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Download Glossary of Alternative Energy Terms

1. What is a POWER INVERTER?
2. Square Wave Inverters:
3. PWM Inverters, Modified Square Wave Inverters, Adapted Sine Wave Inverters etc.
4. PURE SINE WAVE INVERTERS
5. What is Inverter/ Solar Battery?
8. HOW TO CHOOSE THE RIGHT BATTERY?

9. WHAT ABOUT
BATTERY FUSES?
10. HOW TO CHOOSE THE BATTERY CABLES?
11. WHAT IS COS PHI?
12. HOW CAN INVERTERS BE CONNECTED IN PARALLEL?
13. IS THERE A NEED FOR SERIES DIODES ON A SOLAR FIELD?
14. WHY DOES A GRID CONNECTED INVERTER NEED EARTH CONNECTION WITH HEAVY ( 25mm2) CABLE?
15. HOW TO GET INVERTERS WITH DIFFERENT FREQUENCIES AND/OR DIFFERENT VOLTAGES?
16. WHY DOES THE AUTOMATIC LOAD SENSE CIRCUITRY NOT SENSE SOME LOADS?
17. CONVERTER
18. VOLTAGE TRANSFORMER
19. VOLTAGE ADAPTER/RECTIFIER


 

1. What is a POWER INVERTER?

An Inverter is able to convert battery voltage (DC) to alternating current (AC) e.g. 220V AC/50Hz. This may be achieved in several ways. This may be achieved in several ways depending on the available technology and the intentions of the designer. Basically we have three major types of power inverters, namely: Square wave, Modified Square Wave and Sine Wave


2. Square Wave Inverters:

The output of these inverters is a square voltage of 220V AC/50Hz. The regulation of the output voltage is often very inaccurate and directly depending on the input voltage and on the output load. Square Wave Inverters may have very high efficiency for purely resistive loads ( cos phi = 1, e.g. heaters). Switch mode power supplies like he type in computers (as load) may also give good results if the EMI regulations are met by the inverter.
Loads that have problems when used with square wave inverters:

      • Any loads with cos-phi other than 1 ( inductive or capacitive loads, eg fans , refrigerators, and Fluorescent lights with chokes)
      • Energy saving lamps and other loads with capacitive voltage dividers. Current peaks caused by very steep voltage slopes cause massive reduction of their life time.
      • Interference (white stripes etc.) and audio noise in Hi-Fi, video or TV units.
      • Loads with phase control, sensitive electronics.
      • Electric motors, there are two major problems: Motors running very hot due to current peaks caused by square wave, motor bearings wear out quickly due to torque variations.


3. PWM Inverters, Modified Square Wave Inverters
, Adapted Sine Wave Inverters etc.

All of these inverters have in common the sharp voltage slopes of the square wave inverters. The word “sine” is only introduced by marketing people. The only advantage of these inverters is the regulation of the output voltage independently of input voltage and load.


4. PURE SINE WAVE INVERTERS

This technology is state of the art for several years now. There is no reason for any other inverter technology except price. The pure sine wave is a “natural” waveform as created by any power station available at your home wall socket.
ANY MAINS LOAD AVAILABLE WAS CREATED FOR USE WITH SINE WAVE ELECTRICITY!
Sine wave inverters are more complicated to build thus resulting in increased manufacturing costs. The sine wave shape is synthesized by an additional PWM filter at the output of the inverter. Idle consumption is slightly higher than square wave inverters. The biggest advantage is found in the high efficiency and hassle free operation of almost any load.

MORE TECHNICAL DETAILS (OVERVIEW):

      • 50/60Hz technology: Isolation and voltage step between DC and AC side is achieved by iron transformers. Very high safety standard. Increased lifetime due to reduction of semiconductors. Battery acts as storage for reactive currents. The only disadvantage is high weight of iron transformers.
      • High frequency technology: These units utilize a HF transformer for isolation/voltage step. Reduction of weight but increased number of electronic parts. Efficiency is similar to 50/60 Hz technology with resistive loads but there is no chance to use the battery as storage for inductive currents. Loads with low cos phi can cause problems.
      • High frequency inverters without isolation between DC/AC: Only used in cheap products. Not recommended for safety reasons, no up to date technology.

 5. What is Inverter/ Solar Battery?

Inverter or Solar battery like any other battery is a piece of device for storage of energy for use when needed. To this end an inverter battery or solar battery must have the ability to charge and retain charge very fast. I will also be able to deliver the charge as needed during usage.

Types of Batteries:

There are several types of batteries, but we can only explain the major types based on our topic here. There are basically two types: Deep cycle and shallow cycle.
6.  Deep Cycle batteries have fewer and thicker cells. This ability gives it the resistance to deliver charge to the inverter to a larger extent, up to 60% or 80% dept of discharge without a defect on the plates or the cells.
7. Shallow cycle batteries or traction batteries have high numbers of thin plates or cells with the ability to discharge with high current for a short time. Prolonged discharge will normally cause the cells to damage. The shallow cycle batteries are best for car starting.


