Solar Photovoltaic (PV) Energy Apr2024.pdf

Transcript

SOLAR PHOTOVOLTAIC
(PV) ENERGY
15 APRIL 2024
 CONTENTS

1 Global Context of Solar PV Energy

2 Type of Solar Energy

3 Solar Cell Technologies

4 Application of Solar PV

5 Case Study on GCPV System

6 Advantages & Disadvantages of Solar PV Energy

7 Solar PV Scheme in Malaysia

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 TIMETABLE Jadual Waktu

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 OBJECTIVEs

Participants will be able to:

explain the basic knowledge on solar PV energy

explain the application of solar PV energy

describe the concept of grid-connected PV system

referring policy and regulation by Malaysian government correctly.

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 Global Context of
Solar PV Energy

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 National Energy Transition Roadmap (NETR)

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 National Energy Transition Roadmap (NETR)

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 National Energy Transition Roadmap (NETR)

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 National Energy Transition Roadmap (NETR)

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 MyRER

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 MyRER
MyRER strategic framework

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 MyRER
Summary of RE resource potential in Malaysia

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 MyRER

Malaysia aims to achieve a higher RE growth, from the
existing 23% or 8.45 GW RE in its power installed
capacity. Malaysia Renewable Energy Roadmap
(MyRER) projected to increase the share of RE to 31%
or 12.9 GW in 2025, and 40% or 18.0 GW in 2035.

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 MyRER
RE Capacity Mix to achieve the target in 2025

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 MyRER
RE Capacity Mix to achieve the target in 2035

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 World

Source: https://solargis.com/maps-and-gis-data/download/world

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 Malaysia

Source: https://solargis.com/maps-and-gis-data/download/malaysia

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 Environmental Benefits of Solar Energy

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 Type of Solar
Energy

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 What is Solar Energy?

Energy from the sun that is converted into thermal or electrical energy

Solar Heating Concentrating Solar Power Solar Photovoltaic (PV)
(CSP) / Solar Thermal

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 Solar Heating

“Solar heating is the
conversion of sunlight into
heat for water heating using
a solar thermal collector. A
sun-facing collector heats
a working fluid that passes into
a storage system for later use.”

Source:
https://en.wikipedia.org/wiki/Solar_water_heating; https://smartsolar.com.my/ & https://www.solartechnologymalaysia.com/solar-water-heater/

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 Concentrating Solar Power (CSP) / Solar Thermal

“Concentrating Solar Power
(CSP) technologies use
mirrors to concentrate
(focus) the sun's light energy
and convert it into heat to
create steam to drive a
turbine that generates
electrical power.”

Source:
http://helioscsp.com/global-solar-thermal-power-revolution-urges-for-concentrated-solar-power-innovations/ & http://solareis.anl.gov/guide/solar/csp/
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 Concentrating Solar Power (CSP) / Solar Thermal

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 Solar Photovoltaic (PV)

Grid-Connected PV Stand Alone / Off-Grid PV

is an electricity generating solar PV is an off-the-grid electricity system for
power system that is connected to locations that are not fitted with
the utility grid. an electricity distribution system

House, factory, rooftop etc. Island, rural etc.

Technologies: Tracking, LSS, Technologies: Hybrid
Floating, Batteries

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 Solar Cell
Technologies

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 Build & Layout

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 Type of Solar PV

Thin Film Monocrystalline

Hybrid Polycrystalline
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 How Solar PV Cell Produce Electricity?

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What Types of Solar Panels Are the Most Efficient?

Source: https://www.greenmatch.co.uk/blog/2014/11/how-efficient-are-solar-panels#what-types-of-solar-panels-are-most-efficient

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 Concept of Installation

Building Integrated
Photovoltaic (BIPV)

Retrofit

Free Standing

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 Manufacturer

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 Application of
Solar PV Energy

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 Activity

There are several applications in
solar PV technology. You are asked
to try to explain the applications.

