CA2410787A1 - Final synthesis of poly inductive machine ii - Google Patents

Abstract

The object of the present invention is to produce a few new units of poly inductive machines, the main feature of which will be to produce a non-circular central blade stroke. In addition, we will show that with the use of certain gears, which we will call polycam hybrid, we will show how we can approach new forms of cylinders while maintaining a circular center. These new machines will be able to produce not only new cylinder figures but moreover, a high compression ratio making it possible to produce them in diesel fashion. In addition, this knowledge will be applied in the field of semi differential turbine type machines. As we have, before the present, presented many retro-rotary machines, and similarly post rotary with retro-rotary connotation, we will synthesize our work and will give the last general rules allowing to define the scope of our patents

Description

Vote For a better understanding of this, care will be taken to consult all of our previous work, which we will find. the list at 1; ~. end of this disclosure.
Disclosure L, 'We will note in our previous works a good variety of poly inductive machines, and similarly a good variety I) e types of mechanical supports of different compression parts, and c; e whether they are pistons, blades or ~, palic structures.
These support methods. have the following 1) mono induct.ir> r ~

2) poly induction

3) by serai trar ~ smissïon with. and: without gables

4) by hoop gear

5) by intermediate gear

6) by double internal gear juxtaposed

7) by polycame gears

8) by stepped poly inductive gears

9) by equidistant gears

10) by gear structure

11) by cam 13) by hoop and intermediate, off-center 14) by eccentric polyinductive 15) by hoop gear atlgulé
16) by unitary poly induction 17) by hybrid polycamera gears 18) by external poly iruduction iori.sée 19) by dynamic mono induction 20) by geometrical poly in ciuction 21) by double p ~~ ly differential induction rFor the poly turbines, we will abut some more supports specific that it will be too long here to list.
To better understand the purpose of this we will summarize somewhat forward about some urns of these methods, which will either be developed here, or even in combination for new forms of polyinductive machines of higher levels.
Although we will only combine here some of the methods of supports blades of such kinds to produce new figures of machine it is important to mention that these new figures can later be re-created from all types of media put in combination.
For the purposes of this presentation we will summarize the elements of base in the following way.
First, remember that we can support the blades of the machines post and retro rotary apart from structures that we have named at hoop gears. (Fig. ~ 2) In these structures, the action on the blade is obtained by the delay accomplished on the hoop gear and transferred to the induction gear .of the blade, causing it to be soil; to slow down, but staying in the same sense that that of the crankshaft, is to slow down enough to turn in the opposite direction to vilebrc ~ q ~ uin. In the first case, we will obtain retro rotary machines, and in the second, so-called machines rc ~ trorotatives.
Second, after noticing that you can create shapes news using gear staging we showed that we could realize: m ~ th qa.e figures those made with this e: n gear racking using single inductive procedures, but this time, with the help of multi-cam gear. (Fig.3) 7, thirdly, we have shown that with the help of of polycamerous gears to ~~ days, produce blade supports said equidistant, making it possible to produce several variants of cylinders, and in particular the same racing figuras, produced by mechanics originally retro rotary; that originally post rotary.
Lately we have already shown that all of our methods cie supports could support various machines already presented by ourselves, other than single blade machines, either rotor cylinder machines, Ie; s machines ~ palic structures, machines with irregular cylinders, that is to say, metaturbines . (Fig..4) l The innovations currently proposed herein apply to surplus to all these types of machines, since, as we have previously demonstrated, all can be applied to the different poutine methods of compression parts.
We therefore begin the demonstration of this by recalling that the variation of the point of attachment of a poly inductive structure vary the stroke of an interior figmre going from more acute to more softens, outwards (Ivi g. 5) But it should also be noted that, for a given geometric shape, if we subtract, instead of adding a geometric value, we will produce a shape similar to the first one but this time more flattened, since the geometric lustration has changed in a larger ratio Ies parts in height than the parts in lar; eur (Fg. 6) in the present case, the most interesting fact to r ~ .rr ~ archer is very ~; s certainly the one that the new form created demecrre able to realize all the qualities of initial shape, in particular, if a triangular blade is inserted into it in rotation, all the sharp will touch the surface at any time To produce this geometric subtraction, we will produce by point of support two poly induction; a ~ tagged to which we will attach a connecting rod whose additional geometrical part will be directed towards the center.
I, 'we will call this methoci.e, poly induction from the outside. (Fig.7) (this new, more extended figure will have the originality of increasing considerably the ratio ct ~ mpre sïon, and this at this point of power produce the machine diesel. This last type of poly induction will take us directly to the second object of the present invention, â ~ to know, to show how poly inductive methods have the ability to guide a piece of palate in such a way as to push the compression at a height: ~~~ uf ~ ïsante to make retro machines or post rotary able to run on diesel fuel. New debt cylinder shape, obtained by external poly induction can be made with only two attachments.
