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An experimental study of the windmill of solar cell buckets
WREX 1996
AN
EXPERIMENTAL
STUDY OF THE WINDMILL OF SOLAR CELL BUCKETS Yoshihiro ONAI and Izumi USHIYAMA Ashikaga Institute of Technology 268-l Gmaecho, Ashikasga Cii, 326Japan
ABSTRACIIn order to demonstrate a complementary relationship between solar energy and wind energy, the authors proposed the WISH(Wiid and Solar Hybrid) type windmiU. The flexible amorphous photovoltaic modules are attached to the buckets of Savonius type windmill, After eight months operation of the WISH type windmiU in the field, we contirmed that there exists a complementary relationship between solar energy and wind energy. We also found that the power generation of this type of windmill was nearly twice as large as those without photovoltaic modules. KExwoRJls Savonius type windmill; Photovoltaic modules; Hybrid System Wmd Energy; Solar Energy, INTRODUCTION It is well known that solar energy and wind energy are the typical natural energy. Between these two energy sources may exist seasonal complementary relationship. Japan belongs to monsoon climate area therefore, the intensity of solar radiation is strong in summer and weak in winter. On the contrary, wind is strong in winter and weak in summer. Consequently, ifwe construct the generation system which comb&s these two energy sources, it is possible to acquire a stable energy throughout the year. The wind and solar hybrid systems currently in use consists of independent wind powered generators and photovoltaic modules. However, in this paper, the authors proposed an unique hybrid system which integrates the windmill and the photovoltaic modules. The windmiU celled Savonius type of which large buckets are attached by flexible amorphous photovoltaic modules. The system is named WISH: Wind and Solar Hybrid power system. The authors reported on the result of theoretical computation so far. (Morioka and Ushiyama, 1992) sYMBoJ..sANDuNrrs The main symbols and the units are as follows. A: swept area of the rotor [m’] OL: overlap ratio
H: rotor height [m]
D: rotor diameter [m]
GP: gap ratio
FXPERIMENTALAPPARATUSANDMETHOD The experimentalwidmili installed in the demonstration field is the Savonius rotor with two half cylinder section type. The configuration of the rotor is : rotor diameter D=O.67m rotor height H=1.4m, endplates diameter 0.80 and thickness of 6mrn respectively. Moreover, the swept area of the rotor A=0.94m2, gap ratio GP=QO7 and overleap ratio OL=O.52. The authors compared the ditTerence of generated output between the Savonius rotor generation systems with and without photovoltaic modules. (vshiyama and Nagai, 1988) 905
WREC 1996 The photovoltaic cell unit is flexible amorphous silicon solar module BC5422SO made by TDK corporation. Four sets of panels which consist of five sheets of above mentioned photovoltaic modules were attached to both sides of the windmill buckets. Figure 1 shows the schematic diagram of the author’s WISH type windmill
The specitication and the
characteristics of the flexible amorphous silicon solar module are shown in Fig. 2. The layout of experimental apparatus is shown in Fig. 3. The expetimental windmills were installed in the upper part of the concrete support of 5m height. The external appearance of the experimental windmills are shown in Photo. 1. The lower part of the windmills are connected with low-speed permanent magnet JX generator of 36W rated power through chain and sprocket of speed increasing ratio of 5. A slipring througb which to take out the electric power generated in photovoltaic modules is mounted on the top of the WISH type windmill. Moreover, as shown on Photo. 1, a Savonius type windmill without photovoltaic module on its buckets was also installed at the symmetrical posiion to the support The generation output by wind powered generators and photovoltaic module was charged into 12V storage battery At the same time, generated output by the wind powered generator and photovoltaic module is calculated through the operation of electric power unit, The measuring interval is 30 seconds. The data acquired were recorded into the personal computer through the datalogger at the measming room in the field. The anemometer and anemoscope were installed on the top of the support at 1Gmheight. The actinometer was mounted at the position of 2.7m height of the support.
