EP0210262A1

EP0210262A1 - Axial shaft piston engine

Info

Publication number: EP0210262A1
Application number: EP19860901296
Authority: EP
Inventors: Robert Charles Cahill; Lyn Vickery
Original assignee: Individual
Current assignee: Individual
Priority date: 1985-01-31
Filing date: 1986-01-31
Publication date: 1987-02-04
Also published as: WO1986004637A1

Abstract

Dans un mécanisme pouvant être utilisé comme moteur à combustion interne, comme une pompe ou comme un compresseur volumétrique à pistons, l'arbre secondaire (9) est co-axial par rapport aux pistons (1, 2) et passe longitudinalement par le centre des pistons (1, 2). Le mouvement alternatif des pitons (1, 2) est transformé en un mouvement rotatif de l'arbre (9), et vice-versa, par une came cylindrique (10) montée sur l'arbre (9) et par des cylindres (11, 12, 13, 14) fixés à des protubérances de limitation du couple (24, 25) des pistons (1, 2). Lorsque les pistons (1, 2) sont poussés le long de cylindres opposés respectifs (3, 4) par la pression d'un gaz, les cylindres (11, 12, 13, 14) montés dans les protubérences (24, 25) agissent sur la came cylindrique (10), exerçent un couple sur la came (10) et provoquent ainsi la rotation de l'arbre (9). Inversement, dans la construction de pompage, un couple appliqué sur l'arbre (9) par des dispositifs extérieurs provoque le mouvement alternatif des pistons (1, 2) dans les cylindres (3, 4) et permet au mécanisme de fonctionner comme pompe, à l'aide d'un agencement de soupapes approprié.In a mechanism that can be used as an internal combustion engine, such as a pump or as a positive displacement compressor, the secondary shaft (9) is co-axial with respect to the pistons (1, 2) and passes longitudinally through the center of the pistons (1, 2). The reciprocating movement of the pins (1, 2) is transformed into a rotary movement of the shaft (9), and vice versa, by a cylindrical cam (10) mounted on the shaft (9) and by cylinders (11 , 12, 13, 14) fixed to protuberances for limiting the torque (24, 25) of the pistons (1, 2). When the pistons (1, 2) are pushed along respective opposite cylinders (3, 4) by the pressure of a gas, the cylinders (11, 12, 13, 14) mounted in the protuberances (24, 25) act on the cylindrical cam (10), exert a torque on the cam (10) and thus cause the rotation of the shaft (9). Conversely, in the pumping construction, a torque applied to the shaft (9) by external devices causes the reciprocating movement of the pistons (1, 2) in the cylinders (3, 4) and allows the mechanism to function as a pump, using an appropriate valve arrangement.

Description

AXIAL SHAFT PISTON ENGINE This invention relates to a mechanism which may be used as an internal combusion piston engine or positive displacement piston pump or compressor -in which the output shaft is co-axial with the pistons and in which the reciprocating movement of the pistons is transformed into rotational movement of the shaft (and vice versa) by means of one or more cylinder cams mounted on the shaft and acting with rollers attached to the pistons.

Conventional piston engines and pumps utilize a piston(s) - connecting rod - crankshaft arrangement in which the direction of the piston movement is at right angles to the axis of crankshaft rotation. This results in complexity in terms of parts, high reciprocating mass, side thrust on pistons, complexity of manufacture of crankshaft and crankcase assemblies, comparative large physical size per unit capacity and difficulty in balancing reciprocating masses, particularly in single cylinder units.

The objects of this invention are to reduce physical size for a given capacity, simplify the manufacture of the major structural parts, reduce the number of parts, simplify the balancing of reciprocating masses, and increase mechanical efficiency.

The objects of this invention are achieved by arranging the pistons and shaft co-axially, with the shaft running through the centre of the pistons.

The pistons and cylinders are arranged such that the pistons move inwards and outwards in their cylinders concurrently under the effects of the gas pressures in the combustion chambers and act, via rollers mounted in a yoke attached to extensions of the pistons, on the cylinder cam which is mounted on, and forms part of, the axial output shaft. This in turn produces torque in the shaft.

Conversely, in the pump configuration, torque applied to the shaft rotates the cylinder cam which acts on the rollers and causes the pistons to reciprocate in their respective cylinders. FEATURES

30 The features that distinguish this mechanism from other piston engines are as follows;

1/ The use of a cylinder cam instead of a crankshaft. 2/ Output shaft co-axial with piston movement.

OPERATION

The following details the operation, of the engine.

FIGURES 1A, IB & 1 C show the mechanism as an internal combustion engine (see also schematic diagrams FIG 2 & 3).

