Tuesday, September 12, 2017

Do's and Don't of Installing Solar PV Systems.

In this post I will write from one of my articles published in the Annual Journal of Institute of Engineers of Pakistan - Saudi Arabian Chapter  (IEP-SAC) in 2016. This post is regarding some bad practices when installing a solar PV systems or in general any electrical system. I visited a farm in Abqaiq city of Eastren Saudi Arabia. 

Introduction

The use of solar energy is growing extensively in the Kingdom of Saudi Arabia (KSA). Being an oil rich country the dependency of energy generation on oil is very high. Meanwhile oil also forms the economic backbone of KSA. With the fall of oil prices the government is encouraging the use of renewable energy sources like Solar, Wind and Waste to Energy. With the increasing use of solar photovoltaics (PV) for domestic use the installers tend to compromise the quality and standards for photovoltaic system installation. This report is about the mistakes encountered while installing solar power system and how to avoid them. The best practices for solar power system are published in the National Electrical Code (NEC) article 690 [1] which ensure highest performance and safety and can be referred for further details. Another entity that publishes and enforces the standards for PV installation is the North American Board of Certified Energy Practitioners (NABCEP) [2].  
A case study is presented for a standalone solar power system installed in a farmhouse in eastern province of Saudi Arabia. The farm house is situated off the main highway from Riyadh to Dammam at a latitude of 26.184 degrees and longitude 49.49 degree east. The area lies in the subtropical region and is part of the larger Arabian dessert. To the south of this site is the Rab-Al-Khali Dessert (the Empty Quarter).  

System Attributes

The solar power system under study is a standalone system with 24 hour battery backup. It is installed on a roof of a small home in a farm and is used to power up AC electrical load like television, refrigerator and lights. The installed peak capacity of the system is 1.3 kW. Figure 1 shows the PV array installed on the roof of the home. The system costs including the installation was about SAR 20,000.


Figure 1: 1.3 kilo Watt Standalone Solar Power System with 24 hour battery backup
The system is divided into four distinct parts.
1.      1.3 kW Solar Array
2.      450 AH Battery Bank
3.      3000 Watt Inverter System
4.      Charge Controllers

System Design

Physical Layout

The solar power system has five roof mounted solar panels. The structure of the roof is shown in Figure 2.


Figure 2: Roof and Building Layout (The figure is not according to scale )
The array is aligned with the tilt of the roof which is 5 degrees and is pointed towards south i.e Array Azimuth angle = 180 degrees.

Electrical Layout

The PV array consists of 5 solar panels. Each solar panel has a rated power of 260 Watts. The array is divided into two sub-arrays which are connected to two charge controllers that feed both the solar inverter and battery bank. Figure 3 shows the block diagram of the system electrical layout.


Figure 3: Block diagram of 1.48 kW off-grid solar power system
All the major components of this plant are described below.

Solar Panels

The solar panels are from Yingli Solar. The characteristics of this panel are given in Table 1.

Table 1: Characteristics of Yingli Solar Panel
Parameter
Value
Rated Power
260 Watts
Open Circuit Voltage
38.9 Volts
Short Circuit Current
8.98 Amperes
Rated Voltage
30.9 Volts
Rated Current
8.41 Amperes

Charge Controllers

The charge controllers connected to the system are from the manufacturer Copex. The electrical/thermal characteristics of this charge controller are given in Table 2.
Table 2: Charge Controller Characteristics
Load Current
30 Amperes
System Voltage
12 Vdc or 24Vdc
Max Voltage of Solar Collector
47Vdc
Protection Class
IP32
Ambient Temperature Allowed
-25 to +50 degree C
Thermal Protection
85 degree C

The purpose of charge controller is to regulate the voltage of the DC Bus. The DC bus in this case is operating at a voltage of 24 volts. 24 volt bus was selected because the inverter in the system, operates at 24 volts. The charge controller keeps the DC bus at a voltage slightly higher than the DC Bus voltage i.e. (28 volts approx.). This is to make sure that during the day, the current flows towards the batteries in order to charge them. The connections of the charge controller are shown in Figure 3


Figure 4: Copex Solar Charge Controller (http://copexsolar.com/scd-series/scd-1010/ )

Battery Bank

The battery bank is connected to the system to provide a backup power for 24 hours. The batteries used in this system are Automobile duty – Lead Acid batteries from National Battery Company Saudi Arabia. Figure 5 shows one of the batteries connected in the battery bank.



