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8/2/2019 Generators Test
1/19
PR-98-05-I
Performance of two permanent magnet generatorsFor use with small windchargers
Gerrit Jacobs
Arrakis
Formerly
REDRenewable Energy Development vof
Eindhoven, the Netherlands
October 1998
Arrakis/REDRenewable Energy DevelopmentvofDe Olieslager 7- 5506ER VeldhovenThe NetherlandsTel: +31(40) 2819454E-mail: [email protected]
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Summary
The non-governmental organisation CESADE (Centro de Estudios y Accin para el Desarrollo) inNicaragua is determined to provide affordable electricity for the low income group. With AMEC(Aerobombas de Mecate) it has developed a small windcharger for charging 12 V batteries. One ofthe bottlenecks is the lack of a small (approximately 100W) generator that is affordable
(approximately US$ 50) and reliable. Results of the tests on two small DC permanent magnet generators that may be suitable are
described: a Bosch generator and an Omni Instruments generator. The rotational speed of the Omni Instruments generator has to be over 5500 RPM to reach an output
voltage of 12V. Therefore the generator is not suitable to charge a 12 V battery with the AMECwindrotor, in an unmodified state.
Without modifications, the Bosch generator is capable of charging a 12 V battery, startingat rotational speeds of approximately 900 RPM. At approximate 2200 RPM the generatorcan deliver 50 W which is more or less the maximum power that can be generated withoutoverheating when charging a battery, because of the small diameter of the wires. Themaximum efficiency that can be reached with this generator is approximately 65% at
rotational speeds of over 3500 RPM. A generator model has been developed which may be used with permanent magnet DC
generators in general. Using the model, generator performance can be determined with aminimum of measurements. The model is also useful for matching the generator with thewindrotor.
I am very grat ef ul t o Henk Holt slag of Cent ro de Estudios y Accin para el Desar rollo(CESADE),
J ohan van Doorn, Ton Marinburg, , Wim Thir ion, Jan van der Veen en Mar ij n Uyt de Wil legen of
t he Depar t men of Elect r ical Engineer ing: Group Elect romechanicsand Power Elect ronicsof t he
Eindhoven Universit y of Technology, Adr iaan Kragt en of Kragt en Design, J an de J ongh and Remi
Rij s, of Renewable Energy Development vof (RED) and Paul Smulder s f or t heir valuable suggest ions
and assist ance given.
t
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Contents
SUMMARY................................................................ ........................................................... ................................. 2
1. INTRODUCTION...... ........................................................... .............................................................. ............. 4
2. DESCRIPTION OF THE GENERATORS.................................................................................................... 5
2.1 BOSCH GENERATOR ..................................................... ........................................................... ....................... 52.2 OMNI INSTRUMENTS GENERATOR .................................................... ........................................................... ... 5
3. GENERATOR PERFORMANCE.............................. ........................................................... ......................... 6
3.1 OPTIMISATION OF THE GENERATOR ........................................................... .................................................... 63.2 LOSSES .................................................... ........................................................... ........................................... 6
4. THEORY.......................................................................... ......................................................... ........................ 7
4.1 PERMANENT MAGNET DC GENERATOR MODEL................................................... ........................................... 74.2 REFINEMENT OF THE MODEL............................................................ ........................................................... ... 7
5. MEASUREMENTS.............................................. ................................................................ ............................ 9
5.1 METHODOLOGY........................................................... ........................................................... ....................... 95.2 CALIBRATION OF RPM MEASUREMENT ..................................................... .................................................... 9
6. BOSCH GENERATOR TEST RESULTS....................................................... ............................................ 10
6.1 INTERNAL RESISTANCE .......................................................... ........................................................... ........... 106.2 LOAD RESISTANCE ....................................................... ........................................................... ..................... 106.3 MAGNETIC FLUX CONSTANT ............................................................ ........................................................... . 106.4 GENERATOR VOLTAGE........................................................... ........................................................... ........... 116.5 GENERATOR CURRENT........................................................... ........................................................... ........... 11
