DE4210712A1 - ROTATION MACHINE - Google Patents

Abstract

A rotor 1 rotatably mounted in a housing 9 has a drive or driven shaft 2 projecting from the housing. A circumferential array of radial cylinders 3 contain free pistons 5. The pistons slidably engage an elliptical peripheral track 8 secured to the housing. Each piston 5 defines a variable-volume chamber 3a at the radially inner end of its associated cylinder 3, where the cylinder is provided with a port 4 communicating with inlet and exhaust ports 15, (16, Fig. 1) and associated channels in a central tube 14 fixed to the housing 9. <IMAGE>

Description

The present invention relates to a Rotary machine, in particular of the type which is used for combustion motors, compressors, vacuum pumps and the like are attached.

The invention particularly relates to a Rotary machine, which is specific for the applications mentioned is attached and, by using the known compression and Expansion effects of liquid or gaseous bodies inside of chambers with variable volume, a new kind Functional principle corresponds to which, in practice by partial Changes to certain accessories of the entire machine, to produce the various versions mentioned above allowed.

The functional design of this invention remains in itself the same, regardless of their application to any of the mentioned versions. With this in mind and taking into account that this description is as clear as possible, with the last Design options of this machine are to be presented, will explain their features based on one of their most complex Executions accomplished, d. H. as an internal combustion engine. Naturally this does not prevent the possibility of the others mentioned To tackle executions because they're all easier and based on the same principle of operation.

The new type of construction and functionality the machine of the present invention produces results which  so far from none of the well-known and patented rotations machines have been obtained. In the case of application to the Execution which is described, i.e. on internal combustion engines, you get z. B. a better weight / performance ratio, one greater thermodynamic efficiency and adaptability various fuels, and the treatment of Gases to reduce pollution and other benefits, which are given in detail along this description.

The principle of operation of the machine of this invention is based on the fact that the chambers have variable volumes during the rotations of the rotor in the inner part of the corresponding radial Cylinders of the same arise, in said cylinders are corresponding de free piston movably attached, the strokes by a outer track or track, which are preferred is elliptical. Said chambers connect with Openings or channels with the central core of said rotor, to create the feed and exit flows. The as mentioned, pistons are free, i. H. they don't have that conventional accessories such as B. crank rods, bolts, etc., wherein also no crankshafts are needed, as well as no other mechanical devices for connection to the rotor axis, because this axis and the rotor are connected in solidarity.

In the execution of this machine as a motor from which Position very close to the pistons to the core, they move radially  outward by centrifugal force in the feed phase, thereby an internal vacuum is created, which is sequentially in each Cylinder draws in the air / fuel mixture by appropriate Openings, which are in a fixed central tube, concentric to the Rotor, are attached. This pipe also takes the through separately the combustion generated gases on, through the outlet opening, after the start of combustion, which of those with the cylinder connected ignition elements is ignited; the expansion stroke will used for the rotary movement of the rotor, by reaction of the piston on the track or career, whereupon the piston looks like on an inclined plane.

This improves the thermodynamic efficiency receive that the supply of the fuel mixture through the Motor core flows and after a stretch of thermal exchange flows into the cylinder, the core cooled and the Feeder are warmed, thereby a loss of volume causing which can be practically neglected for an engine with such an advantageous weight-performance ratio, especially if this occurs with a heat output, which by Warming up the feeder will result in double the previous loss brings (trials of Shell Laboratories, England).

The introduction through the core of the rotor enables ejecting the feeder and thus increasing the load, thus bridging the characteristic filling effect without  Distribution 'intersection' and also not 'ram-jet' effect, which that cause unburned escape from the mixture.

The ejection achieves correct turbulence and results in a gradual stratification of the load in the Chambers where ideally ignites the combustion with a rich Mix near the circumference, using two flame fronts which propagate to the poor mixing zone, so a perfect one Reaching combustion.

The coefficient of friction of the entire unit is very high low, and that has zoned the lubricated Allows parts.

The exit gases, still in flames, at the exits the exhaust pipes of the core pipe, unite with that of the cooling air flow coming where with this air grant the complete afterburning of the poisonous gases is assured Nitrogen oxides are reduced up to 60%, which immediately after Cooling of the gases are generated.

To concretely address the advantages so briefly discussed design, with many users and technicians in the industry could contribute further advantages, and to the understanding of the structural and functional features of the new rotary machine a preferred example of a Execution described, and in the accompanying drawings depicted, it being expressly made clear that since it is  is just an example, it is not appropriate here, the example in a limiting or excluding character to interpret in terms of the scope of protection of the invention, but that this only explains the principles of the same and are illustrated.