_
630
<
panel bucket(FRl’) waterproof film solar
Fig. 1 The schematic 560 /electrode(+)
\
electrode+)
electrode(-)
\
electrode(-)
/
I
of the WISH type windmill
seal film
\ cell
TypeBCS5422SO Operating voltage
17w
Operating current
3001~1
Open voltage Short-circuit
current
WV1 3SO[mA]
Characterllltlc value IP25°C. AM, 5.
,com,cnl at “ETaCal
Photo. 1 The external appeamnce ofthe acperimental
Fig. 2 The specification and the characteristics of the
windmill
flexible amorphous silicon solar module 906
WREC 1996
&Se Fig. 3 The layout of experimental apparatus Wind direction, wind speed and solar radiation are measured siiultaneously with the output of wind energy and solar energy These data are recorded into the same personal computer through the datalogger. The saved data in the hard disk are copied to a floppy disk, and the data are processed both daily and monthly at the laboratory. IXPEREVIENTAL
RESULTS AND CONSIDERATIONS
A relationship between the wind speed and the solar radiation is shown in Fig. 4. It is clear from the figure, from around 11 o’clock to around 16 o’clock, the wind speed is weak and the solar radiation is strong. On the contrary, t?om around 17 o’clock to around 24 o’clock, the wind speed is strong and the solar radiation is weak. Thus, there may exists a complementary relationship. As mentioned above, there exists a seasonal relationship between the solar energy and wind energy. As shown in this figure, there also exists daily complementary relationship between them. Figure 5 shows a cumulative daily output data in the second halfof June 1995.
I .2
I6
The generated output by the Savonius wind rotors with and without solar modules are nearly the same values.
14
-Wtnd
However, the total generated output by WISH type windmill is nearly twice as large as the Savonius type wind rotor without solar module. Thus, the effectiveness of the
sixed
- - 12
I Solar radlatlon
t
WISH type power system is confirmed. The monthly cumulative output of WISH type power system is shown in Fig. 6. It is obvious from this figure that, Tom June to September, the wind energy is strong as the characteristic of summer season in Japan. Then, from October to January, the solar intensity became weak while the wind energy became strong as the typical feature of winter
0.2
season in Japan. As previously described, these are the seasonal
complementary
relationships between
energy and solar energy. Consequently,
wind
it may be
0 0
2
4
6
8
concluded that the WISH type power system tested in this experiment
could
acquire
the
average
power
of
907
12
I4
I6
18
20 22 Ttme(hour)
Fig. 4 A relationship between the wind speed and the solar radiation
1kwhmonth through the year.
IO
WREC 1996
OSavonius
-y$100
-WISH
e 5
80
2 '; 60 Cl
tyoe windmill tyoe windmill (Wind energy)
--WISH
type windmill (Solar energy)
-WISH
tyoe windmill (Wind energy + Solar energy)
.+! 40 z Ig 20 0 0 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 TimeCday)
Fig. 5 A cumulative daily output data in the second half of June 1995 1600
?? Solar energy
T 1400
@IWind energy
;: 1200 E \ 1000 g 2 2
800
;
400
600
2 u' 200 n
”
June
July
August
September
October
November
December
January
Fig. 6 The monthly cumulative output of WISH type power system CONCLUSIONS After eight months operation of the WISH type power system in the field the following conclusions were drawn. (1) It was clear that there exists seasonal and daily complementary relationship between wind energy and solar energy (2) The power output ofthe WISH type wind rotor is much larger than that without photovoltaic modules. (3) The WISH type power system could acquire the stable energy from the wind and solar energy through the year. ACKNOWLEDGMENT The authors wish to express their gratitude to The R & D Center
staffof TDK corporation.