6.6 GENERATOR ELECTRICAL POWER .................................................... ........................................................... . 116.7 GENERATOR TORQUE................................................... ........................................................... ..................... 126.8 GENERATOR EFFICIENCY ....................................................... ........................................................... ........... 12
7. OMNI INSTRUMENTS GENERATOR TEST RESULTS............................................................ ............ 13
7.1 INTERNAL RESISTANCE .......................................................... ........................................................... ........... 137.2 LOAD RESISTANCE ....................................................... ........................................................... ..................... 137.3 MAGNETIC FLUX CONSTANT ............................................................ ........................................................... . 137.4 GENERATOR VOLTAGE........................................................... ........................................................... ........... 147.5 GENERATOR CURRENT........................................................... ........................................................... ........... 147.6 GENERATOR ELECTRICAL POWER .................................................... ........................................................... . 147.7GENERATOR TORQUE.................................................... ........................................................... ..................... 157.8GENERATOR EFFICIENCY ........................................................ ........................................................... ........... 15
8. MATCHING OF THE WINDROTOR AND GENERATOR ................................................................. ... 16
9. CONCLUSIONS AND RECOMMENDATIONS.......................................................... .............................. 17
9.1CONCLUSIONS .................................................... ........................................................... ............................... 179.2 RECOMMENDATIONS ................................................... ........................................................... ..................... 17
BIBLIOGRAFY....................................................................................................... ............................................ 18
APPENDIX 1 CALCULATION OF THE EFFICIENCY....... ..................................................................... . 19
APPENDIX 2 CALIBRATION OF THE RPM MEASUREMENT............................................................ . 19
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1. Introduction
The non-governmental organisation CESADE (Centro de Estudios y Accin para el Desarrollo) fromNicaragua is determined to provide affordable electricity for the low income group. Existing 50 Wpsolar home systems (SHS) cost about US$ 600 in Nicaragua. It is felt that there is a market for smallwindchargers when they are cost effective, compared to SHS's. The cheapest commercial small
windcharger that is available costs US$ 700. Therefore two prototype windchargers have beendeveloped locally by AMEC (Aerobombas de Mecate) with assistance from Mr. Henk Holtslag ofCESADE. Tests indicate that design and performance are promising [1]. However, a bottleneck is theavailability of a small generator and therefore CESADE, through Mr. Henk Holtslag, has askedRenewable Energy Development vof(RED) to test two small DC permanent magnet generators thatmay be used with the AMEC windcharger. The results of the tests are described in this report. Only atechnical analysis is given here. A financial comparison between a small wind charging system and aSHS is given in [1].
The figure below shows a picture of the type of the AMEC windcharger that is meant to be used with thegenerator. The generator is mounted at the bottom of the round rim. The rotor diameter is approximately 2m. A detailed technical description of the system is given in [1].
(Photo: Remi Rijs)
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2. Description of the generators
The design philosophy of AMEC is not to develop a windcharger that has a maximum energyefficiency but a machine which is cheap (competitive to SHS's) and suitable for local production. Forthe generator this leads to the following criteria: maximum power output of approximately 100 W,
capable of charging a 12 V battery at a maximum rotational speed of 1500-2000 RPM(depending on the type of transmission that is used),
sealed construction, low maintenance and a long life, cost of approximately $US 50.-.It is difficult if not impossible- to buy a generator off the shelve that has the above characteristics. Twogenerators were identified by CESADE that might be suitable: a Bosch and an Omni Instrumentgenerator.
2.1 Bosch generatorThe generator is manufactured byAmerican Bosch and has thespecification: 8(?)078524M030MM.41080 110V CCW. The nominalvoltage is 110 V DC at 10.000 RPM.It has two permanent magnets in thestator and 16 poles in the rotor. Thediameter of the coil wires is 0.3 mm.The diameter of the shaft is 12 mmwith on one side a ball bearing and onthe other side a brass bush. It has acommutator with brushes.
2.2 Omni Instruments generatorThe figure shows the dismantled OmniInstruments generator with the rotor onthe right and the stator housing withthe magnets at the back. Originally thegenerator has been designed fordriving an electric bicycle but nofurther information is available form
the manufacturer (Omni InstrumentsUSA, 133 Novak Drive Petaluma,California). It is a 12 VDC permanentmagnet type with 16 poles in the rotorand 4 permanent magnets in the stator.