Figure 5: Spark Automotive Battery from National Batteries Company - Saudi Arabia
The batteries are rated at 12 volts and 150 Amp-hours each.
The battery bank is formed by making a series parallel connection of six batteries. To attain a DC Bus voltage of 24 volts, three sets of two series batteries are connected in parallel. Figure 6 shows the battery bank. The bank is placed inside a box with holes to allow air ventilation.  The connection of the battery bank is shown in Figure 3.



Figure 6: Battery Bank (Dust settled on the batteries)

Inverter

The inverter used in the system is a general purpose inverter available in local market. It is a modified sine wave inverter with a power rating of 3000 watts and DC input voltage of 24 volts. The characteristic data of this inverter is not available hence it is not mentioned in this report. Figure 7 shows the power inverter.


Figure 7: 3000 Watt Power Inverter
This inverter produces an output voltage of 330 volts AC.



Inverter System Layout

The inverter is connected with the DC bus formed by the two charge controllers. This system is shown in Figure 8. The purpose of inverter system is to collect DC power at maximum rate from solar array and provide AC power at constant voltage to the load. The maximum power from the solar panels is ensured by the charge controllers whereas the inverter provides a constant AC voltage to the load side at 330 volts.


Figure 8: Layout of Inverter System



 

Load on the system

The system is capable to power a load of 1.25 kW peak theoretically. But at the time of visit following loads were being powered up by the system



Figure 9: All loads connected to the PV system
Table 3: Load Characteristics
No.
Load Type
Power Rating
Quantity       
1
Television
70 Watts
1
2
Refrigerator
100 Watts
1
3
Energy Saving Lamp – type 1
36 Watts
3
4
Energy Saving Lamp – type 2
20 Watts
1
5
Miscellaneous Load (mobile charger)
2 Watts
1

Total load
300 Watts





Observations and Recommendations for Improving the Design – The Don’ts.


Wire Routing:
The routing of wires must be proper to avoid confusion during inspection. The wires in the system were improperly routed which caused unwanted stretching at the joints. Secondly the wires are a potential tripping hazard for person performing cleaning or any other activity on the roof. Therefore they must be properly secured and routed along the roof.




Figure 10: Improper routing of wires form PV Panels


It is recommended to re-route the wires and use proper wire conduits to secure all the loose wires in place.



Figure 11: Improper wiring of battery bank – the battery terminals are not covered.



The wires inside the battery bank must be secured to the bank housing. Loose wires are never preferred especially when the battery cleaning/maintenance is performed. Loose wire can be easily tangled.
Another observation on the battery bank is the covering of battery terminals. The terminals must be properly covered to avoid any metal tool / damp cloth etc.  to cause a short circuit.




Figure 12: Improper wiring of inverter and charge controller


Figure 10,Figure 11 and Figure 12 show the improper wirings of the system. The wires are not secured in proper place and are jumbled up. To tackle this issue, the wires must always be properly attached to the housings and wire conduits must be used to make groups of wires.

Wire Connections:

The series parallel connections in the PV system have been done using simple insulation tape. Even-tough the modules are originally equipped with proper MC-4 connectors. This practice is to be avoided and proper MC-4 connectors are to be used for making series-parallel connections.





Figure 13: Insulation tape used for making connections


The problem with insulation tape is that it can easy get torn apart after long term exposure to changing weather conditions, water and dust. This may lead to exposed conductors that may get short circuited during cleaning or accidental contact with metal mounting structure.

Wiring/Instrument Labels:

There are no wiring labels on any of the wires. This can be a serious problem if any modification/upgrade or inspection is required on site. To overcome this issue it is recommended to use proper water/weatherproof wiring labels marking all the DC Wires, Strings, Modules, Inverter, Charge Controller and Batteries inside the bank.



Cleaning of modules is necessary and there are different hazards involved if proper precautionary measures are not taken. e.g. the modules are located very near the edge of the roof giving rise to fall hazard. There must be a support rail near the edge to avoid any accidental fall.

DC Disconnect Switch

In the present design, there is no DC disconnect switch in the system. The DC disconnect is required to disconnect the solar panels from the system for reasons that may include
1.      Maintenance of Inverter System
2.      Emergency Shut-down
Apart from a DC disconnect switch, there is no other way to stop the power flow from solar panels to the system. The solar panels will produce power as long as there is light. Therefore in order to carry out any maintenance activity on the inverter system or the battery bank the solar panels are to be disconnected otherwise there exists a shock hazard for the maintenance personnel.

AC circuit Breaker

In the present system design, there is no AC Circuit breaker to interrupt the system in case of a fault such as a short circuit on load side. This is regarded as the biggest hazard because in case of a short circuit there is nothing to stop the current from flowing to the loads except for the inverter itself with its built-in short-circuit protection. A short circuit can easily damage the inverter in that case.