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 1. GCPV w/o Storage

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 Basic Concept

A system that converts sunlight into electricity

The GCPV system requires a lively grid line to operate

Notes:
Grid voltage & frequency
230V, 50Hz (1-phase)
400V, 50Hz or 11kV, 50Hz (3-phase)

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 Configuration

DC AC AC

Solar PV Grid-Inverter PV Meter Grid

The GCPV system is a simple electrical system but requires
specialized skills to design and install it.

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 Schematic

MS 1837:2018 Installation of GCPV System (Second Edition)
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 Installation (4.14kWp GCPV System @ Penang)

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 Installation (6.69kWp GCPV System @ IREC TNB ILSAS Bangi)

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 Installation (803kWp GCPV System @ TNB ILSAS Bangi)

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 Yearly Saving

Year 2020 2021 2022 2023
Saving RM 2,049.12 RM 139,816.61 RM 194,957.44 RM 141,808.69

Accumulative Saving

RM 478,631.85

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 Method of Connection
Direct Feed – In

Power from the PV is connected directly to the grid line
An energy meter is installed to measure the amount of energy
generated by PV
Typically for industries that install large scale PV systems, the
connection is at 11kV grid voltage
Consumption
Meter
Distribution
Load
Board

230V,

PV
Array
= 50Hz

PV
Meter

Direct Feed - In

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 Method of Connection
Indirect Feed – In

PV power is transferred to the grid through the Distribution Board
(DB)

Indirect Feed - In

Consumption
Meter
Distribution
Load 230V,
Board
50Hz

PV
Array
=
PV
Meter

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 Interconnection Method


Direct-
Feed

Indirect-
Feed



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 Factors Influencing Output Power

Module Incompatibility

Hot spot

Impurities / Dust

Shading

Cable

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 Grid-Inverter
Basic Principal:

The function of the inverter is to convert DC Voltage released from
PV Module to AC Voltage that can be connected to the grid.

AC Voltage and frequency must correspond to the voltage and
frequency of the grid.

Synchronization is done automatically by the inverter before this
voltage is connected to the grid.

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 Function

MPP tracking

Recording of the operating data & signalling

Establishment of DC and AC protective devices

Grid monitoring/management

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 Type of Inverter

Central Inverter String Inverter Module Inverter

Used for PV Array Very wide use For use only one PV
power exceeding module
Used for PV Array
100kW power not more than Not economical for
large scale
Connected to grid 100kW
via 3 Phase system There are modules
Connected to grid equipped with this
via Phase 1 system type of inverter -
known as AC Module

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 Features

Heart of the GCPV system

The most sensitive component. Easily damaged by Surge Voltage.

Most of the inverter's efficiency exceeds 90% up to 98%.

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 Features
Synchronization & Anti-islanding:

Auto Synchronization: The inverter output voltage must be in sync
with the grid voltage before the Inverter is connected to the grid.
This process is automatic.

Anti-islanding: In the event of a grid failure, the Inverter will
automatically shut down. So there is no power supply provided by
the GCPV system to the grid.

The inverter detects instability of grid frequency, voltage,
temperature. In the event of exceptional circumstances or beyond
the permitted tolerance value, the inverter will isolate the GCPV
system from the grid itself.

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 Factors Influencing Output Power

Input Power. It depends on the size of the array installed.

Environmental weather. Although the power of the PV Array is
high, but if the weather is not as good as haze or overcast; then the
output power of the PV Array will also decrease.

Improper connection will result in loss of power.

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 Manufacturer

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 2. GCPV w Storage

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 Definition
Batteries store and produce energy as needed.

Capture surplus energy generated by your PV system to allow you
to store energy for use later in the day.

Provide power when electrical loads require more power than the
PV panels are generating.