Read more specifically observing the course of the dynamics of the center of this machine, we realize that, in addition to being created from a new mechanics, this machine has a center whose dowel is not circular. (Fig.B) : We also see that we could modify the shape of the cylinder such a way of recalling the balloon shape already commented on by us-even before the present, corn again this time more pronounced. Observing the race from the center of this news machine, we will realize who; this one is moving and realizing a shape elliptical elongated at its back, allowing a very compression ratio high and very slower rotation. So we can build this type diesel, since the compression ratios can quite easily be raised to one in ten s ~; pt ...
f; n indeed, in this last figure, L'OIl can imagine that the piston will move, in addition in a ballory cylinder, and: or consequently, Ia combustion chamber would long be attached to the arc, which will allow, in addition to be able to realize the engine in a diesel way, carry out several consecutive explosions. ultimately, like this form suggests, the explosion may occur angularly, which would allow us to suppose, that here, as in the poly turbine energy, we realize an engine without dead time, but this problem with single blade. (Fig.9) The blade stroke of this machine would therefore be ideal for several points of view, since while the blade would slide, before its descent final, we would have time to produce several explosions, of the type diesel, since its compressûo ~ n would already be sufficient from the start.
Subsequently, his angular attack <rf ~ would cancel the word time lately the segmentation would be assea ~. 1-asylum, puoisque ~ ;; ~ will not be Ies corners which will receive Lc more frïctünn 1 ~. One knows that by using a poly cam gear with a structure mono inductive conventional, we get a ball curvature less pronounced rotary port machine with three blades. (Fig. 3) We can see that here that the specific guiding realization of this blade with the combination of support structure from the outside and by polycammed gear gives a first result.
Other forms of blade support will appear more obvious when a more rigorous analysis of the center behavior of the blade.
By observing in fact the position of the center of the blade, we will notice one of the notable originalities of the machine in that the center of it does not move, like; in all of the others post or retro rotary machines, in a circular fashion. Indeed, as we can see it, the displacement of this one is read itself e-xcentric, being even, at I ~ ri ~ by looking at a parallel replica of the of the shape of the cylinder.
Lin effect, we see that the poGycamation of the gears allows to exaggerate the structure and produces the desired shape; throughout the movement, we also see that the angulation is conducive to the explosion which realized without dead time.
relay, this structure takes up a certain amount of memory.
Furthermore, we know that according to the equidistance rule which we have previously shown in our previous patents, if we couple f; nset of polyc gear; ames, the center of these will travel a stroke parallel to that of the support gear, external or reverse and the center points of these ~. ~ n; ~ renages will be: equidistant throughout their stroke, which allows them to attach a rigid blade, To further information: ,, we must consult our patent application relating to equid support; ~>t; ants.
In the present case, a second way of guiding the piece of compression will produce clogged gears don the gear rie support will be a parallel ~ of the sought course and, pale the continuation of build complementary induction gears.
lWe can choose either type of support gears internal or external, because, as we have already noticed, these types gears will make it possible to make the transition; post rotary machines to the rotary machines without problem (Fig. 9, 10) Then we can. attach the centers of these gears to the parts boosted and thus produce the machine, the driving part being, as at :( 's used the induction crankshaft support crankshaft hWe must now ask ourselves the question of whether, as for other poly indiactive machines, if other support methods apply, and moreover, it is the most effective.
But first, it is necessary to deteunine if the machine is post or retro rotary our feeling will be that this machine is predominantly rétrorotative. This may seem surprising since we are at this point accustomed to seeing the triangular blade ~ ar ~ kle. But let's add to present, as shown. on several occasions, that the blades triangular are also used c: n retro rotation and, they move in a square-shaped cylinder.
here are the two ideas that names tip to opt for the fact that this structure is rather hyhrid the points, d ~ :; mix of post rotary blades follow, if placed, as we have previously shown, a curvature which can approach that of the cylinder, while in the machines retro-rotating, they define very complex faunas, with passages with a lot of loops, this is quite the case here. Then the offensive phase of the blade of a post rotary machine goes through a <~. acceleration then towards a deceleration. here, the geometry is contradicted m since the tip of the pa: GLr: literally stops in the middle of the arc as if it were ~. ~ x sides put end to end. If so, this would be the speeds and the races, which more than the appearance we would make it possible to affirm that i I 's a coach ïne à bases back to triangular opals, moving in a universe of four limiting sides.
Considering this, we can, as we have already mentioned, indeed apply the metho ~ ae ~ equidistant polycamé support for realize the machine. New gears, alternately eccentrics and incentives, which we will call hybrid polycams will then be used. (Fig.1 (U) This observation leads us to state that we can, in combination with a second ~ en ue structure controlling another part of the blade, make a combination of supporting the center of the blade For example, the center of this blade could be supported by polycam gear sets, since we know that the center These gears follow the desired course. (Ii ïg. L I
In another way, we can support the blade center with a poly retro-rotary induction, by adding a geometrical component to the retroactive gear of induction, by the use of a connecting rod crankshaft of a specific length. We see then that the end of the rod travels the sought trajectory :. (I ~~ ig. I 1 b) As we know we can paint a retro rotary shape with post rotary gears, may ~~ however polycamé, The structure do following support will be able to do so: nir the center of; the blade.
