Low-cost Windmill, multi-vane fan type
Construction details for a low cost windmill are presented. The windmill produces one horsepower in a wind of 6.4 metres/sec (14.3 mph), or two horsepower in a wind of 8.1 metres/sec (18.0 mph).
The windmill uses the rear axle and differential of a small car. Other parts are made from sheetmetal, pipe, steel ribbon, rod, angle iron, or channel, welded or bolted together, and wood.
No precision work or machining is required, and the design can be adapted to fit different materials or construction skills. The rotor blades feather automatically in high winds to prevent damage. A full-scale prototype has been built and tested successfully.
NOTE: The University of California, Dr. Bossel, W. Delameter and P. Miller retain proprietary rights to commercial exploitation of lnventions disclosed in the present report.
INTRODUCTION The VITA windmill (Fig. I1) is a complete aerodynamic and structural redesign of an earlier prototype designed, built and tested by W. Delameter and P. Miller under the supervision of H. Bossel of the Mechanical Engineering Department. The fullscale prototype proved the soundness of the rotor design, overloading control (blade feathering), and directional control (vane).
The VITA windmill consists of five major components: the transmission, the rotor with overloading control (feathering), the vane for directional control, the turntable (supporting rotor, transmission, and vane), and the platform and tower structure. The rotor is constructed from steel rod, support wires, and sheet metal blades hinged to the spokes. A simple spring-loaded mechanism allows the blades to feather in high winds or when overloaded. The mechanism is explained in Fig. I2.
The rotor center plate is bolted to the brake drum of the rear axle of a small car. The wheelbrake stops the rotor when it is not is use.
The other wheel is permanently locked, resulting in a transmission ratio of about 1:4 from the horizontal to the vertical. The rear axle is free to swivel about the vertical on a turntable.
A vane, which is set at a small angle to counteract the torque transmitted vertically, keeps the rotor pointing into the wind. The whole assembly is mounted on a small platform on a single-beam tower.
Detailed blueprints are not presented in this report, since the design will differ with the materials, parts, and skills the builder finds at his disposal. He should understand that most dimensions and details (except those stated explicitly) are not critical, and can be adapted to suit the needs. There are a few exceptions in particular.
First, number, shape, and angles of the blades should remain unchanged to obtain the specified performance. Second, the control spring should come close to the stated specifications in order to adequately protect the rotor from possible destruction. Third, vane area, vane arm from the vertical axis, and vane angle should remain as given in the report for the same rotor and transmission ratio.
More generally, the product (vane area) x (vane arm) x (vane angle) should remain constant, where the vane angle should always be less than about ten degrees. This product must remain proportional to the torque transmitted; i.e., it should be doubled if a transmission ratio of 1:2 instead of 1:4 is used for the same rotor.
A few possible modifications of the basic design might be of interest. Automobile rear axles offer a rather wide choice of transmission ratios depending on how they are mounted, and whether one wheel drum or the slip gears are locked or removed. This range is from approximately 1:4 from rotor to vertical shaft if the rotor is mounted on the wheel drum, to 4:1 if the rotor is mounted on the drive shaft side.
In the first case, a second rear axle and/or an automobile gear box could be used to further increase the rotational speed and drive a centrifugal pump, circular saw, electric generator, feed mill and the like.
In the second case, the slow rotation would permit driving directly a reciprocating pump, or other machninery requiring slow rotation. In that case, the torque in the vertical shaft cannot be counteracted by the aerodynamic torque of a vane of reasonable size and the rotor must either be mounted rigidly in the direction of prevailing winds, or turned manually and locked, or turned by a nonreversible control mechanism (which would greatly increase the complexity).
Manual turning should also be considered for the case of lower torque and higher shaft speed of rotation. It would eliminate the vane and simplify the central bearing problem, since less precision and some friction would be permitted. Specifications for a smaller 2 meter windmill, and suggestions for electric power generation are provided in the Appendix.