In the accompanying drawings:

Fig. 1 is a schematic section of a rotary machine, in its embodiment as an internal combustion engine, where the outer housing is not shown;

Fig. 2 is a view according to section II-II of Fig. 1, but with the outer housing included;

Fig. 3 shows a schematic perspective of the rotor;

Fig. 4 is a perspective view of the feed and exhaust pipe, according to one of the possible embodiments; and

Fig. 5 includes eight sectional views as in Fig. 1, showing the positions every eighth revolution to explain the execution of the functional circuit of the internal combustion engine.

The same reference numbers correspond in all figures the same parts or elements that make up the machine.

As can be seen in FIGS. 1 and 2, the rotary machine according to the present invention consists of a rotor 1 , preferably in the form of a cross with four right-angled and equal arms, as can also be seen in FIG. 3, said rotor being connected in solidarity with an exit axis 2 .

The said rotor asked four cylindrical cavities 3 radially attached in opposite pairs, opened at their outer end and internally connected to the central part of the rotor 1 through the openings 4 .

Inside each of said cylindrical cavities 3 there are housed a piston 5 , with corresponding closing piston rings 6 of conventional design, each of said pistons 5 having a slide or sliding element 7 at its outer end, which with the inner surface of a track or raceway 8 in Contact is, said track is preferably elliptical, and is rigidly connected to the housing 9 , housing which makes up the outer body of the machine.

Between the cylindrical cavities 3 and the inner side of the pistons 5 , the known chambers with variable volume are determined, in the interior of which the conventional phases of the internal combustion engines are carried out: supply - compression - explosion / expansion exhaust.

A plurality of ribs 10 are attached to both side surfaces of the rotor 1 , for the purpose of heat dissipation and also, when the rotor is rotating, to function as blades of a centrifugal fan, thereby causing a draft that enters from outside through the openings 11 provided in the housing 9 and is passed through inner steering plates 12 , thus cooling the entirety of the rotor, the hot air flows out through other openings 13 , also fitted in the housing 9 , which correspond to the rotational plane of the rotor. It is possible to mount a collector on the outside of the housing 9 to direct the hot air flow outside, or in any other desirable place.

In the core part of the rotor, more precisely in its cylindrical hollow part, a fixed pipe 14 is attached, which has openings 15 and 16 , which are used for supply and exhaust, said pipe being equipped with a dividing partition 17 , as can be seen in Figure 4 can, with ends bent in opposite directions, so that the inner cavity of the pipe 14 is divided into two inner parts 18 and 19 , without connection between them, which respectively determine the supply and exhaust distances. It should be emphasized that this inner subdivision of the pipe 14 , as well as the function introduced thereby, can be replaced by other designs which make the circuits of the supply and exhaust gases independent of one another. So the invention is not solely due to the option outlined above.

An ignition element or spark plug 20 is attached in the cylindrical cavities 3 , it being obvious that this element can be doubled in each cylinder in the manner known from internal combustion engine technology.

In Fig. 5 the various positions or positions of the rotor are shown schematically, only for one piston, in graphical form for every eighth revolution of the rotor, thus producing the chambers of variable cavity which, in the example described here, carry out the characteristic stages of a four-stroke cycle as described below.

In scheme I, the piston 5 is at the bottom dead center in the corresponding cylinder, and the opening 4 of said cylinder is blocked by the part of the pipe 14 which divides the feed and exhaust openings. The piston is in this position because the track or raceway 8 which guides the piston along the cylinder by means of the carriage or sliding element 7 is in one of the two points which are closest to the rotor axis.

If the rotor now makes ⅛ rotation in the direction of the arrow, see II, the piston separates from the bottom dead center of the cylinder due to the effect of centrifugal force, a vacuum or suction being produced in the opening 4, which is no longer caused by the rotation is blocked, but is opposite the supply opening 15 of the fixed core tube 14 , as a result of which the fuel mixture can freely enter the cylinder and fill the variable cavity 3 until the piston reaches the maximum value of its stroke, see III, so the highest cavity in the chamber 3 reaching, now completely occupied by the burning mixture. This constitutes the feed cycle and it can be seen that at the end of this phase the opening 4 of the cylinder is blocked by the wall of the tube 14 .

As the rotor rotates further, the track 8 causes the piston 5 to compress the fuel mixture, as shown in Scheme IV, until the smallest volume of the chamber is reached which is possible with the type of fuel mixture used, as can be seen in V. At that moment the ignition takes place by means of the spark plug 20 with a subsequent explosion, whereby the next stage of expansion occurs, with a corresponding complete combustion of the mixture. When the gas mixture explodes, it expands and drives the piston 5 against the track or raceway 8 , see VI, which acts as an inclined plane and results in the rotation of the rotor in the direction of the arrow, by the action of the reaction component of the slide 7 , until the maximum stroke is reached, as shown in Scheme VII, which corresponds to the beginning of the opposite position of the opening 4 of the cylinder and the exhaust opening 16 of the central tube 14 .