They kindly provided us the
flexible amorphous silicon solar modules in manufacturing our WISH type power system. REFERENCES S. Morioka and I. Ushiyanq (1992) A Wmdmill of Solar cell Blades, Proceeding of The 2nh World Renewable Energy Congress, Vol. 3, 1507. I. Ushiyama and H. Nagai, (1988) Optimum Design Configurations and Performance of Savonius Rotors, Wind Engineering, Vol. 12, No. 1, 59. 908
AN
EXPERIMENTAL
STUDY OF THE WINDMILL OF SOLAR CELL BUCKETS Yoshihiro ONAI and Izumi USHIYAMA Ashikaga Institute of Technology 268-l Gmaecho, Ashikasga Cii, 326Japan
ABSTRACIIn order to demonstrate a complementary relationship between solar energy and wind energy, the authors proposed the WISH(Wiid and Solar Hybrid) type windmiU. The flexible amorphous photovoltaic modules are attached to the buckets of Savonius type windmill, After eight months operation of the WISH type windmiU in the field, we contirmed that there exists a complementary relationship between solar energy and wind energy. We also found that the power generation of this type of windmill was nearly twice as large as those without photovoltaic modules. KExwoRJls Savonius type windmill; Photovoltaic modules; Hybrid System Wmd Energy; Solar Energy, INTRODUCTION It is well known that solar energy and wind energy are the typical natural energy. Between these two energy sources may exist seasonal complementary relationship. Japan belongs to monsoon climate area therefore, the intensity of solar radiation is strong in summer and weak in winter. On the contrary, wind is strong in winter and weak in summer. Consequently, ifwe construct the generation system which comb&s these two energy sources, it is possible to acquire a stable energy throughout the year. The wind and solar hybrid systems currently in use consists of independent wind powered generators and photovoltaic modules. However, in this paper, the authors proposed an unique hybrid system which integrates the windmill and the photovoltaic modules. The windmiU celled Savonius type of which large buckets are attached by flexible amorphous photovoltaic modules. The system is named WISH: Wind and Solar Hybrid power system. The authors reported on the result of theoretical computation so far. (Morioka and Ushiyama, 1992) sYMBoJ..sANDuNrrs The main symbols and the units are as follows. A: swept area of the rotor [m’] OL: overlap ratio
H: rotor height [m]
D: rotor diameter [m]
GP: gap ratio
FXPERIMENTALAPPARATUSANDMETHOD The experimentalwidmili installed in the demonstration field is the Savonius rotor with two half cylinder section type. The configuration of the rotor is : rotor diameter D=O.67m rotor height H=1.4m, endplates diameter 0.80 and thickness of 6mrn respectively. Moreover, the swept area of the rotor A=0.94m2, gap ratio GP=QO7 and overleap ratio OL=O.52. The authors compared the ditTerence of generated output between the Savonius rotor generation systems with and without photovoltaic modules. (vshiyama and Nagai, 1988) 905
WREC 1996 The photovoltaic cell unit is flexible amorphous silicon solar module BC5422SO made by TDK corporation. Four sets of panels which consist of five sheets of above mentioned photovoltaic modules were attached to both sides of the windmill buckets. Figure 1 shows the schematic diagram of the author’s WISH type windmill
The specitication and the
characteristics of the flexible amorphous silicon solar module are shown in Fig. 2. The layout of experimental apparatus is shown in Fig. 3. The expetimental windmills were installed in the upper part of the concrete support of 5m height. The external appearance of the experimental windmills are shown in Photo. 1. The lower part of the windmills are connected with low-speed permanent magnet JX generator of 36W rated power through chain and sprocket of speed increasing ratio of 5. A slipring througb which to take out the electric power generated in photovoltaic modules is mounted on the top of the WISH type windmill. Moreover, as shown on Photo. 1, a Savonius type windmill without photovoltaic module on its buckets was also installed at the symmetrical posiion to the support The generation output by wind powered generators and photovoltaic module was charged into 12V storage battery At the same time, generated output by the wind powered generator and photovoltaic module is calculated through the operation of electric power unit, The measuring interval is 30 seconds. The data acquired were recorded into the personal computer through the datalogger at the measming room in the field. The anemometer and anemoscope were installed on the top of the support at 1Gmheight. The actinometer was mounted at the position of 2.7m height of the support.