PERFORMANCE DATA
Performance at sea level
Windspeed
m/sec
4
6 8
10
km/h
14.4
21.6
28.8
36.0
mph
9.0
13.4
17.9
22.4
Rotor speed revolutions per 21.0 31.5 42.0 52.5 minute (rpm)
Rotor torque
mkgf
8.8
19.8
35.2
55.0
ft lb
63.6
143.2
255.0
398.0
Starting torgue
mkgf
15.3
34.5
61.4
96.0
ft lb
111.0
250.0
445.0
695.0
Power
mkgf/sec
18.1
61.1
145.0
283.0
kw
0.177
0.60
1.42
2.77
hp
0.24
.81
1.91
3.73
Altitude effects
Altitude
m
0 1000
2000
3000
4000
ft
0
3280
6560
9840
13,100
percentage reduction of power and torque % 0 9 18 26 33 (rotor rpm unaffected)
Feathering Information
For control spring of spring constant 1.5kgf/cm precompressed to 13.5 kgf:
Rotor braked: Blades begin to feather at a wind speed V of 6 m/sec.
Blades fully feathered at V = 10 m/sec.
Rotor running under load:
Blades begin to feather at V = 8 m/sec.
Blades fully feathered (and rotor stopped) at V = 12.5 m/sec.
Rotor running free:
Little or no feathering.
Rotor
speed will
increase with wind speed, and damage is likely.
Always brake
rotor when not running under load.
TOOLS
Protractor (to measure angles) Hack saw Welder (gas or electric) Sheet metal shears Steel drills (approximately 3 to 30 mm) Hammer Pliers Adjustable wrenches, or set of wrenches General Notes: All sheet metal, nuts, bolts, wires, nails should be gaivanized, if available. All nuts must be secured by using spring washers, lock washers, or a second nut tightened against the first.
CONVERSIONS
1 m = 100 cm = 1000 mm = 3.28 ft = 39.4 in
1 in = 25.4 mm
1 kgf = 2.2 lbf
1 m/sec = 3.6 km/h = 2.24 mph
1 kw = 1.34 hp
TRANSMISSION
The present design uses a rigid rear axle and differential (from a small car) with mechanical brakes. Other car axles can be used with corresponding modifications. If the wheels have hydraulic brakes, use the master brake cylinder and other components from the car brake system to build a rotor brake system. Lock permanently the wheel drum on which the vane is to be mounted, by either locking the brake completely and permanently, or by blocking the slip gear.
In most cars the rotational speed of the drive shaft will then be approximately four times higher than that of the rotor mounted on the wheel drum. The drive shaft and the two universal joints are used to transmit the rotor power to the driven machinery (see Fig. A1).
The drive shaft can be lengthened by using pipe of approximately 20 to 40 mm outer diameter. Note: Permit some axial motion of the drive shaft to allow for thermal expansion and use shear pin to prevent damage (see Fig. A2). 08p09b.gif (486x486)
Various possibilities of transmissions using a second automobile rear axle and/or automobile transmission are shown in Fig. A1. ROTOR Part number Quantity Remarks (see Figs. R1 - R7)
R1 1 Steel plate 0.5m x 0.5m, approximately 5 mm thick. For mounting on axle, drill same drill pattern as required for rear wheels (Fig. R1).
R2 1 Steel rod (same as for spokes), 4.35m long, approximately 6 to 8 mm diameter. Bend into circle of 1.39m outer diameter, weld ends together (Fig. R2)
R3 16 Round steel rods for spokes 1.87m long, approximately 6 to 8 mm diameter (Fig. R1).
R4 48 Washers to fit loosely on spokes, approximately 2-3mm thick, 30mm outer diameter. Note: washers can be square and home-made from sheet metal.
R5 16 Sheet metal strips approximately 50mm x 70mm 2-3mm thick.
Drill one centerhole to fit on spokes (R3) and three holes for wire (R10) and rigging wire (R13) (Fig. R1, Fig. R4).
R6 16 Galvanized sheet metal blades, made from 8 pieces 1.3m x 0.75m, approximately 0.5mm thick (Fig. R2).
R7 48 Sheet metal strips, approximately 50mm x 70mm; 1.5 - 2mm thick. Bend to shape shown (Fig. R2).
R8 16 Sheet metal strips, approximately 50mm x 50mm; same material as vanes (Fig. R2).
R9 16 Rubber strips, approximately 50mm x 100mm, made from side walls of used car tire Fig. R2).
R10 1 Steel wire or cable, 26m long, 2 - 3 mm diameter.
R11 1 Steel wire or cable, 6 m long, 2 - 3 mm diameter.
R12 8 Steel wire or cable, 2.5m long, 2 - 3 mm diameter.