(Photo: Remi Rijs)
The generator has a commutator with brushes. The shaft diameter of the generator is 8.0 mm and thecopper wire in the coil has a diameter of 0.7 mm. There is a combination numbers and letters is printed onthe casing: SHI(?)I(?)T2B, 30/97DE, 6002626, 12V.
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3. Generator performance
3.1 Optimisation of the generatorIn its simplest form, a generator is a coil of wire, passing through a magnetic field. By the process analternating voltage is induced, of which its magnitude depends on the length of the coil, the number ofturns in the coil, the flux density of the magnetic field and how rapidly the coil passes through themagnetic field (the effective rate of change of the magnetic field flux through the coil). Two differentmethods are used to change alternating current (AC) into direct current (DC): by using a commutator andbrushes (in a DC generator), and using diodes (in an alternator).To be able to charge a car battery, the DC voltage generated should be higher than the sum of the batteryvoltage and the voltage drop over the blocking diode, in case of a generator. If a generator does not satisfythis condition at rotational speeds that can be provided by a windmill, it can be modified. In redesigningthe generator for higher voltage output, there are a number of parameters that should be taken intoconsideration [8]. These include: the number of poles, the magnetic flux density of the field, the number of turns in the coils,
the maximum current through the commutator and the resistance of the wire, the space available in the armature for the coils.
Since it is not easy to change either the number of poles or the magnetic flux density of the field of anexisting generator, attention is given to the remaining points.
3.2 LossesThere are several reasons why the efficiency of a generator is lower than 100%. These include:electrical losses: heat generated in the coils (I2R losses), hysteresis losses in the iron of the armature, eddy current losses,
voltage drop over the commutator (brushes and the commutator segments),and mechanical losses: pressure of the brushes on the commutator causes friction, friction in the bearings.The voltage induced in a coil of wire passing through a magnetic field is proportional to the number ofturns in the coil. However, increasing the number of turns is limited by the available space. With a givenspace, decreasing the diameter of the wire can increase the number of turns. This will also increase theresistance of the wire. Apart from the I2R losses in the coil, not much can be done about the mentionedlosses in an existing generator. The generator voltage is proportional to the number of turns of the coil,whereas the maximum generator current is inversely proportional to the number of turns, given a fixedspace available. Therefore the generator resistance is proportional to the number of turns squared and as aresult the I2R losses in the coil will not change at a given power. However, I2R losses in the wires betweenthe generator and the battery will increase with increasing current.There is a trade-off between the rotational speed, voltage, current and efficiency of the generator. Thecharacteristics of the generator (and also of the windmill and battery) and the relationship between theparameters have to be known to be able to optimise a generator for use in a windcharger. In the followingparagraph some theory is given, followed by a discussion on how the generator characteristics have beenobtained and what the results of the measurements are.
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4. Theory
4.1 Permanent magnet DC generator modelThe generator can be considered as an ideal generator withan internal resistance in series as illustrated in the figure.
The torque Tand rotational speed are input parameters.
The currentIand the voltage Uare output parameters. Theexternal resistance is noted as RuAccording to Faraday, the generated voltage is a linearfunction of the rotational speed (1) and according toLorentz, the generated torque is proportional to thecurrent (2):
U .m (1) T . m
I (2)
In which mis a constant which is proportional to the magnetic flux (m in Vs or Wb).The voltage U that is supplied at the generator clamps is equal to the voltage generated minus the
voltage drop over the internal resistance, which is also equal to the generated current times externalresistance:
U .m .I R
i and also:U .I R
u (3)
The torque required to drive the generator is equal to Tg plus the torque required to overcome losses(T0).
T T T0 substituting Tg: T
.m
I T0 (4)
The efficiency is defined as the ratio of electric power generated and mechanical power required:
P
el
Pmec
.U I
.T T0
(5)
The losses L can be calculated as the sum of the power due to the lost torque and heat generated due to
the internal resistance of the generator:
L .T0 .I
2R
i(6)
4.2 Refinement of the modelThe model previously described has been verified with the measurements of the Bosch generator. It was
found necessary to refine the model when describing the Omni Instruments generator because this
generator operates at a much lower voltage. Brush voltage and torque losses are introduced in the revised
model.