Source: https://www.fuelcellstore.com/blog-section/battery-energy-storage-for-the-pv-system

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 Basic Operation

The PV system The PV system generates little
generates solar energy to no solar energy
The system will check to see if Energy is obtained from the
all of the energy generation battery system
can be used to power your After the battery is discharged,
household electricity can be obtained from
Any surplus energy will be the grid
used to charge the battery
If the battery is already
charged, excess energy will be
exported to the grid

Source: https://www.fuelcellstore.com/blog-section/battery-energy-storage-for-the-pv-system

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 Configuration

Source: https://files.sma.de/dl/31186/SBS37-60-DEN1751-V21web.pdf

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 Type of Battery
Two Most Common Types of Batteries for PV System Storage

Lithium-ion Batteries Lead-acid Batteries
Becoming more common in Used for off-grid storage
domestic grid-connected solar systems where additional
PV storage systems storage is required
More expensive Less expensive
Lighter and smaller Heavier and larger
Requires integrated controller to Requires good charging and
manage charging and discharging process to maintain
discharging battery health
More efficient Less efficient
Can discharge more stored Shorter expected lifetime
energy
Longer expected lifetime
Source: https://www.fuelcellstore.com/blog-section/battery-energy-storage-for-the-pv-system

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 Research Project
Solar PV
Community
Scale
25kW -
100kW

Commercial
& Industries

Generation Grid
Distribution
Residential
Bulk Aggregated Utility Scale
Storage Utility Scale 100kW -
>50MW 2 - 50MW 2MW

DES
Objectives of TNB’S BESS 1kW – 5kW

To perform peak shaving & power arbitrage
To provide frequency control
To provide power limit & ramping for PV systems
To provide islanding mode
To develop VPP

Source: Tenaga Nasional Berhad

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 Field Trial

Jelutong, Penang; 50kW 70kWh 400V Li-Ion
Operation: Peak Shaving Mode Johor Bahru, Johor; 50kW 156kWh 400V Li-Ion
Functionality: Reduction in the feeder / Operation: Peak Shaving Mode
transformer peak load Functionality: Reduction in the feeder /
transformer peak load

Bukit Rambai, Melaka; 280kW 170kWh 400V Li-Ion
Operation: Renewables Ramping / Volatge Regulation Mode
Functionality: Smoothing needed for swing mitigation

Source: Tenaga Nasional Berhad

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 3. Floating Solar

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 Definition
A system consists of PV panels and floater device, installed on a water
body and fixed by mooring and anchoring system

Source: TNB Research Sdn. Bhd.

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 Why Floating Solar?

Land area are
Reduce water
reserved for
evaporation
development

Increase in Water body surface
efficiency due to utilization, hydro
cooling effect dam etc.

Source: TNB Research Sdn. Bhd.

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 Floating Solar Project

Sungai Labu Water Coal Ash Pond, TNB
Treatment Plant Janamanjung

Capacity: 108 kWp Capacity: 105 kWp
Funded by MESTECC Funded by TNB
through AAIBE grant R&D Fund
Completed March 2017 Target Completion:
Nov 2019

Source: TNB Research Sdn. Bhd.

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 4. Stand-Alone System

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 Definition

Meaning – not connected to a national utility grid.

Designed to operate independent of the electric utility grid.

Commonly installed in remote locations with no electric utility grid.

Supply DC and/or AC electrical loads.

In many SAPV systems, batteries are used for energy storage.

Can be configured in several ways, such as direct coupled system;
or hybrid system.

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 Configuration

Direct-coupled SAPV system

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 Configuration

SAPV with battery system configuration for DC and AC loads

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 Configuration

Hybrid SAPV with battery system configuration for DC and AC loads

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 Installation

SAPV system – Solar Hybrid System 276kWp (Semporna, Sabah)

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 Installation

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 Installation

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 Installation
Pulau Perhentian (Solar Hybrid Plant)

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 Case Study on
GCPV System

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 Hot Spot

“Hot spots are areas of
elevated temperature affecting
only part of the solar panel.
They are a result of a localized
decrease in efficiency, which
results in lower power output
and an acceleration of the
materials degradation in the
affected area.”

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 Cable

“Correctly sizing the solar
cables ensures that there is
practically no overheating and
very little loss of energy. Using
an undersized cable not only
poses a potential for causing a
fire due to overheating but is
also a code violation in most
jurisdictions.”

