sizing of pv system

1. Sizing a PV system

2. Content

3. Systems

4. Importance

5. Steps

6. Load evaluation

7. Energy use profile of individual
appliances
Refrigerator Energy Consumption Profile

8. They are very good candidates to enhance them with “smartness”.
The intermittent peak electricity use can be shifted in time, in order to reduce the
overall peak energy demand on the grid.
From the household perspective, time-of-use pricing will enable significant
energy bill savings.
However, the DR algorithms have to be implemented without incurring
unacceptable consequences for the consumers.
The main benefits of utilities that arise from using DR include:
> automatic energy reduction without any inconvenience to consumers;
> precise control of appliance power usage on a network level – a powerful
facility for sharing the load among participating consumers;
> a clear, real-time view of the aggregated demand-side energy-saving
potential on the network that enables:
> the prediction of required supply;
> the setting of time-of-use and dynamic energy pricing;
> the ability to minimize the need for purchasing spinning reserve, thereby
lowering costs and significantly reducing carbon emissions
demand response (DR).

9. problems related to loads
For all systems (AC and DC supply
systems):
• A1 - Wrong selection: some loads are non-adapted for
stand-alone PV systems.
• A2 - wiring: substandard or inadequate wiring and
protection devices will also cause poor system response.
• A3 – Low efficiency: low electrical efficiency loads lead
to over energy consumption.
• A4 - Stand-by loads: stand-by mode of some loads
waste energy.
• A5 - Start-up: current spikes during the start-up of some
loads can create temporal overload of the system.

10. problems related to loads:
Only for AC
• AC1 - Reactive power: when appliances with
capacitive or inductive loads are used, real
circulating current differs from the consumed.
• AC2 - Harmonic distortion: some electronic
appliances with non-linear loads can create
waveform deformation of the inverter output
signal.
• AC3 - Mismatch between load and inverter
size: Low overall efficiency can result from
oversized inverters operating at low-power for
long periods.

11. A1 Wrong Selection.
• For good energisation it is better not to use electricity for all types of
load.
• For example, generally it is not appropriate to use PV electricity to
produce heat.
Example
• The energy needed to take a shower is about 1 kWh, this daily habit
accounting 30 kWh/month, or 500 Wp of installed PV power*
• Using thermal collectors to directly heat water is much more cost-
effective for this usage (about 10 times cheaper than PV) *
Assuming a water temperature of 10 ºC, and raise it to 38 ºC; for
heating 30 l of water to take a shower we need: 30 lwater * 4,18
kJ/(kg*ºC) * 1 kg/1lwater * (38-10)ºC water * 3600s = 1kWh.
• Calculation of installed Wp: assuming a daily average irradiation of
4000 Wh/m2, and a performance of the system of 50%, the Wp
needed are: 1 kWh/day/50% * 1kWp/4hp = 500Wp

12. A2 - wiring
• Wiring is an important issue to guarantee correct
performance when using appliances. Having
undersized or damaged distribution cables, can
lead to the following problems:
Problems:
• If section of wires is undersized or selection of
fuses is incorrect, high current through these can
cause a fire ( by resistive heating).
• Undervoltage may detrimentally affect the
performance of some appliances.

13. A3 Low efficiency
• Generally speaking, inefficient appliances are cheaper to
buy.
Problems:
If the system was sized for efficient loads and, inefficient
devices are used, insufficient energy is available,
resulting in:
• Frequent cut-offs.
• Frequent low SOC of batteries resulting in low life.
• System undersized.
• User unsatisfied and may even by-pass the controller.
• If diesel genset runs periodically, operating costs can
increase dramatically due to increase in demand/ or
increased demand.

14. saving energy with high-
efficiency appliances:

15. A4 Stand-by loads
Problems:
• When these appliances are left on stand-by for
hours or even days, their cumulative effect can
become a significant part of system
consumption. This may be reflected as low
charge of the batteries and earlier cutoff of the
system.
• A recent study carried out in Japan estimated
that about 10% of domestic electricity
consumption is used to power appliances on
stand-by.

16. A5 Start-up
• Some appliances consume high electric power (several times its rated
power) at start-up.
• In case of AC current, the inverters should resist peaks of power several
times higher than its rated power value, during the short start-up periods.
• The loads affected should have a starter, which could “soften” the start-up.
• The problem would be solved using loads according to the availability of
power, always considering energy-availability (e.g. water pump with less kW
but operating during longer time).
• In case of simultaneous start-up of the appliances, the peak power would
be the sum of each one. Progressive start-up of the loads connected should
be done, controlled by the inverter or another device.
• The last solution would be to use an alternative power source for
problematic loads (e.g. a diesel generator,...).
• Specify the inverter continuous watts and surge watts by estimating the
surge requirements correctly.
• Use a linear current booster or use permanent magnets in pumping
systems to assist start-up.
• A starter used for a water pump could be a device, which produces a
frequency variation of the output inverter AC signal, to improve the start-up
of the water pump.

