Rack and pinion drive system
of the ornithopter model EV7
1. Drive unit
The required input power for the drive motor calculated in 1986 for inclined climb was an average of 133 watts and a maximum of 211 watts during a flapping period.
2. Animation of the rack and pinion system
There was used a pin rack with a pitch of 6 mm. Corresponding chain drives are used at model cars. This rack moves up and down and drives the inner lever of the flapping wing.
The rotating pinion must be leaded along the black dotted line around the rack.
First the power flight must be switched on. To go back to gliding flight at any time a short click on the gliding flight button is enough. In the following round passing the lower dead point the motor will be reduced to half speed and gets switched off to gliding flight position.
3. Drive mechanism
The gas pressure spring for storing the aerodynamic upstroke energy and balance the lift forces is good to be seen. A pressure vessel with the valve of a bicycle is like the driving mechanism of the EV4. Also visible is the small cover for the steel spring at the final wing stroke positions. For the flow of energy in the springs please look at the handbook, chapter 1.5, 1.6 and 2.5, also 5.2 and 5.3.
The wing stroke was controlled by linkages over the 55 mm long lever arms of the wing adapter rollers.
3.1 Drawings of the driving mechanism
Longitudinal section drawing through the fuselage
with a view to the area of the drive mechanism. The drawing shows in particular the swing (Sch) in the side view with its built-in components. Furthermore is shown the location of the gear mechanism (AW, Z1, Z2) with its sprocket pinion (TR) in relation to the pin rack.
Top view to the swing
swing is a frame of plywood with attached components of the
drive. The frame is hanging on the levers like a swing.
Cross section through the fuselage at the linkages
of the wing adapter rollers. The lever (L) connected the swing (Sch) with the inner lever arm (F) of the wing adapter roller (W) or the wing. For reinforcing the fuselage on both sides are glued two carbon tubes (R). They are tapered fore and aft to the inner surface of the fuselage.
Cross section through the fuselage at the compensating spring
During gliding flight the lift affects an upward directed torque of the wing. The
compensating spring compensated or balanced
this torque on the inner lever arm of the wing. But the lift
during the upstroke is smaller and during the downstroke larger
than at gliding flight (please look at calculation tool
1). So, in flapping flight with a compensating spring
the motor must develop the difference of the torques between
gliding and flapping flight. But this difference is relatively
small. In this way the motor is less and relatively equally loaded
during the whole stroke cycle.
Furthermore, the compensating spring assists the adjustment and compliance of the glide position of the wing during the flight. Also, depending on the settings of the spring it enables to adjust different length of the upstroke cycle time and the downstroke cycle time. In addition, in it you can buffer the energy of the wing upstroke.
Here, the spring is designed as an inflatable or adjustable gas spring. It works with an average operating pressure of about 3.2 bar [320 kPa] and has an elastic force of 460 N. The maximum permissible pressure is 5 bar.
The rolling diaphragm (RM) is used as a seal between the piston (K) and the cylinder. It works with low friction and it is clearly visible in the adjacent drawing.
The pressure-vessel (D) I have made of fibreglass reinforced epoxy resin over a mould of candle wax (please take a look at the pencil drawings, PDF 160 KB).
Cross section through the fuselage at the spring for the final wing positions
This steel spring (AF) affects particularly to the mass of the wing via the inner wing lever. The maximum spring force is about 1000 N. First, it decelerates the incoming mass of the wing and accelerates it again in the opposite direction in the area of the upper and lower stroke position.
The shown construction enables to use only one pressure spring for both final stroke positions of the wing. But under certain conditions one can dispense with a spring in the lower final stroke position (please take a look at the functional description of the drive of the ornithopter model EV8).
spring for the final wing positions the motor
must spend two times the torque for the acceleration of the wing mass
at every wing beat. But this is associated with related energy loss. It
is more advantageous to enable the oscillation of the wing mass with the
aid of a spring.
3.2 Detail drawings of the pin rack drive
It is a rack bar with 6 steel pins assembled with rolls (of a roller chain with a pitch of 6 mm).