module, losses on the rectifier modules could be

reduced.

Figure 13. Rectifier efficiency vs load

The efficiency of rectifier modules has increased from 92%-96% since the early part of the 21st

century. However as efficiency increases, so does the price. At present, rectifier investment is costly

and therefore it is not realistic to replace current rectifier modules with more efficient ones just to see

a reduction in OPEX.

Turkcell’s innovative solution was to make the current rectifier modules work with higher loads in

order to reduce losses. As can be seen in the above graph, when the load on the rectifier module

increases, so does the efficiency. Rectifier modules share the load equally, so when one or two

modules are removed from the rectifier cabinet, the remaining modules are required to generate

more current, thereby increasing their load.

In order to determine the rectifier units that could be removed, we used the capacity utilisation report.

The below graph shows the capacity utilisation of all rectifiers in the network when the rectifier

management system was initially launched. More than 50% of the rectifier modules were working at

less than 20% cent of their capacity.

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Figure 14. Rectifier capacity utilization distribution

Trials were conducted at a sample of base station sites and one of two rectifier modules were

removed depending on the load and battery capacity on the sites. The results can be seen below.

Figure 15 Module removal effect

On average, an energy saving of approximately 2.5% was measured across all sites. The overall

energy saving across the network varied depending on the module efficiencies used and how

capacity was utilised depending on the loads. In this case, around 7% of all rectifier modules in the

network were removed from rectifier cabinets, generating an OPEX energy saving of

approximately 3GWh annually.

Rectifier power saving features

As previously mentioned, to reduce losses on the rectifier modules, increases in the efficiency of the

rectifier module was necessary. Module reduction did achieve this outcome, however, it is necessary

to have some excess capacity in rectifier cabinets for two reasons;

1. To charge batteries after a grid failure. Batteries must be charged with suitable currents and

Telecom equipment at the site must be fed simultaneously.

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2. For redundancy. If one of the rectifier modules fails, the remaining ones can keep generating

the necessary current. Additionally, since all rectifier modules work with a different AC phase,

additional modules are required for AC phase redundancy.

When considering these constraints on removing excess rectifier modules, another way to increase

the efficiency of each module was required. Turkcell implemented energy efficient algorithms that

showed the rectifier control module monitoring the necessary current for the load and putting the

excess modules into standby mode. The logic behind this feature can be seen in the below visuals.

Rectifier modules work with load sharing, therefore when one of the rectifier modules is in standby

mode, other active modules generate more current and are able to work at a more efficient rate.

Using a rectifier management system, this feature can be activated remotely, thereby eliminating the

need for site visits.

When the power saving algorithm was activated on all rectifiers in the network, a more than 2%

decrease was measured in the overall site energy consumption, generating more than 30M kWh in

energy savings annually from the OPEX expenses of the network.

The below graphs show the change in the energy consumption of sites after the power saving

algorithm has been applied. The green box shows when the algorithm is activated. The red lines in

the graphs represent air conditioning energy consumptions. The blue lines represent the Telecom

equipment energy consumption and the yellow lines represent the overall consumption of the sites.

Figure 16. Energy saving measurement after activation of rectifier energy saving features

Converter removals

Further to the rectifier modules in a base station site, there are also converter units which convert

the -48VDC to +24VDC voltage level.

The purpose of converter units is mainly due to old Telecom cabinets requiring +24VDC voltage as

input. Most of these types of cabinets have been replaced over the years in Turkcell’s network,

however, some of the converter modules, required for feeding the equipment were not removed.

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The deployment of the rectifier management system made it possible to detect a number of base

station sites where redundant converters existed. These converter units consumed a small amount

of residual electricity and therefore it was decided to uninstall them from the network.

Excess converter modules were removed from all rectifiers in the network and this generated more

than 500,000 kWh energy savings annually.

Invoice controls

When considering the number of base stations in a network, it is important to control the energy

consumption bills for each site. Before deploying the rectifier management system, there was no

option to compare and contrast data from different base station sites or bills over a period of time.

With the rectifier management system, the DC load in every base station site can be measured

enabling the power consumption from the grid to be calculated accordingly. By adding the cooling

consumption, an estimated energy consumption can be compared against the energy bill. This data

enables payments to be verified, minimizing inaccurate payments.

Generator start-up algorithm

A majority of telecom operators use some sort of backup power in their network. Most of the time

backup power is covered by batteries, however, in addition, generators are used to increase the

backup time. Prior to deploying the remote management system, during a grid outage, generators

would start up within 15 minutes of the grid outage. The cost of starting the generator is considerably

higher compared to covering the backup need with batteries.

For reducing the generator working hours and decreasing fuel costs, the algorithm below was

designed. This algorithm monitors all AC phases, battery discharge status, battery voltage and

internal temperature. Combining all these parameters, the generator is only started when it is

absolutely necessary.

