GB2053352A

GB2053352A - Internal combustion engine driving gear between piston and crankshafts

Info

Publication number: GB2053352A
Application number: GB8019724A
Authority: GB
Original assignee: Individual
Current assignee: Individual
Priority date: 1979-07-10
Filing date: 1980-06-17
Publication date: 1981-02-04
Also published as: GB2053352B

Abstract

The piston P of each cylinder C of a four-stroke I.C. engine is connected by a connection rod 10 to an intermediate point 12 of a floating link 11, which point 12 is constrained, for instance by an arm 17, to travel substantially rectilinearly, and the ends of the floating link 11 are joined by connection rods 13, 15 to primary and secondary crank shafts 14, 16 respectively which are coupled together to rotate at a selected ratio of different rotational speeds, the ratio best being 2:1. The arrangement is such as to give a longer power stroke than induction stroke. The cylinder may be provided both with a normal valve-controlled exhaust port 19 and with exhaust ports 20 which are only uncovered at the end of the power stroke. <IMAGE>

Description

SPECIFICATION Internal combustion engines The invention relates to four-stroke internal combustion engines.

In conventional engines of this kind, the swept volumes of the induction and power strokes are substantially identical and, as is known, considerable energy is lost in the discharged exhaust gases.

Also due to connection of the piston, or each piston, to a crank shaft by means of a connecting rod, high side loads and high friction losses are experienced.

The invention seeks to reduce these losses.

According to the invention, in a four-stroke internal combustion engine the, or each, piston is drivingly connected by a linkage to two crank shafts which rotate at a selected ratio of different rotational speeds such that the piston partakes of a longer power stroke than induction stroke, the linkage including a piston connection rod which is constrained in operation to travel substantially rectilinearly.

The piston connection rod may be constrained to substantially rectilinear travel by a tracking arm of substantial length which has one end pivoted on the engine fixed structure, e.g. its casing, and the other end pivoted to a point of the piston connection rod remote from the piston so that this point travels in a shallow arc.

The linkage in a convenient form may comprise separate connection rods for the crank shafts joined to respective ends of a floating link to which the piston connection rod is pivoted at an intermediate point. In such a form, the intermediate point can be nearer the end of the link to which the connection rod of the faster rotating crankshaft is connected.

In the basic construction of the improved engines of this invention, not only is there greater utilisation of the combustion energy, but also side loads on the cylinder wall due to swinging of the piston connection rod as occurs in conventional engines are eliminated to a large extent.

The present invention seeks to improve even further the operational efficiency of such engines as compared with conventional engines and according to a feature of the invention each cylinder is provided, in addition to a conventional upper cylinder valve controlled exhaust port, with lower exhuast ports which are uncovered by the piston only towards the end of the power stroke, but not in the induction stroke, thus allowing substantial reduction of the quantity of exhaust gas to be discharged through the upper end exhaust valves during the exhaust stroke thereby effecting a saving in energy.

Some engine arrangements constructed in accordance with this invention will now be described with reference to the accompanying drawings, in which: Figs. 1 to 4 show the operating cycle of a single cylinder engine, Figs. 5 and 6 illustrate one multiple cylinder arrangement, Fig. 7 illustrates a second multiple cylinder arrangement, Fig. 8 illustrates a third multiple cylinder arrangement, Fig. 9 illustrates a fourth multiple cylinder arrangement, and Fig. 10 illustrates an additional feature of advantage in reducing losses.

Referring to Figs. 1 to 4, the engine utilises two crank shafts, namely a 'primary crank shaft' 14, and a 'secondary crank shaft' 16, which shafts are rotationally locked to each other via gear wheels, pulley wheels and chains, or similar devices, such that the secondary crank shaft 1 6 rotates at half the speed of the primary crank shaft 14. The shafts rotate in opposite directions in the example described.

'Primary' and 'secondary' connection rods 13, 1 5' are connected by one end to the primary and secondary crank shafts 14, 1 6 respectively and have their other ends on respective ends of a floating link 11.

A 'piston' connection rod 10 is pivoted by one end to the piston P and at the other to the link 11 at a point 1/3 of the link length from the end to which the primary connection rod 13 is pivoted.

A 'tracking arm' 1 7 is used in this version of the engine, the arm being pivotally secured at one end on the engine fixed structure, e.g. its casing, and at the other end to the link 11 at the same position as the piston connection rod 10.