R13 16 Steel wire or cable, 3 m long, 2 - 3 mm diameter.
Rivets or small nuts and bolts to fasten hinges and rubber strips on vane.
CONSTRUCTION OF ROTOR
Prepare parts (R1) - (R10).
Make the blade bending rig (Fig. R3).
Bend blades (R6) intocorrect shape (see Fig. R3).
Hint: Use rollers, or
bend by
hand over piece of pipe.
Take care that hinge line remains
straight.
Rivet or bolt hinges (R7) to vanes (Fig. R2).
Very important:
make sure hinges line up exactly.
Rivet or bolt rubber strips (R9) between blade (R6) and washer
plate (R8) (Fig. R2, Fig. R6).
Weld spokes (R3) to centerplate (R1) (Fig. R1).
Weld ring (R2) to spokes at correct (22.5 [degrees])
intervals (Fig. R1).
Weld 16 washers (R4) to intersections of ring (R2) and spokes
(R3) (Fig. R1, Fig. R5).
Slide one washer (R4) on each spoke. Grease spokes at hinge locations. Slide blades on spokes with the wider blade tip facing outward.
Very important: All blades must rotate freely. If this is not the case, adjust blade shape, spokes, or hinge locations.
Slide one washer (R4) on each spoke. Weld parts (R5) onto tips of spokes, giving about 1 mm play (blade movement in the direction of the spoke) (Fig. R1, Fig. R4).
Thread wire or cable (R10) through holes of parts (R5) and align spokes at 22.5 [degrees] intervals (Fig. R4).
After completing circle, stretch taut and connect both ends. CONTROL SHAFT Part number Quantity Remarks (See Figs. C1 - C3)
C1
1
Steel pipe, 25 to 30 mm outer diameter, 1.5m long.
C2
1
Inner diameter
same as outer diameter of part (C1).
Use piece of pipe (also
for C3, C4, C5).
Drill end plate for wheel
bolts (same drill pattern
as part (R1)).
C3
1
Inner diameter
same as part (C2). Plate has 16
evenly
spaced holes
for 16 support wires, and 2
holes for restraining rods
(C8).
C4
1
Similar to part
(C3), except plate has central
hole
and part slides
freely on part (C1).
8 evenly spaced holes for
8 control wires, and
2 holes for restraining
rods (C8).
C5
1
Part must slide
on part (C1).
C6
1
Compression
spring, approximately 330 mm long.
Spring constant must be
approximately 1.5 kgf/cm
(i.e.
a compression of 1 cm for a weight of 1.5 kg).
Note: Make spring from 4 mm steel wire according
to Fig. C2, if suitable spring cannot be found.
A
softer
spring can be used, but it must also
be precompressed to 13.5
[kg.sub.f]. Springs harder
than 2 kgf/cm should not
be used.
C7
2
Washers (if spring diameter is larger than the
outer diameter of parts
(C4) and (C5)). Size
depends on spring
diameter. Make out of sheet
metal approximately 2 mm
thick.
C8
2
Wire,
approximately 3 to 4 mm diameter, 400 mm long.
Bend during installation
(Fig. C3).
4 Cotter pins, bolts, or wire to secure parts (C3), (C4), C5) on shaft (C1). 4 small washers
CONSTRUCTION OF CONTROL SHAFT
Make parts (C1) - (C7).
Lubricate shaft with heavy grease at the location of parts
(C4) - (C7).
Mount all parts on shaft (C1) as shown.
Secure parts (C3) and (C4) by cotter pins, bolts, or wire.
Compress spring to a force of 13.5 kgf and secure part (C5)
by cotter pin, bolt, or wire at this location.
Install wires (C8) with washers as shown (Fig. C3).
Bend each
end to a loop.
Wires must stick out 130 mm when pulled. (These wires prevent blades from going over dead center.)
ROTOR ASSEMBLY
Lay center
plate (R1) of rotor on blocks to raise it
approximately 0.5 m from the ground.
(Side to which the spokes
are welded "up").
Temporarily bolt the control shaft in place
by two bolts through plates (C2) and (R1).
Make sure control
shaft is exactly vertical.
Connect
the 16
wires or cables (R13) to the 16 holes of
centerplate (C3).
Connect
the 8
wires or cables (R12) to the 8 holes of
control plate (C4).