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Figure 17. Grid failure process flow

After all 3 AC phases are restored, the generator stops with a short delay.

Increasing site temperature

Acclimatisation energy consumption is one of the main components of overall base station energy

consumption. The amount of energy used for acclimatisation depends on many parameters,

including the technology of the air conditioner (AC) unit (whether it is an inverter or on-off type), the

set temperature of the AC, outdoor temperature and additional free cooling equipment.

The percentage of AC energy consumption from all site energy consumption changes depending

on the factors above. In some base station sites, ACs consume around 8 % of total energy yet in

other base station sites, AC energy consumption can be as high as 20 % of total energy

consumption. In order to reduce energy consumption in a base station site, free air cooling units

were deployed, (cool air from outside, brought inside with the help of a DC fan). The free air

cooling units have the functionality to activate AC units if the indoor temperature increases.

During trials of the free cooling remote management system, the average temperature of base

station sites was increased from 24°C to 30°C in all our base station sites. The result of this action

was an energy saving from air conditioner energy consumption of more than 10M kWh annually.

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However, one disadvantage of this temperature increase was the negative effect to the life

expectancy of batteries. There is a negative relationship between battery temperature and battery

life. The ideal working temperature for batteries is between 20°C and 25°C.

The negative effect on battery life can be combated by decreasing the base station average

temperature and cool the site without using the air conditioner unit, maintaining the indoor

temperature closer to suitable levels for batteries. This is practical when then the outdoor

temperature is cold enough to cool the base station site, ideally during winter periods. Additionally,

emergency cooling of free cooling units decreases the site temperature in cases of air conditioner

failure, preventing batteries from excess temperatures.

Every 1°C increase in site temperature results in a 3% decrease in the lifetime of the battery. Using

remote management for changing parameters, decreasing average site temperature in winter and

emergency cooling positively increased the battery lifetime by more than 5%.

Conclusion

The in-house development of infrastructure by Turkcell to improve the monitoring and remote

capabilities of base station equipment provides an easy method to improve site efficiency at relatively

low cost with clear OpEX benefits. This has been achieved without the purchase of new equipment

or on boarding of third-party vendors, though still requiring input and an additional benefit is that

these have been specifically designed with Turkcell’s requirements in mind.

Appendix 1: Turkcell’s Infrastructure Management system capabilities An efficient infrastructure management system must be able to provide users with summary

reporting information for decision making, support automated functions and take corrective actions.

Reporting capabilities

The infrastructure management systems created by Turkcell provides a variety of reports to support

decisions for CAPEX and OPEX reduction and energy efficiency.

Basic data log for power systems

By gathering periodical measurement data from power systems, site power infrastructure can be

examined in detail and the results of changes made for energy efficiency can also be calculated.

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Figure 18. Basic data log

Figure 19. Archive and Power consumption graph

Power system capacity utilization

DC power system capacity utilization directly affects energy efficiency and with low-utilization,

energy efficiency is reduced and OPEX costs increase and it is likely that the power system capacity

is over-dimensioned.

With the power system capacity utilization report, capacity utilization is calculated per site, per region

or for the whole network and power system capacity dimensioning can be done by evaluating results.

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Figure 20. Capacity utilization distribution

Rectifier capacity reconfiguration report

Rectifier capacity utilization relates to the efficiency of the load per rectifier module, and at low loads

per module (when part of the rectifier capacity is used) the rectifier efficiency is reduced and the

energy consumption of the site is increased.

The following rectifier module efficiency graph shows load-dependent efficiency change.

Figure 21. Rectifier efficiency versus load

In order to increase the capacity utilization of the rectifier module, it is necessary to reduce the

number of rectifier modules and to increase the load per module. The following report details the

average load per power system and advises how many modules are required. If the power system

has excess capacity, modules should be removed.

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Figure 22. Rectifier module number advisory report

In cases of insufficient power system capacity for redundancy purposes, module addition is advised.

Figure 23. Rectifier module advisory report

Battery temperature report

For optimal battery life and energy efficiency, the site internal temperature is an important parameter.

The below report shows information about temperature distribution for specified date range per site,

per region or for the whole network.

Figure 24. Battery temperature distribution

Temperature and humidity report

Utilising the free cooling management systems, each base station site’s indoor, outdoor

temperatures, and humidity levels are collected and measured as displayed in the graph below. In

base station sites where only a thermostat is installed only the indoor temperature can be monitored.

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Figure 25. Indoor/Outdoor Temperature and Humidity levels

Automated Functions

The Management System created by Turkcell has automated functions that take corrective actions

at the site infrastructure level for increased OPEX and CAPEX efficiency.

