This patent discloses one cylinder axial internal combustion engine having Scotch-Yoke based two phase fuel compression system. Scotch-Yoke actuator employed here is a specially modeled Multi Purpose Multi H-Slot double action Scotch-Yoke Actuator. Each H-slot is quad-laterally operated by a special mechanism. It performs suction and compression in ignition chamber and auxiliary compression chamber via two piston plates one in each chamber and transfers compressed fuel-air mixture from auxiliary compression chamber to ignition chamber through yoke rod. Flywheel is coaxially mounted on the outward side of the auxiliary compression chamber.

A motion conversion apparatus (400, 500) comprises at least one set including a rodrack assembly (110) between two gearshaft member end sections (155), and a gearshaft member mid section (156) between the two gearshaft member end sections (155). The rodrack assembly (110) comprises a first gear connection member (120) and two guide members (140). The gearshaft member mid section (156) comprises a second gear connection member (160) configured to engage with the first gear connection member (120). The two gearshaft member end sections (155) each comprise a guiding surface arrangement (170) configured to contact the two guide members (140). The rodrack assembly (110) is configured to provide rotation of the gearshaft member mid section (156) about a rotational axis (A) by reciprocating linear motion of the rodrack assembly (110) along a first spatial dimension (D1) orthogonal to the rotational axis (A), or vice versa.

A motion conversion apparatus (400, 500) comprises at least one set including a rodrack assembly (110) between two gearshaft member end sections (155), and a gearshaft member mid section (156) between the two gearshaft member end sections (155). The rodrack assembly (110) comprises a first gear connection member (120) and two guide members (140). The gearshaft member mid section (156) comprises a second gear connection member (160) configured to engage with the first gear connection member (120). The two gearshaft member end sections (155) each comprise a guiding surface arrangement (170) configured to contact the two guide members (140). The rodrack assembly (110) is configured to provide rotation of the gearshaft member mid section (156) about a rotational axis (A) by reciprocating linear motion of the rodrack assembly (110) along a first spatial dimension (D1) orthogonal to the rotational axis (A), or vice versa.

An apparatus for adjusting a length of a connecting rod of a cylinder of an internal combustion engine by installing and/or removing an intermediate plate between a connecting rod small end and a connecting rod shank of the connecting rod in the state of the connecting rod, with the following assemblies: a pivot guard for the connecting rod small end mountable to the connecting rod small end between the connecting rod small end and a cylinder liner of the cylinder; supports mountable to counterweights of the cylinder on opposite sides of the connecting rod; holders mountable to the supports and extend between the supports perpendicularly to the same; lifting cylinders mountable to the holders and lift the connecting rod small end relative to the connecting rod shank with unscrewed screw connections between connecting rod small end and connecting rod shank.

An apparatus for adjusting a length of a connecting rod of a cylinder of an internal combustion engine by installing and/or removing an intermediate plate between a connecting rod small end and a connecting rod shank of the connecting rod in the state of the connecting rod, with the following assemblies: a pivot guard for the connecting rod small end mountable to the connecting rod small end between the connecting rod small end and a cylinder liner of the cylinder; supports mountable to counterweights of the cylinder on opposite sides of the connecting rod; holders mountable to the supports and extend between the supports perpendicularly to the same; lifting cylinders mountable to the holders and lift the connecting rod small end relative to the connecting rod shank with unscrewed screw connections between connecting rod small end and connecting rod shank.

An improved internal combustion engine utilizes at least one orbital-epicycle crankpin eccentrically offset from an orbital shaft, rotationally linked to the main shaft via an orbital-epicyclic gear set, such that the piston and connecting rod, influenced by the force from the thermodynamic process, transfers a straight linear force to the orbital-epicyclic crankpin via a conventional connecting rod and the two-piece flying crank arm to the main shaft. The concept provides a simple way of adjusting or inverting the piston to crank relationship for a different engine application and fuel characteristics with a variety of (dwell duration) ECVC cycle durations to appear at TDC or BDC. Consider that; volume vs pressure/heat are in an opposed proportion!

A piston arrangement includes a piston movable within a cylinder in reciprocating motion along a piston axis, a rack movable with the piston, a sector gear configured to engage and disengage the rack and rotatable around a sector gear axis, a track adapted to rotate relative to the cylinder around a track axis of rotation, the piston being coupled to the track. The sector gear and the track are coupled in rotation. The track may have a shape such that the movement of the piston coupled to the track is substantially non simple harmonic. Also, an internal combustion engine comprising the piston arrangement.

A piston arrangement comprising: a piston; a rotatable element, rotatable about an axis, having a first engagement profile; and a mechanism comprising: a first connecting element connected to the piston; a second connecting element pivotable about a fixed point and pivotally connected to the first connecting element; and a second engagement profile coupled to the first and/or second connecting element, configured to mechanically engage and disengage with the first engagement profile of the rotatable element.

Highly efficient pressure differential rotary engines can include rotatable cylinders arranged radially around a central stationary shaft. Each of the cylinders can house one or more pistons, and the cylinders and pistons can rotate together about the central stationary shaft. Pressure differentials within the cylinders can be used to power the rotation of the cylinders about the central stationary shaft.

An Engine with Isochoric Combustion has pistons arranged within cylinders, connecting rods connected to the pistons and to upper joints of triangle links, and a crankshaft with crankpins offset from the centerline of the crankshaft by crank arms. The triangle links are connected to the crankpins at additional joints of the triangle links. Radius links are pivotally connected to the engine by pivot pins at one end and to the triangle links at a further joint of the triangle links at their other end. By way of geometry of the linkages defined by the crank arms, the triangle links, the radius links, and the connecting rods, and by way of the relative positions of the crankshaft, the cylinders, and the pivot pins, during a crank angle segment, the Cylinder Volume during the combustion event is characterized by an extended dwell.