Connect
the 16
wires from (C3) to the holes in (R5) at the
tips of the spokes (Fig. R4).
Tighten the wires (or cables) at each spoke until the spoke is horizontal, then fasten wire securely. Note: do this simultaneously at opposing sides of the rotor to avoid bending of the control shaft. Do not proceed to next step unless all spokes are horizontal while control shaft is exactly vertical.
With wire or rope tied to (C3) pull (C4) up against the cotter pin. Connect the 8 wires from (C4) to the rubber strips on every second blade (Fig. R6).
Adjust the wire length until the blade has the required angle (Figs. R3, R7), with the trailing edge of the blade tip 230 mm below the plane of the spokes (leading edge angle with that plane 42 [degrees] at the tip). Fasten wire securely.
Using wire or cable (R11), connect all rubber strips (R9) with each other (Figs. R6, R7).
Work in the direction shown, holding up every second blade in the correct position when connecting it. When the circle is completed, all blades must be at the same angle.
TURNTABLE
(See Figs. T1, T2)
T1
1
Frame welded
together from steel
channel,
approximately 50 to 80 mm wide.
Frame is
exactly square.
Note: Dimension
"D" (distance
of brackets (T2), wheel distance, and
outer diameter of circular track) depends on
location of leaf spring mounts on car axle.
T2
2
Brackets made from angle iron
(about 5 to 8 mm
wall thickness). Drill pattern
corresponds to
that of leaf spring mounts on car axle.
T3
8
Steel plate
approximately 4 to 10 mm
thick.
T4
1
Steel plates approximately 5 to 10 mm thick.
T5
4
Steel axles 20 to 30
mm diameter.
Thickwalled
pipe can be used.
T6
4
Use whatever can be
found.
Diameter of wheel
body (T6a) should not be less than 50 mm.
Rim
diameter (T6b) should be approximately 40 mm
greater than that of (T6a).
Prefer ball bearing,
or bronze bearing, but simple steel cylinder
(T6a) acceptable.
Grease cavity reconmended in
this case. Weld or bolt rim
(T6b) to (T6a).
T7
8
Spacers.
Pieces of pipe, or several washers.
T8
20
Washers (can be made
from sheet metal 1
- 2 mm
thick).
T9
1
Circular track.
Ribbon steel, approximately 30
mm wide, 5 to 10 mm thick. Bend
and weld together
to form ring of outer diameter "D".
Ring must be
exactly circular to avoid derailing of
turntable.
T10
8
Brackets made from
angle iron, or bent
(heat!)
ribbon steel approximately 5 to 8 mm thick.
8
Cotter pins, or wire
or nails.
Construction of Turntable and Track
Prepare wheel assembly (parts (T4) - (Tb)).
Make Sure wheels
rotate with little friction.
Weld frame (T1) together.
Weld brackets (T2) onto frame such that car axle is exactly
centered on the frame when mounted to the brackets (T2).
Weld part (T3) onto frame.
Bend and weld circular track (T9) and weld 8 brackets (T10)
to
its inside.
Lay
track on flat surface and make sure it has no
waves and is perfectly horizontal.
Clamp wheel assemblies lightly to frame, with wheel rims
facing
outward. Set frame
up on blocks on the circular track on a
flat
floor, with all wheels resting on the track.
Weld parts (T4) to
the frame, checking repeatedly that all wheels rest on
track.
Wheels should have axial play of approximately 1 mm.
Adjust by
adding or removing washers.
VANE
(See Figs. V1 - V4)
V1
1
Steel channel, approximately 50 to
80 mm wide,
3 to 5 mm wall
thickness, 1.10 m
long. Drill
two holes to fit two wheel bolts on the wheel
drum, and two holes for bolt supportinq brake
handle (V8).
V2
1
Angle iron, approximately 20 x 20 mm "L" shape,
2 to 3 mm wall, 3.30 m long.
V3
1
Angle iron, approximately 20 x 20
mm "L" shape,
2 to 3 mm wall, 2.50 m long.
V4
1
Angle iron, approximately 20 x
20 mm "L" shape,
2 to 3 mm wall, 2.60m long.
V5
1
Ribbon steel, approximately 20 to
30 mm wide,
2 to 3 mm thick, 1.30 m long.