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 Inverter
“Inverters today come
with monitoring systems. This
means that if your inverter
detects a problem with your
system – down to an individual
panel – you will know about it
and can send someone over for
maintenance. Inverters also
improve the efficiency of the
whole system. Energy gets lost
when it is transferred from the
panels to the home so an
inverter that can minimize
those losses delivers more
power to your home and saves
you more money. Inverters
become more efficient,
installers will need to install
fewer panels – saving you
money upfront and making
solar even more attractive than
it already is.”
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 Shading

“Solar panels help in maximum
utilisation of solar energy during
the day. However, shading can
have a huge impact on the
performance of solar photovoltaic
panels. A common misconception
is that partial shading does not
affect the output of solar panels. In
fact, the solar photovoltaic panels
consist of a number of cells which
are wired together into a series
circuit. Because of this, the
performance of the solar panel is
significantly reduced even if a
smallest section of the panel is in
shade.”

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 Cell Crack

“Cracks may lead to
disconnection of cell parts and,
therefore, to a loss in the total
power generated by the PV
modules”

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 Dirt

“Accumulation of dirt or
particles like dust, water, sand
and moss on the surface of
solar photovoltaic panel
obstruct or distract light
energy from reaching the
solar cells. This is a major
problem since the light
obstruction materials pose as
external resistances that
reduce solar photovoltaic
performance.”

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 Advantages and
Disadvantages of
Solar PV Energy

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 Pros and Cons

Advantages of Solar Energy Solar Energy Disadvantages

Renewable Energy Source Cost

Reduces Electricity Bills Weather Dependent

Diverse Applications Solar Energy Storage is Expensive

Low Maintenance Costs Uses a Lot of Space

Technology Development Associated with Pollution

Easy to Install Hard to Dispose

Source: https://www.greenmatch.co.uk/blog/2014/08/5-advantages-and-5-disadvantages-of-solar-energy

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 Solar PV Scheme
in Malaysia

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 FACTOR DRIVE RENEWABLE ENERGY (RE)

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 Feed-In Tariff (FiT)
Malaysia’s Feed-in Tariff (FiT) system obliges Distribution
Licensees (DLs) to buy from Feed-in Approval Holders (FIAHs)
the electricity produced from renewable resources (renewable
energy) and sets the FiT rate.
The DLs will pay for renewable energy supplied to the electricity grid
for a specific duration.
By guaranteeing access to the grid and setting a favorable price per
unit of renewable energy, the FiT mechanism would ensure that
renewable energy becomes a viable and sound long-term
investment for companies industries and also for individuals.

Source: https://www.seda.gov.my/reportal/fit/

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 Feed-In Tariff (FiT)

Source: http://www.seda.gov.my/

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 Feed-In Tariff (FiT)

Source: http://www.seda.gov.my/

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 Net Energy Metering (NEM)
NEM is one of the options for you to generate electricity from your
own solar PV system, and offset or reduce your electricity bills.
This system is designed to provide you credit for any excess of
solar energy you generate. It is then used to offset your next
electricity bill. This way you can save on your electricity bills and
also protect yourself from rising costs of electricity in the future.
Even better, you will become a part of the clean energy movement
to reduce the effects of climate change!
A bi-directional meter will be installed for these types of
connections, and you must ensure that adequate communication
signal is available since meter reading will be done remotely.
Before the solar PV system is connected, TNB will conduct a
technical assessment to ensure safe operation and reliability of
network.
SEDA Malaysia is the Implementing Agency for NEM.

Source: https://www.mytnb.com.my/renewable-energy/net-energy-metering

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 Net Energy Metering (NEM)

Source: http://www.seda.gov.my/

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 Net Energy Metering (NEM)

Source: https://www.seda.gov.my/reportal/nem/

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 Net Energy Metering (NEM)

Source: https://www.st.gov.my/en/contents/files/download/94/Guideline_for_NEM_Rakyat_and_Nem_Gomen_V24.pdf

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 Solar For Rakyat Incentive Scheme, SolaRIS is an incentive programme
launched by the Government aimed at attracting new installations of solar
photovoltaic (PV) systems in residential premises. This programme
supports the government’s goal of increasing renewable energy capacity
in the electricity supply system to 70% by the year 2050 and reducing
carbon emissions.