Brush voltage
A brush voltage Ub is introduced which has the opposite sign as Ug. Formula 1 changes into:
Ug
.m U
b (7)
The value that has been used for Ub is 0.1 V.
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Torque losses
From the graph: torque versus rotational speed at zero load (chapters 6.7 and 7.7), it can be observedthat the torque depends on the rotational speed.This dependency was introduced in the model for the Omni Instruments generator as:
T0
C1
.C2
The torque T0 can be determined by measuring the torque as a function of the rotational speed at opencircuit (I= 0 A).
In appendix 1 it is shown how the efficiency can be written as a function of the rotational speed andvoltage respectively, using the above equations.
Using the model, the characteristics of a DC permanent magnet generator can be determinedaccurately with a minimum of measurements. For instance, using a spring balance, a multimeter andRPM counter, the efficiency of a generator can be determined.
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5. Measurements
5.1 MethodologyTests of the generator have been carried outin the laboratory of the Department ofElectrical Engineering, Group Electro-
mechanics and Power Electronics of theEindhoven University of Technology. Thegenerator (at the bottom of the picture) isclamped-in between wooden blocks and isconnected to a brakedynamo (shown on theleft). The brakedynamo is mounted freely, sothat the generated torque can be measured.The maximum rotational speed of thebrakedynamo is 4000 RPM. Torque iscalculated using the product of distance andforce. Force is calculated from weight, whichis measured with a scale with a resolution of1 g. This results in a torque resolution of0.003 Nm.For determining the characteristics of thegenerator, torque, voltage, current androtational speeds have been measured, using arheostat as a load.
5.2 Calibration of RPM measurementFirst the tachometer of the dynamo was calibrated with a handheld tachometer (Shimpo DT205). Thecalibration graph is given in Appendix 2. The RPM of the brakedynamo can be calculated using:RPM=33.8+19.35*Vdyn. The calibration was made without any load connected to the brakedynamo. Itwas found that when a load is connected to the brakedynamo there is an over-estimation of therotational speed of not more than 2%.
In the following chapter, first the results if the measurements on Bosch generator are discussed, followedby a discussion of the measurements on the Omni Instruments generator.
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6. Bosch generator test resultsFirst the values of the internal resistance (paragraph 6.1), load resistance (paragraph 6.2) and themagnetic flux constant (paragraph 6.3) are determined.
6.1 Internal resistanceThe internal resistance of the
generator was measured by varyingthe resistance of the rheostat andmaintaining the rotational speedconstant, using the circuit of figure 1,(p7) with an ammeter connected inthe circuit. This was done forrotational speeds of 595, 880 and1175 RPM. From the slopes of thegraphs it can be determined that theinternal resistance of the generator is
approximately 4.7 . The straight
lines have been determined by linearregression. It should be noted thatthis `dynamic internal resistance(impedance) is different from the`static internal resistance that ismeasured with an Ohm-meter.
0,0 0,5 1,0 1,5 2,0 2,5 3,0
0
2
4
6
8
10
12
14
16
18V = 16.68 - 4.77*I
V = 12.02 - 4.66*I
V = 7.85 - 4.77*I
V595
V880
V1175
Generatorvoltage(V)
Generator current (A)
0 2 4
0
5
10
15
20
25
30
35
V = 0.02 + 4.77*I
V = -0.05 + 1.30*I
V = 0.20 + 7.15*I
V = 0.15 + 10.04*I
V = 0.11 + 12.55*I
V = 0.1 + 14.91*I
V = 0.18 + 20.9*IVm1
Vm2
Vm3
Vm4
Vm5
Vm6
Vm7
GeneratorVoltage
(V)
Generator Current (A)
6.2 Load resistanceThe load resistance is the sum of theresistance of the rheostat and theinternal resistance of the ammeter. Ithas been determined by plotting
generator voltage versus generatorcurrent at different rotational speedswith the load resistance as parameterand calculating the slope of the graphusing linear regression. The values ofthe load resistances are:
Resistance () Label in all graphs1.30 .14.77 .27.15 .3
10.04 .412.55 .514.91 .620.90 .7
0,0 0,5 1,0 1,5 2,0 2,5 3,0 3,5 4,0 4,50,0
0,1
0,2
0,3
0,4
0,5
0,6
T = 0.046 + 0.1404*Im
T = 0.060 + 0.1328*Im
TN1TN2
TN3
TN4
TN5
TN6
TN7
GeneratorTorque(Nm)
Generator Current (A)
6.3 Magnetic flux constantAccording to formula (4), the magneticflux constant can be determined fromthe slope of the torque versus current
graph. The values of m and To thathave been used in the model are0.137 Vs and 0.053 Nm respec-tively.
