rhombic drive

Cut away diagram of a Rhombic Drive Beta Stirling Engine Design
Pink - Hot cylinder wall, Dark grey - Cold cylinder wall (with coolant inlet and outlet pipes in Yellow), Dark Green - Thermal insulation separating the two cylinder ends, Light Green - Displacer piston, Dark Blue - Power piston, Light Blue - Flywheels,
Not Shown: external heat-source, and external heat-sinks. In this design the Displacer piston is used without a regenerator.

The rhombic drive is a specific method of transferring mechanical energy, or work, used almost exclusively when a single cylinder is used for two separately oscillating pistons. A prime example of this use is on beta type-Stirling engines; the drive's complexity and tight tolerances causing a high cost of manufacture is a hurdle for the wide-spread usage of this drive.

In its simplest form, the drive utilizes a jointed rhomboid to convert linear work from a reciprocating piston to rotational work. The connecting rod of the piston is rigid as opposed to a normal reciprocating engine which directly connects the piston to the crankshaft with a flexible joint in the piston. Instead, the rod connects to one corner of a rhombus. When force is applied to the piston, it pushes down; at the same time, the outer corners of the rhomboid push out. They push on two cranks/flywheels which cause them to rotate, each in opposite directions. As the wheels rotate the rhombus progresses its change of shape from being flattened in the direction of the piston axis at top dead centre to being flattened in the perpendicular direction to the piston axis at bottom dead centre.

In the pictured example the left crank/flywheel turns clockwise and the right crank/flywheel anticlockwise. They turn at the same angular velocity and this can be reinforced by intermeshing them as gear wheels.

Another example of this type of rhomboid mechanism is in some types of car jack.

References

Mechanical Drives for Stirling Engines Dr. Siegfried "Zig" Herzog ,Assistant Professor of Mechanical Engineering, Penn State University at Mont Alto. 06/01/05 Accessed August 2007

Heat engine types/configurations using thermodynamic cycles (Power cycles)
Stroke number and stroke parting
Crower six stroke · Four-stroke cycle · One-stroke cycle · Scuderi Split Cycle Engine · Six stroke engine · Two-stroke cycle
Different work volume types (incl. Pistonless rotary engine)
Britalus Rotary Engine · Combustion chamber · Controlled Combustion Engine · Jet engine · Orbital engine · Piston engine · Quasiturbine · Rocket engine · Swing-piston engine · Toroidal engine · Trochilic engine · Tschudi engine · Twingle engine · Wankel engine
Different work volume ports and main forms of valves
Cylinder head porting · D slide valve · Four-stroke cycle engine valves · Manifold · Multi-valve · Piston valve · Poppet valve · Rocket engine nozzles · Sleeve valve
Different pistons layouts
Bourke engine · Delta engine · Double acting/differential cylinder · Opposed piston engine · Radial engine · Rotary engine · Single cylinder engine · Stelzer engine · Straight engine
Different main rotational motion mechanisms or arc to (or even almost) pistons back-and-forth.
Cam · Connecting rod · Coomber Rotary Engine [1] · Crank Substitute Engine [2] · Crankshaft · Evans linkage [3] · Parallel motion · Peaucellier-Lipkin linkage · Piston rod · QRMC Stirling/HydraLink [4] · Revolving Cylinder Engine [5] · Rhombic drive · Scotch yoke · Sector straight-line linkage [6] · Swashplate · Swashplate engine · Watt's linkage
One-way stop-and-go like rotational motion mechanisms to rotation.
Toroidal engine · Trochilic engine

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rhombic drive

rhombic drive

References

See also