A cash rebate of up to RM4,000 will be given to residential customers who
submit Net Energy Metering (NEM) application to Sustainable Energy
Development Authority (SEDA) Malaysia from 1 April 2024 onwards and
successfully commission their solar PV system installations with TNB.

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 Self-Consumption (SELCO)
Apart from Net Metering, SELCO is another option for you to
generate electricity from your own solar PV system, to offset or
reduce your electricity bills. SELCO lets you consume all the
electricity generated by your solar system but will not allow any
excess to flow into the utility network.

You are required to present to TNB the power flow study of the
proposed connection of your generating plant/source (if the installed
capacity of the solar PV system is 425kW and above) so we can
identify whatever effects it may have on the utility network.

Source: https://www.mytnb.com.my/renewable-energy/selco

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 Self-Consumption (SELCO)

Source: http://www.seda.gov.my/

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 Self-Consumption (SELCO)

Source: https://www.mytnb.com.my/renewable-energy/selco

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 Large Scale Solar (LSS)
LSS is a scheme that lets you generate your own electricity via solar
PV farm with installed capacity ranging from 1MW to 30MW to 50MW/100MW
(for grid/transmission connected solar PV plants) and sell to the
grid. This scheme is administered by the Energy Commission and the
selection for potential developers will be to through competitive
bidding.

A technical study must be conducted before submission for the
scheme to the relevant authority.

Source: https://www.mytnb.com.my/renewable-energy/large-scale-solar

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 Large Scale Solar (LSS)

Source: https://www.mytnb.com.my/renewable-energy/large-scale-solar

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 New Enhanced Dispatch Arrangement (NEDA)
New Enhanced Dispatch Arrangement (NEDA) is a program which
allows non-PPA/SLA Generators such as co-generators, renewable
energy generators/producers, embedded generators and expired
PPA/SLA Generators to operate as Merchant Generators to sell
energy to the Single Buyer. NEDA allows these power generators to
bid their variable costs (fuel cost and operation and maintenance
cost) than those stated in the PPAs and SLAs. NEDA is designed to
enhance competition and cost efficiency of the Single Buyer market.

Source: https://www.mytnb.com.my/renewable-energy/new-enhanced-dispatch-arrangement

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 New Enhanced Dispatch Arrangement (NEDA)

Source: https://www.mytnb.com.my/renewable-energy/new-enhanced-dispatch-arrangement

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 New Enhanced Dispatch Arrangement (NEDA)

Source: https://www.mytnb.com.my/renewable-energy/new-enhanced-dispatch-arrangement

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 Corporate Green Power Programme (CGPP)

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 Corporate Green Power Programme (CGPP)

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 Activity

Using the NEM Calculator (SEDA),
you are asked to design a solar PV
system for your home according to
your average electricity bill per
month.

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 Q&A

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 TNB Integrated Learning Solution Sdn Bhd – ILSAS
Jalan IKRAM-UNITEN, 43650 Bandar Baru Bangi,
Selangor, Malaysia.
Tel: (+6)03-892272222
Fax: (+6)03-89263505
Email: [email protected]
Website: www.tnbilsas.com.my

Energy Industry Award Human Resource Minister
2011- Training Provider Award
Excellence 2007 Winner –Best Training
Provider Category

Role Model Company
2013 for Electrical Training
Programmes by JTM

City and Guilds Approved Training Centre
Disclaimer
All information contained herein are solely for the purpose of this presentation only and cannot be used or referred to by any party for other purposes without prior written
consent from TNB-ILSAS. Information contained herein is the property of TNB-ILSAS and it is protected and confidential information. TNB-ILSAS has exclusive copyright over
the information and you are prohibited from disseminating, distributing, copying, reproducing, using and /or disclosing this information.

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