The sluggish growth of the mono-Si market this year is notable given
the fact that many cell manufacturers had switched from multi-Si to
mono-Si production in the second half of 2014. Statistical research
conducted by EnergyTrend for the 2015 PV market finds that even though
the global demand has reached 53GW, the total mono-Si cell shipments
worldwide may be lower than 10GW.
Cost is the deciding factor as to
whether or not the mono-Si market can achieve higher growth in the
future. According to EnergyTrend’s annual mono-Si cell shipment forecast for
2015, Taiwan as the leading producing country may surpass 2GW. Major
Chinese cell manufacturers including JA Solar, Suntech, and DMEGC will
push their country’s mono-Si cell shipments to 2GW. Other regional
markets – the U.S., Europe, South Korea and Japan – will ship around
1GW~1.5GW respectively. Major mono-Si cell manufacturers in those
regions include SunPower from the U.S., SolarWorld from Europe, LGE from
South Korea, and Japan’s Sharp and Panasonic. Taken together, this
year’s global mono-Si cell shipments are estimated to be under 10GW. The
picture is starkly different in the multi-Si market, where cell
manufacturers have been seeing a surge in orders and high capacity
utilization rates for multi-Si cell production. Currently, just about
10% of the top-tier global cell manufacturers’ combined capacity is
devoted to mono-Si products.
Figure 1: Total mono-Si cell demand and shipments in 2015
Source: EnergyTrend
Mono-Si products are overcoming their weaknesses
For companies developing mono-Si products with higher efficiency, the
good news is that the distributed generation (DG) markets in the U.S.,
the U.K., and Japan have kept growing. However, prices of mono-Si
modules remain much higher compared with prices of multi-Si modules.
Moreover, P-type mono-Si products come with inherent disadvantages of
having higher cell-to-module (CTM) loss and higher light-induced
degradation (LID). Using passivated emitter rear cell (PERC) process
during the mono-Si cell production significantly raises the products’
conversion efficiency rates, but the technology also increases LID from
the average 2% to 3~6%. N-type mono-Si cells by contrast do not suffer
from LID. However, they have lower production yield rates and less price
flexibility. Producing N-type mono-Si cells also requires additional
equipment. Hence, N-type mono-Si products have yet to become the market
mainstream due to high costs, and they may need another two or three
years become popular.
Since the second half of 2015, cell manufacturers have gradually
overcome the mentioned disadvantages of P-type mono-Si cells (pricing,
CTM loss, and LID). Demand for P-type mono-Si cell is therefore likely
to pick up as better solutions to LID become available and the mono-
versus multi-Si price difference in the p-type cell market starts to
narrow. In fact, prices of mono- and multi-Si cells in the Chinese
market have been almost identical in recent times.
Costs of P-type mono-Si cells have also been lowered substantially
this year following the Chinese New Year holidays. During this period,
the weak demand for mono-Si products caused excess inventory for mono-Si
wafer manufacturers and forced them to sharply reduce their prices. By
the second half of 2015, multi-Si wafers stayed at US$0.82~0.83/pc on
average, whereas the average price of mono-Si wafers had dropped from
US$ 1.05/pc to US$ 0.92/pc. Therefore, the price gap between mono- and
multi-Si in the wafer market has contracted from US$0.18~0.20/pc to
US$0.10/pc. Moreover, the average manufacturing cost difference between
mono- and multi-Si cells is now at US$ 0.015/W. These factors along with
higher conversion efficiency rates have resulted in mono-Si cells
reaching a dominant position in generation costs (see table 1).
Table 1: Cost and profit comparison between mono- and multi-Si cells
Source: EnergyTrend
Wafer and cell industries have each developed ways to solve LID.
Wafer manufacturers focus on reducing the boron-oxygen complex that is
the main contributor to LID. Aside from reducing the amount of oxygen in
the wafer, manufacturers can also change the dopant. For instance, they
can adopt gallium doping or boron and gallium co-doping. Meanwhile,
cell manufacturers have begun to add an annealing procedure in their
production. Among the equipment used for the annealing process,
Germany-based Centrotherm’s regenerator units are the most popular.
Recently, Taiwanese cell companies have implemented the annealing
procedure and found that LID in mono-Si PERC products have been
considerably reduced to within 2%. Wafer and cell companies nonetheless
still have a way to before their technological solutions achieve
maturity.
Policies and PERC will help accelerate mono-Si demand
Although mono-Si products have become as competitive as multi-Si
products in terms of C/P ratio, they require additional stimuli to win
larger market share. Currently, national renewable policies in major PV
markets are moving towards subsidy reduction. The U.K. and Japan for
instance are going to revise their feed-in tariffs (FiT), while the U.S.
will make a big cut to its investment tax credit (ITC) for PV systems.