_
630
<
panel bucket(FRl’) waterproof film solar
Fig. 1 The schematic 560 /electrode(+)
\
electrode+)
electrode(-)
\
electrode(-)
/
I
of the WISH type windmill
seal film
\ cell
TypeBCS5422SO Operating voltage
17w
Operating current
3001~1
Open voltage Short-circuit
current
WV1 3SO[mA]
Characterllltlc value IP25°C. AM, 5.
,com,cnl at “ETaCal
Photo. 1 The external appeamnce ofthe acperimental
Fig. 2 The specification and the characteristics of the
windmill
flexible amorphous silicon solar module 906
WREC 1996
&Se Fig. 3 The layout of experimental apparatus Wind direction, wind speed and solar radiation are measured siiultaneously with the output of wind energy and solar energy These data are recorded into the same personal computer through the datalogger. The saved data in the hard disk are copied to a floppy disk, and the data are processed both daily and monthly at the laboratory. IXPEREVIENTAL
RESULTS AND CONSIDERATIONS
A relationship between the wind speed and the solar radiation is shown in Fig. 4. It is clear from the figure, from around 11 o’clock to around 16 o’clock, the wind speed is weak and the solar radiation is strong. On the contrary, t?om around 17 o’clock to around 24 o’clock, the wind speed is strong and the solar radiation is weak. Thus, there may exists a complementary relationship. As mentioned above, there exists a seasonal relationship between the solar energy and wind energy. As shown in this figure, there also exists daily complementary relationship between them. Figure 5 shows a cumulative daily output data in the second halfof June 1995.
I .2
I6
The generated output by the Savonius wind rotors with and without solar modules are nearly the same values.
14
-Wtnd
However, the total generated output by WISH type windmill is nearly twice as large as the Savonius type wind rotor without solar module. Thus, the effectiveness of the
sixed
- - 12
I Solar radlatlon
t
WISH type power system is confirmed. The monthly cumulative output of WISH type power system is shown in Fig. 6. It is obvious from this figure that, Tom June to September, the wind energy is strong as the characteristic of summer season in Japan. Then, from October to January, the solar intensity became weak while the wind energy became strong as the typical feature of winter
0.2
season in Japan. As previously described, these are the seasonal
complementary
relationships between
energy and solar energy. Consequently,
wind
it may be
0 0
2
4
6
8
concluded that the WISH type power system tested in this experiment
could
acquire
the
average
power
of
907
12
I4
I6
18
20 22 Ttme(hour)
Fig. 4 A relationship between the wind speed and the solar radiation
1kwhmonth through the year.
IO
WREC 1996
OSavonius
-y$100
-WISH
e 5
80
2 '; 60 Cl
tyoe windmill tyoe windmill (Wind energy)
--WISH
type windmill (Solar energy)
-WISH
tyoe windmill (Wind energy + Solar energy)
.+! 40 z Ig 20 0 0 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 TimeCday)
Fig. 5 A cumulative daily output data in the second half of June 1995 1600
?? Solar energy
T 1400
@IWind energy
;: 1200 E \ 1000 g 2 2
800
;
400
600
2 u' 200 n
”
June
July
August
September
October
November
December
January
Fig. 6 The monthly cumulative output of WISH type power system CONCLUSIONS After eight months operation of the WISH type power system in the field the following conclusions were drawn. (1) It was clear that there exists seasonal and daily complementary relationship between wind energy and solar energy (2) The power output ofthe WISH type wind rotor is much larger than that without photovoltaic modules. (3) The WISH type power system could acquire the stable energy from the wind and solar energy through the year. ACKNOWLEDGMENT The authors wish to express their gratitude to The R & D Center
staffof TDK corporation.
They kindly provided us the
flexible amorphous silicon solar modules in manufacturing our WISH type power system. REFERENCES S. Morioka and I. Ushiyanq (1992) A Wmdmill of Solar cell Blades, Proceeding of The 2nh World Renewable Energy Congress, Vol. 3, 1507. I. Ushiyama and H. Nagai, (1988) Optimum Design Configurations and Performance of Savonius Rotors, Wind Engineering, Vol. 12, No. 1, 59. 908