V6
1
Galvanized sheet metal,
approximately 0.5 mm
thick, 2.60 m x 1.50 m.
V7
1
Clamp made frgm ribbon steel
approximately 30 to
40 mm wide, 2 to 4 mm thick. To
fit over car
axle.
Weld to part (V2).
Provide holes for
clamping bolt.
V8
1
Brake handle.
Ribbon steel, or angle iron,
approximately 20 to 40 mm wide, 2 to 4 mm thick,
400
mm long.
Hole for supporting bolt is to be
approximately 2 mm wider than bolt diameter.
V9
1
Brake handle stop.
Flat piece about 3 to 6 mm
thick. Weld to (V1).
V10
2
Support wires or cable,
approximately 2 to 3 mm
diameter, each 3 m long.
Rivets or small nuts and bolts to fasten sheet
metal to vane frame (wire could also be used).
FIGURE V2
Vane Construction
Prepare parts (V1) - (V10).
Bend (V2) 10 degrees, to one side.
Weld (or bolt) together parts (V1) - (V5), (V7) and (V9).
Fasten sheet metal (V6) to vane frame using rivets, small
nuts
and bolts, or wire no more than 300 mm apart.
Connect brake handle (V8) to channel (VI) (Fig. V3).
Note:
Hole in (VB) must be large enough to permit handle to be
lifted
over the stop (V9).
Connect wires (V10) to points "A" and
"B".
PLATFORM AND TOWER
(See Figs. P1, P2)
P1
1
Beam or pole, 6 to 12 m long,
approximately
10 cm x 15 cm, or 15 - 20 cm diameter.
Shape upper end to 10 cm x 15 cm.
P2
1
Platform:
Thick plywood, or thick boards.
Cut out 15 cm x 15 cm central hole.
Note:
diameter of platform depends on diameter of
track (dimension "D").
P3
1
Galvanized sheet metal cover,
somewhat larger
than platform.
P4
1
Beam, approximately 4 cm x 8 cm.
P5
2
Beam, approximately 4 cm x 8 cm.
P6
2
Beam, approximately 4 cm x 8 cm.
P7
1
Piece, approximately 4 cm x 8 cm.
P8
2
Beam, approximately 4 cm x 8 cm.
P9
2
Beam, approximately 4 cm x 8 cm.
P10 10 -
20 Steps,
approximately 4 cm x 8
cm x 35 cm.
Nails approximately 10 cm long (galvanized, if
available).
Nails approximately 4 cm long (galvanized, if
available).
Construction of Platform and Tower
Build platform from parts (P2),(P4) - (P7), with a 15 cm x
15 cm
centerhole.
Shape upper end of tower beam so it fits into the space
between
(P4), (P5), and centerhole.
Nail platform to tower using parts (P8) and (P9).
(Reinforce joints by nailing strips of sheet metal over them
with 4 cm nails).
Cover top of platform with sheetmetal and nail it down on
the
platform and over the sides.
Mount circular track (use nuts and bolts) so that its center
coincides with the center of the square hole.
Check roundness
of the circle.
Nail steps to tower beam approximately 30 cm apart.
WINDMILL ASSEMBLY
The best way to assemble the windmill will depend on local conditions, and on labour, cranes, ladders, scaffolds available. The steps in the assembly should be well thought through before-hand, and all assistants should be fully familiar with the planned procedure. The windmill should be erected on a calm day. The following is one possible assembly procedure. Soak tower structure in creosote for a day, in particular the lower part which goes into the ground.
If creosote is not available, burn the outside of the lower part to a depth of approximately 1/2 cm. Dig a hole approximately 20% of tower height deep (less in rocky soil, more in sandy soil). Place tower vertically in hole, and fill hole with rocks and/or concrete, compacting thoroughly and repeatedly in the process.
It is recommended that the tower be anchored also by at least 3 cables (mount at a low enough position on the tower so that they do not interfere with the rotor). Mount the turntable on the circular track, and secure turntable to tower by wire or rope (temporarily but very rigidly). Grease all sliding or rotating parts, and fill differential 1/3 full with heavy oil or light grease. Rustproof all metal parts (except aluminum or galvanized) by protective paint. Mount car axle (drive shaft removed) on turntable.