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In the paragraphs 6.4 up to 6.8 the squares, circles and triangles represent measured data; the straightlines and curves have been determined using the generator model which is discussed in chapter 4.
6.4 Generator voltageThe figure shows the generatorvoltage as a function of rotational
speed with different loads. Thestraight lines have been obtained byusing formula (3), without correctionfor the brush voltage, and writing thecurrent I as a function of therotational speed (see appendix 1).
0 500 1000 1500 2000 2500 3000
0
5
10
15
20
25
30
35
40
45Vm1
Vm2
Vm3
Vm4
Vm5
Vm6
Vm7
Vm0
Generatorvoltage(V)
Rotational speed (RPM)
0 500 1000 1500 2000 2500 3000
0,0
0,5
1,0
1,5
2,0
2,5
3,0
3,5
4,0 Im1
Im2
Im3
Im4
Im5
Im6
Im7
Generatorcurrent(A)
Rotational speed (RPM)
6.5 Generator currentIndicated is the generator currentversus rotational speed at differentloads. The generator model has beenused to obtain the straight lines.
6.6 Generator electrical power
0 500 1000 1500 2000 2500 3000
0
20
40
60
80
Pmot2
Pmot7
Pmot1
Pmot2
Pmot3
Pmot4
Pmot5
Pmot6
Pmot7
GeneratedPower(W)
Rotational speed (RPM)
Since the electrical power is theproduct of voltage and current, thepower increments exponential with
the rotational speed. The generatedpower depends on the load: with Rinfinite, no current is flowing and
with R = 0 , no voltage is created,so that the generated power is equalto zero in both cases. The powerreaches a maximum if the loadresistance is equal to the internalresistance of the generator. Forclarity only two curves are shown butall curves calculated with the modelfit equally well with the measured
data.
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0 500 1000 1500 2000 2500 3000
0,0
0,1
0,2
0,3
0,4
0,5
0,6
0,7
TN1
TN2
TN3
TN4
TN5
TN6
TN7
TN0TN00
Torque(Nm)
Rotational speed (RPM)
6.7 Generator torqueThe torque is proportional to therotational speed and increases withincrementing loads (smaller externalresistance). The horizontal line (TN0)
corresponds to the torque withoutload (I = 0 A). First TN0 wasdetermined and later the torque withdifferent loads. After analysing theresults it became clear that the torquewithout load had decreased probablydue to the lubrication of the bearingsand settling of the brushes. Thereforethe torque without load was againmeasured (TN00, bottom line) withresults that better fit the model.
6.8 Generator efficiencyThe generator efficiency is calculatedusing formula (5) with the loadresistance as parameter. Thegenerator reaches a maximumefficiency of just over 65% atrotational speeds up to 3000 RPM.The model gives an overestimation ofthe efficiency at low rotationalspeeds because the brush voltage hasbeen ignored. Its presence becomesmost obvious at low RPM. Due to thehigh torque at no load, the efficiencydecreases rapidly at low rotationalspeeds of the generator.
Eff (%)
0 500 1000 1500 2000 2500 3000
0
10
20
30
40
50
60
Eff7Eff6Eff5Eff4
Eff3
Eff2
Eff1
Eff1
Eff2
Eff3
Eff4
Eff5Eff6Eff7
Rotational speed (RPM)
Using the generator model, theefficiency can also be calculated withthe battery voltage as parameter. Theresults are shown in the figure forbattery voltages of 12V (dashed line),
13 V (dotted line) and 14V (solidline). After the battery voltage isreached, the efficiency increasesrapidly and reaches a clearmaximum.