The tracking arm 17 acts to stabilise the three connection rods and the floating link, and restrict movement of the overall mechanism to mechanically defined positions on a shallow arc 1 2a (Fig. 1) through which the end connected to the link travels.

Further the tracking arm holds the link and small ends of the primary and secondary connection rods 13, 1 5 in the plane of the particular cylinder C, and big end journals of the primary and secondary crank shafts concerned, to prevent fore and aft instability.

Alternatively, a slider and guide mechanism may be used to fulfil the same function, particularly that of preventing substantial deviation of the piston connection rod 10 from rectilinear travel.

OPERATION For the purpose of describing the operating principle, it is assumed that: (a) the primary crank shaft 14 rotates clockwise, and the secondary crank shaft 16 anticlockwise.

(b) at the start of the induction stroke (Fig. 1), the piston P will be contained within the cylinder C at its closest position to the cylinder head; that the big end of the primary connection rod 13 will be nominally at top dead centre, and the big end of the secondary connection rod 1 5 nominally at 900 prior to top dead centre.

In practice relative dimensions of the three connection rods 10, 13, 15, the link 11 and tracking arm 1 7, and the crank shaft throws, will not permit these angles to occur precisely as stated.

INDUCTION STROKE As the induction stroke proceeds, the big- end of the primary connection rod 13 moves progressively through 1800 clockwise to bottom dead centre, and at the same time the big end of the secondary connection rod moves progressively through 900 anticlockwise to top dead centre.

At the end of the induction stroke (Fig. 2), the primary connection rod 1 3 will have lowered its end of the link 11 nominally to its lowest position, and at the same time the secondary connection rod 15 will have raised its end of the link 11 nominally to its highest position. The link 11 will have lowered itself slightly and rotated anticlockwise, and consequently the piston connection rod 10, which is attached to the link at a position closer to the primary connection rod attachment than the secondary connection rod attachment, will draw the piston P down the cylinder C through the required induction stroke swept volume.

COMPRESSION STROKE As the compression stroke proceeds, the big end of the primary connection rod 13 moves progressively through 1 800 clockwise to top dead centre, and at the same time the big end of secondary connection rod 15 moves progressively through 900 anticlockwise to 900 after top dead centre. The link 11 will have been raised and rotated clockwise to the position of Fig. 3, and the piston P and piston connection rod 10 will have returned nominally to the position it had at the start of the induction stroke.

POWER STROKE As the power stroke proceeds, the big end of the primary connection rod 13 moves progressively through 1 800 clockwise, and at the same time the big end of the secondary connection rod 1 5 moves progressively through 900 anticlockwise, both then being at bottom dead centre (Fig. 4). The link 11 will have been lowered to its lowest position, and the piston P allowed to 'work' through the extended power stroke swept volume.

EXHAUST STROKE As the exhaust stroke proceeds, the big end of the primary connection rod moves progressively through 1 800 clockwise to top dead centre, the big end of the secondary connection rod anticlockwise to 900 before top dead centre, and the piston P to its closest position to the cylinder head. At the end of this stroke the cycle will have been completed and the parts will be as in Fig. 1.

POWER OUTPUT Power output will normally be taken from the primary crank shaft.

FUEL OPTIONS Any fuel usable in conventional piston driven internal combustion engines may be used (e.g.

petroleum, diesel oil, gases of various types, heavy and light fuel oils etc.).

A variety of engine configurations are possible, and the following are examples.

In Figs. 5 and 6, a twin bank horizontal configuration is illustrated in which the big ends of the primary connection rods 1 3a, 1 3b are mounted rotationally 1800 apart on the primary crank shaft 14, and the big ends of the secondary connection rods 1 Sa and 11 sub are rotationally on a common journal axis 1 spa on the secondary crank shaft 16.

The cylinders are illustrated respectively at the start of the followirig strokes: Cylinder Z: induction Cylinder Y: power Cylinder X: compression Cylinder W: exhaust Fig. 7 illustrates a quadruple bank configuration in which the primary connection rods of cylinders Z, X are mounted rotationally on a common journal axis 1 4a on the primary crank shaft 14, and the primary connection rods of cylinders Y and Won a common journal axis 1 4b 1800 apart from axis 1 4a.