Mount vane on one side of axle and connect the two wires or cables (V10) firmly from the vane (points "A" and "B") to part (T3) on the turntable. Connect a cable from the wheel brake lever on the rotor side to the brake handle (V8) on the vane. Use wire or cable loops fixed to the drum or other means to achieve the necessary 90 degree change in cable direction (Fig. V4).
Adjust the cable length so that rotor wheel is completely braked
when handle (V8) has
been
pulled down to rest against stop (V9).
Pull the brake handle,
braking the rotor wheel.
Remove the
temporary wires holding parts (C3) and (C4) of
the control shaft together.
Raise the rotor assembly.
Remove the
two temporary bolts holding parts (C2) and (R1) together
(but
keep control shaft in position).
Bolt control shaft (C2) and
rotor (R1) to the axle, tightening wheel bolts well.
Remove
restraining wires cautiously from the turntable,
watching for imbalance.
If rotor appears much heavier than vane
assembly, secure heavy rocks or pieces of scrap metal on the
vane
side of the turntable.
Release
brake,
and rotate rotor slowly, watching spoke
and blade alignment.
Make corrections where required.
Pull
brake.
Connect
drive
shaft and load.
Run
windmill
cautiously at first, checking for vibration,
loose parts, misalignment etc., and making immediate
adjustments.
MAINTENANCE AND OPERATION
#Grease or oil all sliding or rotating parts monthly. Add oil to differential. Check for loose components. Always repair immediately, if breakages or misalignments occur. Rustproof all metal parts (except galvanized or aluminum parts) once a year. Remove rust and chipped paint by wire brush, and scraper, then paint with protective paint. In some climates, new rigging wires may be required yearly. Always brake rotor fully when windmill is unloaded or not in use. If rotor blades feather at wind speeds considered too low, increase the precompression in the control spring. If rotor blades feather at wind speeds considered too high, decrease the precompression in the control spring.
SPECIFICATIONS FOR A 2-METER WINDMILL
Construction essentially identical to that of 4 m VITA windmill, except that dimensions are to be adjusted accordingly. Listed below are the major changes; other secondary changes will be obvious to the builder.
PERFORMANCE DATA
Compared to the data for the 4 meter windsmill:
rotor speed
becomes twice that for the 4 meter windmill
rotor
torque becomes one eighth (1/8) that for the 4 meter
windmill
starting
torque becomes one eighth (1/8) that for the 4
meter
windmill
power
becomes one fourth (1/4) that for the 4 meter
windmill,
altitude
effects remain the same
Feathering Information
Remains the same for control spring of spring constant 0.75
kgf/cm
precompressed to 3.5 kgf.
Fig. I1 - Rotor diameter becomes 2 m.
Control shaft becomes half as long, vane becomes half as long and half as high. Fig. A1 - All speeds of revolution become twice that shown.
VANE
Reduce height of vane to one half (approximately 0.75 m at
tail).
Reduce length of vane to one half (approximately 1.3 m).
No change in vane angle (10 [degrees]).
ROTOR
Outer diameter of ring (R2) becomes 0.69 m (length of rod 2.18m). Length of spokes (R3) becomes 0.87 m. Blades (R6) made from 8 pieces 0.65 m x 0.4 m.
New dimensions: FIGURE A
Blade bending rig for 2 m rotor (see new Fig. R3/2) has same angles as before, but all major linear dimensions are reduced to one half.
CONTROL SHAFT
Length of control shaft (C1) reduced to one half (0.75 m). Compression spring (C6) changed to 169 mm long. Spring constant 0.75 [kg.sub.f]/cm (i.e. a compression of 1 cm for a weight of 0.75 kg). If suitable spring cannot be found, make spring of same dimensions as for 4 m rotar, except use 3 mm steel wire. Control spring precompression changed to 3.5 [kg.sub.f]. Change indicated length of wires (C8) from 130 mm to 65 mm. (Fig. C3).
Suggestion for Electric Power Generation Using VITA 2 meter Windmill FIGURE B
(*) depends on alternator used Suggestion for Electric Power Generation Using VITA 4 meter Windmill FIGURE C
BIBLIOGRAPHY
Energy, Volume 7, Wind Power, United Nations Publication Sales No: 63.I.41, New York, 1964. W. Delameter, R. Sprankle, Park H. Miller III, Windmill and Waterpump for Developing Nations. Mechanical Engineering Dept., University of California, Santa Barbara, Calif., June 1969.