12
Eff (%)
Rotational speed (RPM)
500 1000 1500 2000 2500 3000 3500 40000
20
40
60
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13
0 2 4 6 8 10 12 14 16 18
0
1
2
3
4
5
V = 0.21 + 0 .100*I
V = 0.010 + 0.317*I
V = 0.156 + 0 .397*I
V = 0.30 + 0.48*I
V = 0.015 + 0.89*I
V = 0.016 + 1.41*I
Vm1
Vm2
Vm3
Vm4
Vm5
Vm6
GeneratorVoltage(V)
Generator Current (A)
7. Omni Instruments generator test results
Like in chapter 6, first the values of the internal resistance (paragraph 7.1), load resistance (paragraph7.2) and the magnetic flux constant (paragraph 7.3) are determined.
7.1 Internal resistance
0 2 4 6 8 10 12 14 16 18 20
0,0
0,5
1,0
1,5
2,0
2,5
3,0
3,5
4,0
4,5
5,0
5,5
6,0
V = 4.29 - 0.168*I
V = 3.21 - 0.168*IV = 2,06 - 0,159*I
V = 5.39 - 0.187*I
n=1000 RP M
n=1500 RP M
n=1970 RP M
n=2500 RP M
Generatorvoltage(V)
Generator current (A)
From the figure it can be determined(see paragraph 6.1) that the internalresistance of the generator is
approximately 0.17 . The straightlines have been determined by linearregression.
7.2 Load resistanceThe slopes of the graphs are ameasure of the load resistance andare determined using linearregression. The values of the loadresistances are:
Resistance () Label in all graphs
1.41 .10.89 .20.48 .30.397 .40.317 .50.100 .6
7.3 Magnetic flux constantIn theory the torque is independent from
rotational speed. In practice, the value ofmis best determined at high currents andlow rotational speeds because Todepends on the rotational speed.
0 5 10 15 20
0,00
0,05
0,10
0,15
0,20
0,25
0,30
0,35
0,40
T = 0.045+0.02*I
TN1
TN2TN3
TN4
TN5
TN6
GeneratorTorque(Nm)
Generator Current (A)
The values of m and To that havebeen used in the model are 0.02 Vsand 0.045 Nm respectively, which isindicated with the straight line in thegraph.
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In the paragraphs 7.4 up to 7.8 the squares, circles and triangles represent measured data; the straightlines and curves have been determined using the modified generator model which is discussed inchapter 4.
7.4 Generator voltage
0 500 1000 1500 2000 2500 3000 3500
0
1
2
3
4
5
Open circuit voltage
U = 0.00217*n
Vm1
Vm2Vm3
Vm4
Vm5
Vm6
LINE
GeneratorVoltage(V)
Rotational Speed (RPM)
The figure shows the generator
voltage as a function of rotationalspeed with different loads. Thestraight lines have been obtained byusing formula (3), modified with thebrush voltage Ub = 0.1 V, asdescribed in the theory and writingthe current I as a function of therotational speed (see appendix 1). Itcan be observed that the graphs donot pass through the origin as a resultofUb.
0 500 1000 1500 2000 2500 3000 3500
0
5
10
15
20Im1
Im2
Im3
Im4
Im5
Im6
Generatorcurrent(A)
Rotational speed (RPM)
7.5 Generator currentIndicated is the generator currentversus rotational speed at differentloads. Again the generator model hasbeen used to obtain the straight lines.
0 500 1000 1500 2000 2500 3000 3500
0
10
20
30
40
50
Pmot6
Pmot5
Pmot4
Pmot3
Pmot2
Pmot1
Pmot1
Pmot2
Pmot3Pmot4
Pmot5
Pmot6
GeneratorPower(W)
Rotational speed (RPM)
7.6 Generator electrical powerThe graph shows a low power outputat low rotational speeds and a goodconcordance of the model with themeasurements.