Two pistons (1) & (2) (FIG IB), reciprocate in cylinders (3) & (*r). Each of which is enclosed at its end by an end cap (5) &(6) (FIGS 1 A δc 1C) which 40 together with the top end of the piston (1) & (2), forms the combustion chambers (7) & (8).

A shaft (9) runs axially through the centres of the end caps and the pistons and carries a specially shaped cylinder cam (10) at its centre.

The cam (10) is straddled by double rollers (11)(12) & (1-0(13) (FIG IB) which are mounted in yokes (2 ) & (25) attached to an extension of each piston (1) & (2), thus causing the pistons to reciprocate longtitudinally as the shaft (9) and cam (10) rotate.

FIGURES 2 & 3 are schematic representations of the mechanism. The fuel air mixture enters, via a carburettor and valve (16) FIG 2, into the 50 space (15) formed by the pistons around the cam as the pistons move outward. Movement of the pistons inward due to the further rotation of the cam results in the valve (16) closing and the fuel air mixtures starts to compress in space (15). When the pistons approach their inner most position, the induction port (17) is uncovered by the pistons and the pressurised charge transfers from the space (15), via the transfer ports (18) into the combustion chambers (7) _c (8).

Further rotation of the shaft and cam causes the pistons to again move outward, covering the induction ports (17) and the exhaust ports (19) and compressing the fuel air charge in the combustion chambers (7) & (8).

At the appropriate time, the spark plug (20) ignites the fuel thus causing a gO pressure build up in the combustion chambers (7) & (8) and the pistons to be forced inwards. This imparts a force to the cam (10) via the rollers (11) & (13) and causes the cam to rotate and impart torgue to the shaft (9).

Further inward motion of the pistons uncovers the exhaust ports (19) thus allowing the burn't gases to escape ready for the induction of a fresh charge of fuel and air. As the shaft rotates further, the inlet ports (17) open and the cycle repeats.

Torque reaction on the pistons (1) & (2) is opposed by flat linear roller bearings (27) acting between the piston yokes (24) & (25) FIGURE Ψ forming part of the piston extension, and the centre section engine casing, (26) FIG 4.

70 The foregoing describes the operation when the mechanism is used as a power producing device.

CYLINDER CAM VARIATIONS

Whilst the foregoing description relates to drawings which show a two lobe cam (10), giving one inwards and one outwards piston stroke per revolution of the shaft (9), a multi lobe cam may be used to give more strokes per shaft revolution.

FIG 6., shows a four lobe cylinder cam which will give two inward and two outward strokes of the pistons (1) & (2) per revolution when mounted on th shaft (9) in place of the two lobe cam - FIG 5. This will provide two power

80 pulses per revolution of the shaft, hence increasing torque, when used in the

SUBSTITUTE SHEET i

internal combustion engine configuration or two pumping strokes per revolution when used in the pump configuration.

MECHANISM AS A PUMP DEVICE

The operation when used as a pump is as follows.

FIGURE 7 depicts one end i.e. one pumping chamber for simplicity. When the shaft (9) is turned by external means, the cylinder cam (10) rotates and causes the psitons (1) & (2), by means of the rollers (12) & (14), to move inwards and draw fluid (gaseous or liquid) through the valve (21) into the annular space (7). Further rotation of the shaft (9) causes the pistons (1) & (2) 90 by means of the rollers (11) & (13) to move inwards and force the fluid from the space (7) out of the valve (22).

A further application of this configuration would have one chamber used as an internal combustion power producing piston engine (as in FIG 3) and the other chamber used as a pump.

SUBSTITUTE SHEET

Claims

The claims defining the invention are as follows;

1/ An engine having its output shaft axialiy through the centre of the pistons and cylinders and shaft torque being produced by means of pistons acting on one or more single or double lobe cylinder cams mounted on and forming part of the shaft.

2/ An internal combustion engine having two combustion chambers, one at the outer extremity of each of the two opposed pistons each of which moves inwards and outwards in cylinders concurrently and each acting via rollers 1 0 attached to an extension of each piston, on a cylinder cam located between the pistons and mounted on and forming part of the axial output shaft so as to cause rotation of the shaft when pressure is applied to the pistons.

3/ Application of a piston - cam - shaft arrangement described in claims 1 & 2 in a fluid pump (liquid or gaseous) or compressor utilizing an axial drive shaft passing through the centre of the pistons and cylinders and driven by external means.

4/ Combination compressor/ pump & internal combustion engine utilizing the piston - cam - shaft arrangements described in claims 1 & 2. Using one end i.e., piston and cylinder (claims 1 & 2), as power producing section and the 20 opposite piston & cylinder as a fluid pump or compressor (claim 3).

SUBSTITUTE SHEET