The secondary connection rods of cylinders Z, Y are rotationally on a common journal axis 1 6a on secondary crank shaft 11 Sa and the secondary connection rods of cylinders X and W, on a common journal axis 1 6b on secondary crank shaft 1 1 6b.

The cylinders are illustrated respectively at the start of the following strokes Cylinder Z: compression Cylinder Y: exhaust CylinderX: power Cylinder W: induction Fig. 8 illustrates a configuration in which two pistons oppose each other in each cylinder; this configuration offers advantages from an engine balancing point of view. The illustration shows this variant at the start of the exhaust stroke. The references are the same as for Figs. 1 to 4.

Fig. 9 illustrates a twin cylinder bank variant of Fig. 8, incorporating one primary crankshaft 214 and two secondary crank shafts 21 6a, 21 6b.

The illustration shows cylinders T and S commencing induction and exhaust strokes respectively.

A variety of radial, and squat or low profile engine configurations are also achievable.

The common features of all engines operating on the principle of this invention are: (i) that the piston or each piston sweeps through a greater volume on the power stroke than is swept during the induction stroke, and hence extracts a quantity of that energy which would normally be lost by a conventional piston engine, and (II) that piston side loadings are minimised so that frictional losses are reduced.

There will now be described an engine modification applicable to each of the foregoing engine arrangements. Referring to Fig. 10, this modification is shown as applied to a single cylinder four-stroke internal combustion engine as illustrated in Figs. 1 to 4.

In the drawing, as before, the piston connection rod 10 is pivoted to a floating link 11 at point 12 which is nearer one end of the link than the other, the primary connection rod 13 joins the one end of the link 11 to the primary crank shaft 14 and the secondary connection rod 1 5 joins the other end of the link 11 to the secondary crank shaft 1 6. The shafts 14, 1 6 are coupled so that shaft 14 rotates at twice the speed of shaft 1 6 and the shafts rotate in opposite directions. A tracking arm 1 7 constrains point 1 2 to move substantially in a straight line.

The bottom dead centre position of the piston head on the induction stroke is indicated by dotted line 18, and according to the invention in addition to a conventional upper end exhaust valve 1 9 there are provided, spaced below the position 18, a ring of exhaust ports 20 in the cylinder C which ports are uncovered by the piston at the end of its power stroke as indicated by the full line position of the piston P.

Thus at the end of the power stroke the pressure within the cylinder C is rapidly reduced by the outflow of combustion gases through the ports 20 and the quantity of exhaust to be expelled through exhaust valve 1 9 is not only reduced but also its pressure is kept low so reducing the energy absorbed in the exhaust stroke.

Claims

1. A four-stroke internal combustion engine having a cylinder accommodating a reciprocating piston, or a plurality of such pistons and cylinders, wherein the or each piston is drivingly connected by a linkage to two crank shafts which rotate at-a selected ratio of different rotational speeds such that the piston partakes of a longer power stroke than induction stroke, the linkage including a piston connection rod which is constrained in operation to travel substantially rectilinearly.

2. An engine according to claim 1, wherein the piston connection rod remote from the piston has a point of connection to a tracking arm which is pivoted on the engine fixed structure and has such length that said point is constrained to travel on a shallow arc.

3. An engine as claimed in claim 2, wherein the linkage comprises separate connection rods for the crank shafts joined to respective ends of a floating link to which the piston connection rod is pivoted at an intermediate point.

4. An engine according to claim 3, wherein the intermediate point is nearer the end of the link to which the connection rod of the faster rotating crank shaft is connected.

5. An engine according to any of claims 1 to 4, wherein the ratio of rotational speedsof the crank shafts is 2:1.

6. An engine according to any of claims 1 to 5 wherein the shafts rotate in opposite directions.

7. An engine according to any of claims 1 to 6, wherein the or each cylinder has an upper cylinder valve-controlled exhaust port and in addition lower exhaust ports which are uncovered by the piston only towards the end of the power stroke but not in the induction stroke.

8. A four-stroke internal combustion engine constructed and arranged to operate substantially as hereinbefore described with reference to and as illustrated in Figs. 1 to 4, or these Figs'. in combination with Figs. 5 and 6, or Fig. 7, or Fig. 8, or Fig. 9 of the drawings.

9. An engine according to claim 8, the or each cylinder having an exhaust arrangement substantially as described with reference to and as illustrated in Fig. 10 of the drawings,