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0 500 1000 1500 2000 2500 3000 3500
0,0
0,1
0,2
0,3
0,4
T = 0.045 + 0.00001*n
TN1
TN2
TN3
TN4
TN5
TN6
TNIo
Torque(Nm)
Rotational speed (RPM)
7.7 Generator torqueThe line which is most horizontal(TNIo) gives the torque versusrotational speed at zero load (I = 0A). It should be noted that there is a
considerable torque required underzero load conditions, compared to thetorque when the generator is turning.This gives an indication of highlosses.
7.8 Generator efficiencyThe generator efficiency is calculatedusing formula (5). The generatorreaches a maximum efficiency of justover 50% at rotational speeds up to3500 RPM. The model gives a slightunderestimation of the efficiency,compared with the measured values,using m = 0.020 Vs. The curvewith the highest efficiency (circles)shows the results for Eff4 using m =
0.021 Vs, which gives a good match.This shows the importance ofdetermining the value of maccurately. Due to the high torque atlow RPM the efficiency decreasesrapidly at low rotational speeds of thegenerator. This is also observed withthe Bosch generator.
500 1000 1500 2000 2500 3000 3500
0
10
20
30
40
50
60 Eff 3 withm=0.0215 Vs instead of 0.02 Vs
Eff4
Eff3
Eff2
Eff5
Eff6
Eff1
Eff1
Eff2Eff3
Eff4Eff5Eff6
Eff (%)
Rotational speed (RPM)
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8. Matching of the windrotor and generator
Using the proposed generator model,the mechanical power which isrequired to drive the generator at aconstant voltage as a function of the
rotational speed, can be calculated.With the procedure which isdescribed in [4], the mechanicalpower of the rotor can be calculated.Combining the two procedures, thetransmission ratio between rotor andgenerator can be optimised. The resultof this procedure, using thecharacteristics of the AMEC rotor andBosch generator, is shown in thefigure on the right. Calculations of themechanical power which is generatedby the rotor at windspeeds of 2, 3, 4,5, 6, 7 and 8 m/s are shown. Also themechanical generator power and theelectrical power of the generator forbattery voltages of 12 V and 14 V isgiven. It can be observed that with atransmission ratio of 14, there is analmost perfect match between rotorand generator, considering the valuesof the parameters that are given at thetop of the graph. It should be noted
that the value of the transmissionefficiency is estimated. The values ofthe maximum power coefficient(Cpmax) and the design value for the
tip-speed ratio () taken from [1].
v = 6 m/s
v = 7 m/s
Pmech (of the rotor)at v= 8 m/s
Pelectrical
Vbat = 14 V
Vbat = 12 V
0 50 100 150 200 250 300
0
50
100
150
200
250
50
Rotational speed (RPM)
Power(W)
Example of matching the AMEC windrotor with theBosch generator
number of blades = 3 transmission ratio = 14 = 2.5 transmission efficiency = 0.85Cpmax = 0.22
Pmech (of the generator)
Vbat=12V Vbat=14V
0 2 4 6 80
20
40
60
Electrical power versus windspeed
Windspeed (m/s)
Generatorelectricalpower
(W)
Using the graph above, the generator output as a functionof the windspeed can be obtained. This is shown in thefigure on the right.It should be noted that this is only a rough estimationbased on parameters which are not precisely known. For abetter prediction of the electric output of the generator,
also the starting and furling behaviour have to be takeninto account.
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9. Conclusions and recommendations
9.1 Conclusions
ModelThe generator model shows a good correlation with the measured data. At low voltages the modifiedmodel has to be used, which takes the brush voltage and also the RPM dependency of the torque at zero
load into consideration. The magnetic flux m should be determined carefully since it determines mostcharacteristics of the generator and e.g. the relative error in the calculation of the efficiency is four times
the relative error in m. The model may be used with permanent magnet DC generators in general. Whenthe characteristics of the rotor are known, the model may be applied for determining the optimum matchbetween rotor and generator.
Bosh generatorWithout modifications the Bosch generator will be capable of charging a 12 V battery, starting atrotational speeds of approximately 900 RPM. At approximate 2200 RPM the generator can deliver 50W. Due to the small diameter of the wires (D = 0.3 mm) the generator gets hot when generating 50 W
and for sure the generator is not capable of generating 100 W for prolonged periods of time.The maximum efficiency that can be reached with this generator is approximately 65% at rotationalspeeds of over 3500 RPM.