17. start-up of a refrigerator

18. start-up of a water pump

19. AC1 Reactive power
Problems:
• The current to be delivered by the inverter is much
higher than the real consumption,
• resulting in a possible overcharging of the system.
• Current through the cables is higher than necessary,
resulting in the need to increase the wire section to
reduce voltage drops. This will add to the cost of cabling.
The consumption of an electric motor can have a phase
between current and voltage of 50º (cos(50º)=0.64). The
inverter has to supply, in this case, 1 / 0.64 of the current
used by the load (1.56 x the motor current).

20. AC1 Reactive power
Solutions:
• Reduce the need for inductive loads like
conventional ballasts, etc.
• Use of synchronous motors instead of
induction motors in the relevant
appliances.
• Install capacitors at the inductive load or
the distribution panel to provide the
required amount of capacitive reactance.

21. AC2 Harmonic distortion
Problems:
• This causes voltage deformation in the output signal of
the inverter, which may occasion problems with the other
loads.
• Harmonics can shorten the life of the appliances by
voltage stress and increased heating of electrical
insulation.
• Some devices need to sense ‘zero-crossings’ to control
internal switching and could malfunction as the ‘zero-
crossings’ may appear to shift because of harmonics.
Solutions:
• Use of output filtering or use of inverters with high
switching frequency in situations where harmonics are
expected.

22. AC3 Mismatch between load and
inverter size
Problems:
The energy consumed is higher than the expected
one, resulting in:
• Cutout of the system or permanent low SOC of
batteries
• High non-useful energy consumption.
Solutions:
• Use of a specific dedicated inverter for the
application, or a modular inverter with working
points of good performance ranging from low to
its maximum power.

23. Smart Consumers
 A key feature of the Hybrid grid is demand response (DR).
 As defined by the Association of Home Appliances
manufacturers (AHAM) in December 2009 in a smart grid
white paper, DR refers to a set of scenarios whereby the
consumer, utility can reduce energy consumption during peak
usage or other critical energy use periods.
 It is critical to reduce peak demand to avoid the use of
high-cost and high-emission power-generating resources
or when the utility encounters some other issue on the
electrical grid that requires the reduction of electricity
demand, it can send a signal to the home so that the
system will reduce its electrical load during this critical
time periods.

24. Smart appliances
 In the smart appliances concept, the appliances are no
longer passive devices, but active participants in the
electricity infrastructure contributing to energy reduction and
optimization of the electrical grid for greater compatibility with
its greenest energy-generation sources.
 On this line, by providing a variable load, smart appliances
connected to the smart grid are ideal complements to
renewable energy such as wind and solar power, which are
inherently variable in supply.
 First, the focus is on residential consumers, where the
development of DR is more straightforward.
 Developing the smart grid and linking it to smart appliances
and others products having DR capabilities will reliably and
predictably reduce appliance electricity consumption in real
time

25. Smart appliances
 The way consumers interact with the grid is essential.
 Consumers must be able to choose when and how they want their
smart appliances to participate in the smart grid.
 The offer of financial incentive – through time-of-use pricing or other
incentive plans – will be the single biggest driver for consumers to
change their energy consumption habits.
 Therefore, the smart appliances concept provides benefits to
both the consumers that obtain direct economic benefits, and
the utility and society at large.
 The best candidates for smart home appliances are: clothes washer,
refrigerator, clothes dryer, dishwasher, water heaters and heating,
air conditioning, battery charger (for electric cares).
 In the next years the smart appliance market is expecting to record
an important grow.

26. Smart appliances, by integrating
them in the “Whirlpool Smart
Device Network (WSDN)”:

27. Resource Evaluation

28. Resource Evaluation

29. Resource Evaluation

30. Resource Evaluation

31. Resource Evaluation

32. Resource Evaluation

33. Resource Evaluation

34. Resource Evaluation

35. Resource Evaluation

36. Resource Evaluation

37. PV Module selection [JRC]

38. Connection

39. Inverters [JRC]

40. Inverters

41. Inverters

42. Inverters

43. Losses in PV system

44. Losses in PV system

45. PV Yield

46. Final Yield including losses

47. Final Yield including losses

48. Costs

49. Project Example

50. Project Example

51. Project Example

52. Project Example JRC

53. Resource JRC

54. Resource JRC

55. PV Photon Database

56. PV Photon Database

57. Inverters Photon Database

58. Module placement