Battery Fuse and battery DC disconnect switch

A battery fuse and a DC disconnect switch are required to protect the battery bank and disconnect it from the DC bus respectively. The purpose of battery fuse is to protect the battery bank from providing too much current in case of a short circuit on DC Bus. A short circuit on DC bus will case a very high current in the orders of hundreds of amperes to flow from the battery bank. This will cause a high discharge rate on the battery and can render the battery bank useless if its “state of charge (SOC)” goes below a minimum threshold.

Copper DC-Bus Bars for Battery Bank

The battery connections are made using wires jumping from one terminal to other terminal in a haphazard way. The terminal connectors are pointing inwards and are covering the battery caps hence creating a hindrance for opening the caps. To avoid this the battery connections are to be made using copper bus bars.

Wire Color Codes

Proper color codes for the wires must always be used. In the present design, the wires for making the connections on the PV array are all grey colored hence making the positive and negative wires indistinguishable. Moreover this color coding needs to be consistent in the whole system.
AC wires should have different colors than DC Wires.

Placement and Orientation of Inverter

The inverter in the current design is placed in an incorrect orientation. The ventilation openings of the inverter are pointing upward hence dust / water can easily penetrate inside the inverter.
Secondly the indicator LEDs on the inverter are all pointing upward and hence they are not easily observable for an inspector. The indicators should be clearly visible so as to fulfil their purpose which is to provide information about the inverter status.
The sockets are also pointing upwards hence they are vulnerable to water ingress and dust settlement as is seen in Figure 14.




Figure 14: Inverter ventilation ducts, indicators, sockets and switch.

Cleaning the Modules:

The modules are to be cleaned regularly. The power produced by the modules is inversely related to the amount of dirt accumulated on the module surface. It is recommended to clean the modules at-least once per week or as determined by weather conditions. The modules are to be cleaned using water with light brushing to avoid scratches. A dry brush must never be used to remove the dust from the panels. Once per month, the modules can be cleaned using water with detergent. It must be made sure that all the wires are properly secured and no conductor is exposed so that there is no short circuit in case of their contact with water. Figure 15 shows the solar panels before and after the cleaning was performed. The modules in this case were not cleaned for 6 months hence the battery bank was never properly charged leading to the degradation of all the batteries.
 






















Figure 15: Dirty Modules (Before cleaning (Left), after cleaning (Right).

Conclusion:

The increasing use of solar photovoltaic systems has led the installers to compromise the standards for installation of such systems. The standards which are made to ensure the safety and reliability of a system are not followed hence leading to undesired consequences. The report presented a case study of a solar power system installed in the town of Abqaiq in Saudi Arabia. This system had many technical and safety flaws which must be avoided in any solar power system installation.

Friday, September 1, 2017

Research in Solar Tracking - Some Observations

I came across two research papers on design of solar tracking system by same author. The two papers are

1. A sliding mode control for sensorless tracker: Application on a photovoltaic system (International Journal of Control Theory and Computer Modelling (IJCTCM) Vol. 2 No. 2, March 2012.

2. A position control review for a photovoltaic system: dual axis sun tracker (IETE Technical Reveiw, Taylor & Francis, 2011.

Upon reading them I found a huge number of similarities between the two which in my opinion is against the sanctity of the field of scientific research. My first impression was that there is a high degree of plagiarism. Although the author for both papers is same person yet it is against the scientific practice to write same thing is two different journals just by changing some nouns and prepositions and adding a little bit of new but insignificant information. Such practice always has two outcomes

1. The impression of the author is debilitated in the scientific community.
2. The Journal which publishes such work looses its credibility.

Recently I studied a research paper from 2004 about the effect of sun tracking systems on I-V characteristics of solar photovoltaic modules. The title of this paper is " The effect of using sun tracking systems on the voltage-current characteristics and power generation of flat plate photovoltaics". This paper does not show any real work, instead just some pictures from a single day of testing a shown. The author claims to have compared the I-V Characteristics of PV modules by mounting them on different types of tracking systems BUT no metrics have been defined to compare different curves. In short, this paper is a joke.


Another observation is that people researching solar tracking systems confuse "Physical Tracking Systems" with "Maximum Power Point Tracking" both of which are completely different topics.

One such example can be found in following research paper

Lee, C. Y., Chou, P. C., Chiang, C. M., & Lin, C. F. (2009). Sun tracking systems: a review. Sensors9(5), 3875-3890.


I will keep updating this blog whenever I find such non-sense.