These subsidy reductions increase major market’s reliance on DG systems.
China, the current leader in PV demand, continues to come up with new
subsidies for the DG market. Furthermore, the Chinese government also
initiates a new plan called the “Top Runner” program that is expected to
give a big boost to mono-Si demand.
The “Top Runner” program aims to raise the efficiency of Chinese PV
products by setting higher requirements for modules used in
demonstration projects and encouraging manufacturers to adopt these
standards. In this case, the minimum conversion efficiency rates set for
multi- and mono-Si modules are respectively at 16.5% and 17.5%. Based
on these rates, multi-Si modules would have to generate 270W to meet the
standard, whereas the required wattage for mono-Si modules would be
275W. Currently, it is relatively easy for mainstream mono-Si modules to
achieve the program’s target since their wattages are typically around
270~275W. On the other hand, the wattage of multi-Si modules is
generally around 260W. To comply with the standard, multi-Si products
will have to rely on technologies such as PERC or reactive ion etching
(RIE).
Recently, the Chinese government has announced the implementation of
demonstration project in Datong City as part of the “Top Runner”
program. The project, which is located in the coal-mining subsidence
areas of the city, will have a total installed capacity of 3GW. The
first phase of this project will begin construction soon and is
scheduled for completion by the middle of next year. It is expected that
the “Top Runner” program and related projects such as this will raise
both the demand and profile of mono-Si products in 2016.
Figure 2: Distribution of production for multi- and mono-Si cells based on efficiency rates.
Source: EnergyTrend
Furthermore, EnergyTrend estimates that the global PERC capacity in
total will exceed 13GW in 2016. Since mono-Si cells achieve greater
efficiency improvement with the PERC technology, the global PERC
capacity for mono-Si products is projected to grow and reach 8GW. Many
cell manufacturers that have just installed PERC equipment may have to
undergo an adjustment period before going into mass production. However,
major companies such as JA Solar and SolarWorld will be able to
contribute greatly to the global PERC capacity along with
technologically matured Taiwanese cell companies.
Figure 3: PERC capacity distribution for multi- and mono-Si products worldwide and in Taiwan, 2015~2016
Source: EnergyTrend
Mono-Si market outlook for 2016
Cost is the fundamental factor to staying competitive in the PV
market compared with other aspects such as technological advances,
conversion efficiency and supporting policies. Therefore, whether
mono-Si wafers can maintain their recently achieved US$0.10/pc price
difference with the less costly multi-Si wafers will be crucial to
market share growth of mono-Si products in 2016. As mentioned above,
projected global mono-Si demand will be less than 10GW this year, but
global mono-Si wafer capacity has already reached 14GW this year. This
oversupply has led to a substantial price drop in the mono-Si wafer
market. Looking ahead to 2016, wafer manufacturers will be expanding
their mono-Si capacity as they are optimistic about the market
prospects. Major Chinese wafer suppliers that have confirmed to making
such plans are LONGi and Zhonghuan. Also, the leading multi-Si wafer
company GCL has announced that it will increase its mono-Si wafer
capacity to 1GW next year, marking an aggressive entry into this market.
In sum, EnergyTrend projects that the global mono-Si capacity will
surpass 17GW in 2016, with the annual growth rate exceeding 20%.
Figure 4: Global mono-Si wafer capacity, 2015~2016
Source: EnergyTrend
Nonetheless, oversupply will persist in the mono-Si wafer market next
year unless end market demand increases substantially. For N-type
mono-Si wafers, the supply and demand situation is more balanced because
the customer base for these products is concentrated and stable. The
market for P-type mono-Si wafers, by contrast, is already seeing a
severe supply glut. Furthermore, top-tier wafer suppliers will be
initially focusing on expanding their P-type mono-Si production next
year. EnergyTrend therefore expects that it will be difficult for P-type
mono-Si wafer prices to rebound above US$0.95/pc, so the price gap
between mono- and multi-Si wafers will stay narrow.
The mono-Si segment is projected to account for 18% of the global PV
demand in 2015. Besides building on this year’s results, the growth and
development in next year’s mono-Si market will be driven by the
following factors: the rise of the DG market, the low mono-Si wafer
prices, the increase in conversion efficiency, the emergence of
solutions to LID, and the maturation of PERC technology. Based on
EnergyTrend’s analysis, the share of the mono-Si segment in the global
PV demand for next year may grow to 25%, or 14.5GW out of the projected
total demand of 58GW.
http://pv.energytrend.com/research/Cost_and_Efficiency_Are_Keys_to_Mono_Si_M arket_Growth_in_2016.html
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