Site profiles and parameter sets

The rectifiers defined in the rectifier management system are controlled by various parameter sets

according to the site type, the rectifier brand/model, and the battery type connected to the rectifier.

New site profiles and or parameter sets can be added to the system, with power systems or sites

automatically assigned to different profiles according to the location or inventory criteria.

Figure 26. Parameter sets/translation

Parameters for power systems in the network can be easily managed, allowing energy-saving

features at power system level to be turned on network-wide.

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Figure 27. Network-wide parameter management

Remote battery tests

Network battery quality is a significant factor that impacts a network’s OPEX and CAPEX efficiency.

By monitoring network battery quality, early detection can reduce the disruptive effect of a single

faulty battery and therefore the corruption of the whole group can be prevented.

In a large network, it can be challenging to monitor network-wide battery quality and conditions.

Turkcell’s rectifier management system has automated battery test functionality that tests battery

capacity at each site without the need of user interaction. Tests are started by the central

management system and managed by a rectifier controller. DC output voltage can be lowered to

start battery discharge without power cut-off.

The test results are evaluated automatically and sites with degraded battery capacity are reported.

By evaluating battery test results, sites that require battery replacement can be detected and service

failures avoided.

Figure 28. Battery test decision regions

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Figure 29. Periodical Battery Test Results

Real-time Monitoring for Operation

Operational decisions rely on accuracy and precision in order to achieve an OPEX efficient network

and minimal service loss. With real-time monitoring remaining battery capacity can allow for the

prioritization of network operations during grid cut-offs.

Real-time battery voltage is reported on the dashboards for sites that experience grid power loss.

Figure 30. Real-time battery voltage monitoring

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Appendix 2: Additional requirements from the SNMP upgrade

An Ethernet interface that can provide TCP / IP connectivity on the power system controller.

A web interface for management via TCP / IP connection.

Communication support with SNMP protocol via TCP / IP. SNMP protocol MIB files for rectifiers

will be provided by the manufacturer.

Metrics via the SNMP protocol on the rectifier to include:

AC phase voltages, DC output voltage, DC output current (load current), remaining battery capacity,

battery depth of discharge, battery current battery temperature, ambient temperature, rectifier output

current (for each rectifier), rectifier utilization rate, rectifier status(Float, EQU, Battery discharge etc.)

Modifiable Parameters by accessing the rectifier with the SNMP protocol.

Field name, field location, system description, float charge voltage, EQU / Boost charging voltage,

charge current limit, battery capacity, rectifier control (each rectifier module can be turned on and off

remotely), periodic battery test parameters, manual battery test parameters, LVD on and off voltage

setting values, LVD control commands (each LVD can be turned on and off remotely), battery charge

temperature compensation parameters, DC output voltage low alarm threshold value

SNMP alarms generated in the rectifier controller for alarms related to the following rectifier system

including Rectifier alarms, LVD trip alarms, temperature alarms, sensor fault alarms, AC phase

interrupt alarms, AC phase voltage alarms, battery and load fuse alarms, battery test failure alarms,

rectifier overload alarms, DC output voltage high and low alarms, current limit overshoots

Rectifier controller should allow for the rectifier modules to be turned on and off programmatically,

depending on the load, using energy efficiency algorithms.

Rectifier controller will allow periodic and manual battery tests to be done remotely on the power

system. The systems will support the functions that will carry out the constant current load test.

Rectifier system should allow firmware updates via remote connection.

Rectifier system should allow IP address changes with a remote connection.

For air conditioner systems, free cooling solutions that utilised an air conditioner and a fan unit

depending on inside and outside temperatures were already deployed for energy efficiency. But

remote management functions for algorithm changes and measurement of temperatures were not

available. The system worked based on an embedded algorithm set at production.

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Appendix 3: Additional remote site requirements

Monitoring and management of features below were standardised;

Container inner temperature, outdoor temperature, internal humidity

Fan power consumption, air conditioner electricity consumption

Fan Type

Air conditioning working temperature, air conditioning stop temperature

Fan working temperature, fan stop temperature

Inside-outside temperature difference, maximum internal temperature, internal humidity

Air conditioning protection delay, emergency fan stopping temperature

FC deactivated outdoor temperature

Fan day speed, fan night speed

Heater working temperature, heater stop temperature, heating method

Night mode start time, night mode end time, night/day mode selection

Maximum fan speed at a critical temperature

Alarm set values, active/inactive information of alarms

High-temperature alarm, low-temperature alarm, high humidity alarm

Free cooling failure alarm, free cooling fan failure alarm, free cooling fan speed (rpm)

alarm, free cooling fan consumption alarm, filter dirty alarm

AC phase alarm (optional), DC battery voltage is high (optional), DC battery voltage is low

(optional)

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