Omni Instruments generatorThe rotational speed has to be over 5500 RPM to reach an output voltage of 12V. Therefore the generatoris not suitable to charge a battery using the AMEC windrotor and transmission, in an unmodified state.The maximum efficiency that can be obtained is 55%.
9.2 RecommendationsThe Bosch generator might be used with the AMEC windrotor without modifications. However thetransmission ratio has to be high (approximately 15) and the maximum power that can be generated islimited by the small diameter of the generator wire. It is estimated that the maximum power overprolonged periods of time is approximately 50 W (depending on ambient temperature, mounting of thegenerator, etc.).For future development, instead of rewinding the generator, improving the rotor design can be considered.The power coefficient of the rotor is low ( Cpmax = 0.22) and a lot can be gained by improving the bladedesign because with a higher Cpmax the rotor may produce the same mechanical power with a smallerdiameter. Keeping the design value of the tip-speed ratio constant, this results in higher RPMs so that asmaller transmission ratio is required, which improves the overall efficiency. An added advantage is thatthe cost of the rotor is reduced because less material is required.Handling generators
Preferably a generator should not be opened. If a generator has to be opened, this should be done on abench without any metal chippings because they are attracted to the permanent magnets and obstructits normal operation. The generator should not be hammered to loosen the bolts because this mightdiminish the magnetic field or brake the magnets. Care should be taken that the magnets to not turn inrespect to the commutator when assembling the generator. The tested Bosch and Omni Instrumentsgenerators are manufactured in the USA and require non-metric tools.
Care should be taken that the connecting wires do not brake. The generator shaft should not be welded on. The heat might deform it. Welding will lessen the
lubrication of the bearings and bushes and it might overheat the insulation of the coils.
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Bibliografy
[1] Rijs, R, Proyecto pequenos aerogeneradores CESADE-RED, RED Renewable Energy Developmentvof, Eindhoven July 1997.
[2] Hengeveld H.J., Lysen E.H., Paulissen L.M.M.,Matching of wind rotors to low power electricalgenerators, CWD 78-9, December 1978.
[3] Coolen J., Onderzoek naar de generatorkarakteristieken van een naafdynamo, gebruikt alsgenerator in een kleine windmolen, R 643 S/, Technische Natuurkunde, Technische UniversiteitEindhoven, Februari 1983 (in Dutch).
[4] Kragten A.,Aanpassing van windmolen en generator, KD 05, februari 1994. This publication canbe obtained from Kragten Design, Populierenlaan 51, 5492 SG St. Oedenrode, The Netherlands.
[5] Antec, Electrische fiets A1, Tel. 026 4458777, Amsterdamseweg 108, Arnhem, The Netherlands.[6] Elektro-Bikes in forscher fahrt, Internationaler Elektro-Bike test 1998, Mobil, Juli 1998, Germany.[7] ANWB Watersprotinformatie, Electrisch varen, ANWB, The Netherlands.[8] Sagrillo, M,Rewinding Generators/Aternators for Wind Systems, Homepower 9,
October/November 1990.
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Appendix 1 Calculation of the efficiency
U .m
.I Ri
Ub and
U .I Ru
.I Ru
.m .I R
iU
b.
m .I R
uR
iU
bI
.m U
b
Ru Ri
Pel
.I2R
uP
el.
.m U
b
Ru
Ri
2
Ru
Pmec
.T Pmec
..m
I T0
Pmec
..m
.m U
b
Ru
Ri
T0
P
el
Pmec
..
m U
b
Ru
Ri
2
Ru
..m
.m U
b
Ru
Ri
T0
.U I
..m
I T0
U .I Ri
Ub
m
It also can be shown that theefficiency
can be written as a functionof Iand U :
ormula (4)
and
Appendix 2 Calibration of the RPM measurement
0 20 40 60 80 100 120 140 160
0
500
1000
1500
2000
2500
3000
File: RPMCAL.ORG
Calibracion of RPM measurement
Y = A + B * X
Param Value
A 33 ,795
B 19,35
R = 0,99999Drivingmotorrevolutio
ns(RPM)
Voltage output of driving motor (V)