8. HOW TO CHOOSE THE RIGHT BATTERY?

Batteries for inverter or solar energy usage are best rated from 100ah.
Inverters should be operated on batteries of appropriate size. The battery should be cycle proof. Generally, for lead acid batteries: the shorter the discharge time, the lower the energy usable. E.g.: If a battery can deliver 10 Amps for 10 hours, it will deliver 100 Amps only for 20-30 minutes. You should choose the battery size for an operation time of several hours with your estimated load. Additionally you should only allow for a discharge down to 60 to 70% of full capacity in order to increase battery lifetime. E.g: Lifetime of a battery may be 5000 discharge cycle with 20% discharge per cycle. The same battery will only live for approximately 2000 discharge cycles if every cycle is 40% discharge.
Please visit for more information:  www.prostarglobal.com/products/batteries

9. WHAT ABOUT BATTERY FUSES?

Battery fuses should be placed as close as possible to the batteries in order to protect the whole battery cable. In case of cable short, fire might occur! It must be rated 25% above the expected maximum energy draw from the battery bank. DC rated fuses are the best for inverters.


10. HOW TO CHOOSE THE BATTERY CABLES?

DC current in battery cables causes voltage drop according to Ohms law V=R*1. As general guidance: 1m of cable 25mm2 has approximately resistance of 0.001 Ohm. This value multiplied by battery current results in voltage drop. Example: PRC 3000/24 with nominal load, DC current approximately 125Amps, 1.5m distance from batteries, V=2*1.5*125*.001=0.38 volts, heat dissipation in Cables 60Watts approximately! This application should have 35mm2 or even 50mm2. Place the inverter as closely to the battery as possible. Use inverters with higher input voltage if possible. The higher the input DC value the less the current loss from the cable as the efficiency is increased.

11. WHAT IS COS PHI?

With heavy inductive loads the product V*1 (VA on AC side) is much larger than the actual watts delivered. E.g. Inductive motors, fluorescent lamps, etc. This means some of the energy is stored in the inductivity of the load and then flows back to the battery. These inductive currents cause heat dissipation in the power semiconductors and in the cables as well. As the capacity is used up for reactive currents, there is   “no room” for active currents.

 WHY DOES MY 600VA INVERTER NOT WORK ON A LOAD DECLARED 600W?

      • With inductive loads the VA value is bigger than the Watts value. E.g. 600W load, cos phi 0.6 results in 1000VA!
      • With motors often the mechanical output is declared so the VA rating is even higher.
      • Another cause for malfunction is inrush currents (5 to 10 times  nominal current with motors).

12. HOW CAN INVERTERS BE CONNECTED IN PARALLEL?

      • Stand alone inverters: Paralleling is only possible on the DC side;   AC sides always have to be isolated. Never connect your mains to the inverter output or connect the out puts of two stand-alone inverters together, immediate destruction will result.
      • Grid feeding inverters: Paralleling is possible on the AC side. DC Paralleling is not POSSIBLE since MPP optimization has to be performed by every single inverter on its solar field.
      • Some inverters are however designed to be connected in parallel with some special connection meant for frequency synchronization and power out put interconnections.
      • Check out for some models of Xantrex, ASP, and Victron inverters for more information. 

13. IS THERE A NEED FOR SERIES DIODES ON A SOLAR FIELD?

No! Fuses for each string of solar modules are sufficient. Use twice the string current for fuse. Series diodes are only heat dissipaters. By the way, parallel diodes are built into the junction boxes of most solar modules.

14. WHY DOES A GRID CONNECTED INVERTER NEED EARTH CONNECTION WITH HEAVY ( 25mm2) CABLE?

The main function of the earth connection cable is lightning protection and interference suppression. The solar panel field acts as antenna which may transmit interference caused by switching slopes in the inverter. The inbuilt filter circuitry is only active with appropriate earth connection.

15. HOW TO GET INVERTERS WITH DIFFERENT FREQUENCIES AND/OR DIFFERENT VOLTAGES?

Most of the PROSTAR inverters are available for various frequencies/voltages. Different input voltage range is also possible. Ask your distributor for availability if you need that special inverter.


16. WHY DOES THE AUTOMATIC LOAD SENSE CIRCUITRY NOT SENSE SOME LOADS?


There are some limits to the load sensing circuitry. Since the internal measuring circuits are used for several different purposes, the sensing of very small loads can cause a problem for the inverter. Drifts of the sense circuitry over temperature and voltage may also cause drift.

Some of the energy saving lamps have a very bad cos phi.
Some loads are detected correctly but turn off after 10 seconds because operating current is lower than inrush current.
Often the problem is solved by using a different brand of lamps. We will improve load  sensing with the next generation of inverters.


17. CONVERTER:


A piece of electronic device meant for DC/DC conversion e.g 12VDC 10Amps/24VDC 5Amps.

18. VOLTAGE TRANSFORMER:

Transforms or steps AC voltage values from one level to another using transformer e.g. stepdown transformer: 220VAC to

24VAC. Step-up is simply the reverse.

19. VOLTAGE ADAPTER/RECTIFIER:

                       
Changes AC voltage to DC voltage e.g. 220VAC/24VDC. The input value may be same as output in terms of voltage level.

 
 
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