Internal-combustion engines – Rotary – With compression volume means in uninterrupted communication...
Reexamination Certificate
2001-03-26
2002-11-19
Denion, Thomas (Department: 3748)
Internal-combustion engines
Rotary
With compression volume means in uninterrupted communication...
C123S246000, C123S232000, C418S206600, C418S206500
Reexamination Certificate
active
06481410
ABSTRACT:
TECHNICAL FIELD
This invention relates to apparatus that may be operated as an internal combustion or steam engine, a positive displacement device, or the like.
BACKGROUND ART
There are a number of problems with current piston engine designs which utilise reciprocating components.
In a standard piston engine around 10% of the energy from the fuel goes into accelerating and decelerating the pistons and valves, and friction may reduce available power by a further 2.5%. These are considerable power losses. There is also the problem that much of the energy of the fuel is dissipated down the exhaust pipe.
Concepts such as turbo-charging attempt to utilise this “waste” energy to increase power by increasing the compression. Improvements such as the Miller Cycle have improved efficiencies to some extent by creating an expansion volume which is greater than the compression volume
Another problem with piston engines is that much of the force transferred to the crankshaft is at angles less than the most efficient 90 degrees.
In other types of engines such as turbo fan jet engines efficiency is lower than ideal due to the low compression which can be achieved by using a fan rather than a closed displacement chamber.
Current vane type engines also have drawbacks with the complexity of gears and control of the vanes to maintain appropriate contact or sealing, and friction and wear problems due to the large swept area which requires some form of friction seal which causes losses and wear.
Rotary engines based on the Wankel concept have the advantage that moving parts orbit as opposed to reciprocating. The engines are generally lighter more compact and have fewer moving parts than piston engines.
Wankel concept engines have a fixed casing with an internal chamber of a wide-waisted figure of eight and at least one near-triangular rotor. The rotors revolve eccentrically within the casing in such a way that three rotor “tips” are continually in contact with the internal surface of the casing.
Planetary gearing connects the rotor to an output shaft which is equivalent to the crank shaft of a piston engine.
Between the three sides of the rotor and the insides of the casing, chambers are provided, each of which alternatively expands and contracts in size as the rotor orbits. The casing is provided with spark plugs, an inlet port and an exhaust port which are uncovered as the rotor rotates. As a result, a four stroke cycle occurs corresponding to the four stroke cycle of a piston engine, that is, induction, compression, power and exhaust. Efficient seals need to be provided between the rotor tips and the sides of the rotor chamber. The development of effective seals has, to date, been a major problem.
French Patent No. FR 2381908 describes an example of a rotary engine having two “geneva” wheel rotors. The engine has two rotors on parallel shafts. The rotors have recesses and projecting lobes which mesh with each other as the rotors evolve in opposite directions. A small gap between the rotors prevents friction but acts as a labyrinth seal to the escape of gases.
The shafts carry gears which engage with each other to ensure correct contra-rotation of the rotors.
A fuel air mixture is injected through a port in the flank of the engine between the meshing rotors.
A glow plug in the appropriate position ignites the mixture. The resulting expansion produces a force on the lobes of both rotors which causes them to rotate. In the engine described, exhaust gases are released immediately after compression, ignition, and expansion, and the motive forces applied to the arms of the rotors is only over a small segment at rotation.
An object of the present invention is to provide an engine/displacement apparatus of improved mechanical qualities, efficiencies and power.
Further objects and advantages of the present invention will become apparent from the ensuing description.
DISCLOSURE OF THE INVENTION
According to the present invention there is provided a fluid compression and expansion device comprising a casing defining at least two overlapping and substantially disc-shaped internal rotor chambers, bi-axially mounted contra rotating rotors within said internal rotor chambers, each of said rotors having a plurality of radiating rotor arms which mesh in overlapping regions of the internal rotor chambers, the casing provides end walls, and internal rotor chambers perimeter walls, a first side of the internal perimeter wall tracing and conforming to a circular path inscribed by the rotors and a second side perimeter wall having opposed arcuate surfaces which partially trace the circular path inscribed by the rotors joined by a common substantially linear section. The arrangement and construction is such, that on rotation of the rotors, a plurality of compression chambers are provided by the juxtaposed meshed arms of the rotors and the walls of the casing, and enlarged expansion chambers are provided by the juxtapositioned rotors and the second side rotor chamber perimeter walls.
The device can include fuel injection means for injecting a fuel mix into the compression chambers, and fuel igniting means for igniting fuels within the compression chambers.
The rotors can be provided with a hub, arms radiating from the hub each of which have opposed generally involute edges extending to a rotor tip having a arcuate outer edge surfaces.
Each rotor can have three equi-spaced rotor arms radiating from the hub.
Contra-rotation of the rotors can be controlled by meshed gears mounted externally of the casing.
The casing can comprise a pair of end plates to which the rotors are journalled and a central rotor chamber which houses the rotors and to which end plates are fixed.
The rotor outer surfaces enscribe a cylindrical path.
Adjacent walls of the rotor arms may be defined by complimentary volute geometries.
Gearing may be used to increase or vary output speeds.
Where the apparatus is adapted as an engine compression chambers of the engine are split into two and the lateral edges of the rotor arms engage and track along the inner faces of the opposite rotor arms to create high compressions.
Each outer face of the two rotor arms repeats the process in turn creating two compression/combustion areas located between the shafts.
The apparatus has no internal surfaces which maintain contact, hence minimal friction.
Minimal spacing is provided between the surfaces and the rotors and casing.
Sealing may be improved by creating a rolling “air” bearing which maintains containment of the working fluids within the chambers.
Rotor shafts may be supported on the opposite end walls of the casing by bearings. One method may be to use roller bearings to maintain precise tolerance of the apparatus while the standard flat bearings provide support for sideways thrust which is applied.
The rotors are mounted on the shafts and must mesh appropriately in order to provide the sealing and power transfer without friction and wear problems. This could be achieved using a set of gears on rotor shafts, which mesh in such a manner that they can be adjusted to remove any possible backlash and maintain synchronism between the components.
The gears may be housed within the oil sump and may also drive an oil pump if so desired.
The working fluid for an internal combustion engine may be introduced via inlet ports cut into the upper portion of each side of the casing.
The inlet ports should be positioned so that they are closed before the rotors arms begin to intersect, to achieve maximum compression available.
Spent working fluid will be ejected via exhaust ports cut into the lower portion of the casing. The exhaust ports can be positioned parallel to the inlet ports with a small overlap in port opening to allow gas inertia and extraction of clear all exhaust gas and fill the chambers with fresh working fluid.
The exhaust outlets should feed to a common exhaust pipe to aid the gas inertia and extraction of spent working fluid from the chambers.
Other options for improving performance are similar to those currently employed in internal combustion engines incl
Denion Thomas
Hoffman Wasson & Gitler PC
Trieu Thai-Ba
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