From there, the combustion of the burned gases, which are driven outwards by the piston, begins while the rotor runs through the last quarter of the rotation, as shown in Schemes VII and VIII, since here the opening 4 of the cylinder is opposite the opening 16 of the fixed one Central tube 14 remains until the piston 5 reaches bottom dead center again, as shown in Scheme I.

All pistons of the rotor carry the described here cycle, in an independent sequence.

The phase shifts between the different Positions of the piston in relation to the moments where the opposite positions begin between the different openings, on Beginning of the stages, as well as at the end, together with the lead or delay the ignition, are theoretical and experimental development of the engine determines, being express it is made clear that the states mentioned are different from the novel ones Features of the invention are independent because of the functional concept the same is with all possible changes about the regulation of distribution.

It should also be borne in mind that the track 8 where the head of the pistons 5 rests can be designed such that the maximum and minimum strokes of said pistons can be changed so as to achieve various compression numbers while the engine is running, as previously stated , and also an adaptation to the different fuel grades without other changes in the mechanical structure. For this said track or track can consist of a steel strip or similar adapted material.

Regarding the geometrical shape of the track or track 8 in its inner surface, changes can be introduced which aim at better general performance, a basically elliptical shape being selected in the example described.

According to another aspect of the invention, it should be said that although the combustion gases can be ejected in various ways without fundamentally changing the invention, the gases can be passed through the opening 4 when they face the opening 16 of the core tube 14 stands, and then go through the exhaust pipe 19 , and to the outside of the rotor 1 through the openings 21 , which extend radially through the pipes 22 to the inner periphery of the housing 9 , near the opening 13 . Optionally, the ends of said tubes 22 can be inclined at the tangent to the rotor to produce reaction drives so as to take advantage of the amounts of movement of the gases.

In practice you can use the example described the rotary machine in a modified and / or improved form execute, for example by using elements for dynamic Balance, etc .; all of these improvements must be implemented as Changes that are within the scope of protection are considered the invention are included, which is fundamentally by the subsequent claims is set.

Claims (12)

1. Rotary machine for use as an internal combustion engine, pump, compressor and the like of the type which comprises a rotor installed in a housing , said rotor being connected in solidarity with an exit axis which protrudes from the housing, characterized in that said rotor has a plurality of cylindrical has radial cavities in which corresponding pistons are mounted with free movement, the strokes of which are limited by a peripheral track or raceway which is not circular and is rigidly connected to the housing, and determines the extreme positions and intermediate layers which are necessary for the pistons in their corresponding cylinders are provided; wherein each cylinder has an opening at its base for connection to supply and exhaust channels, which are mounted in the core part of the rotor and are connected in solidarity with said housing. 2. Rotary machine according to claim 1, characterized characterized in that the intake and exhaust ducts inside a tube fixed to the housing are attached, the Tube enters the core of the rotor and has an inner partial wall, which separates the channels mentioned. 3. Rotary machine according to claims 1 and 2, characterized in that said fixed to the housing Pipe has corresponding feed and exhaust openings, which are  face the openings of the cylinders one after the other. 4. Rotary machine according to claims 1 to 3, characterized in that the exhaust duct in the fixed pipe in Connection with the rotor is solidarity lines, which are extend by radial tubes fixed to the rotor, which in Inside the housing are present and their ends are preferred in the tangential direction to the intended direction of rotation of said Are bent. 5. Rotary machine according to claim 1, characterized characterized in that said peripheral track or career has a generally elliptical shape. 6. Rotary machine according to claim 1, characterized characterized that around each cylinder, the rotor with heat distribution plates is equipped. 7. Rotary machine according to claim 1, characterized characterized in that the housing on both sides of the rotor Has openings, which means for the entry of cooling air determine. 8. Rotary machine according to claim 1, characterized characterized in that fixed plates attached inside the housing are which conduct the cooling air. 9. Rotary machine according to claim 1, characterized characterized in that the housing has at least one radial opening for the escape of air and / or burned gases.   10. Rotary machine according to claim 1, characterized characterized in that at least adjacent to the ground said cylinder has at least one ignition element attached, like a spark plug, spray nozzle, etc. 11. Rotary machine according to claims 1 and 5, characterized in that the shape of said track or Career is adjustable. 12. Rotary machine according to claim 11, characterized characterized that said track or career for a reason there is also flexible material, under steel tape and the like selected.