As we have already said, on the strength of these observations, we can state the idea that we can adequately support the blade, defining a second support method, this time suitable for : support in combination another point of L, ~, pale.
In this type of machine, i: he, as we have already mentioned, is at retrorotative prominence, i: l was to eliminate the supports by the centers of storytelling, which in this case, for example, runs in form of eight almost mechanically impractical in a simple way.
By studying more closely the figure to realize, we will notice that we could support the center of the blade using a new type polycamé gear, which we will call polycamé gear hybrid. This gear is so named because it has both outward curvature Lar and inward curvature, related with an original .circular curvature.
Indeed, when we look at our first works relating to polycamed gears, we realize that the curvature of these only works in a sen; ~~. (Fig. 3) gears for example quasi triangular are put in composition with gears either single eccentrics, either elliptical or other. These types of gears will have succeeded, as we have already shown it to carry out the work that would have accomplished two pc sets: ~ ly inductive superimposed. Here, to realize the simple looking form, i would need three or four poly sets superimposed inductive or encd: are two sets poly inductive poly cam in the first degree, which is still too much.
The use of a gear; hybrid poly cam, either as a gear support or as a support gear ~ nï will reduce, for so to speak poly induction. (I = ~ ig. L 4) Indeed, in a first ~ -example, we can control, as previously, the dca travel between the hale by poly induction simple polycamed, and control the orientational aspect of the blade by a polycammed hybrid gear fixedly mounted on the blade and coupled to a non-hybrid multi-cam gear, mounted in the side of the machine.
Conversely, we can mount a gear on the blade this time polycamé simple, and in 1f ° llac of the machine, rigidly fix a polycammed hybrid gear. The movement of the blade during rotation will therefore be perfect compatible with the cylinder shape : sought The new movement of the center of the blade, compared to the movement original circular, is a tri.ouvement which passes alternately eccentrically, and incentricluement. We will accept this news terminology, which we think is best suited to define this reality.
Iyès then, it is thus necessary to fill not only the acceleration speci ic deceleration of this; pale, as we did in our first work on balloon cylinders, but at most make up for these differences ~: the ~ variation dccourse centrale by adding new qualities to these eng ~ ° enages, which will push the cylinders balloons to 1a limit oir is understood hereby to push them.
For a good understanding, we can therefore interpret the geometry of hybrid polycammed gears as follows.
('As before, these are not deformations in one sense of single polycarbonate gears. 11 erl are deformations in both directions, which will allow adding new trajectories possible, trajectories that do not; would be possible, as we have already mentioned, only by the. a ~ c. ~ mbinaisc> ns of several overlays of poly induction, or even two superpositions of poly induction polycamés.
We can therefore mount 1c; machine center with poly Standard induction and orientation of the blade by play above mentioned gears.
~ A final type of specific gear, used here to guarantee the effect directional of the blade will be a double polycamera rack gear.
~ .'e double gear will allow the induction gear to jump .directly from the last tooth of one to the first of the other.
~ (Fg.I3) However, if you absolutely want to make the machine in a mono way inductive, with central control of the vane, we note that we can increase the balloon effect of en ~ -enages polycamés simple en using two polycammed hybrid gears. In this way, we will almost have the desired shape and be considerably behind the explosion.
It should also be noted that; the use of these polycamera gears hybrids can be generalized wherever we currently use dies standard gears and polycamed gears, that is to say in all types of blade supports already listed by us, from nnonocamés à par engrenag ~; ~; in structures, passing by types will be transmittive etc As we can see, it is almost impossible to achieve a orientational blade guide which allows it to be driven at each instant for the inenate detenrn form.
It is probable, however, that q ~. ~ C; in this ton halfway between a rotary form and piston shape, requires no guidance orientation other than the cylinder is necessary, in this case a conduct of the center of the piston by a poly inductive, retro-rotating assembly ~; emometrized, or polyc; amé will be extremely powerful since will cancel the time out, in the manner of what we produce in poly turbines (Fig. l? ~
it will be noted that a pipe of the blade, by its center side side, of high end low also produces an interesting figure.
It will therefore be noted, at the limita: that all the blade supports already exposed by ourselves, for example, in double internal gears, juxtaposed, or storied, must be applicable; since indeed, the center of the induction gear follows a circular path, and can therefore therefore receive 1'c; ~ o ~; renage de Lîen that will unite these last two gears Through the work of this patent application, we have proposed a limit form dd ~ machïne rotati ~ ro rectilinear, whose main characteristic, at level no: n not the shape of its cylinder, but of its dynamics, was. that the rotational center of the latter was not circular, but rather non-circular, here elliptical The next realizations of this type of machine will apply to so-called differential machines, and thereafter to hybrid machines located between the differential machines and the rotary machines.
In the first embodiment of the present invention relating to differential machines, we will assume, as in machines original, the blades inserted in a circular cylinder. However in the present embodiment, it will be assumed that their ends are all connected to a rotor cerr ~: ral shown rotatably in the center of the machine. In this type of machine, the inner part of each blades will then be connected to a poly inductive mechanical urte, preferably polycamed. As we have nvc ~ ntré, we pLUt realize quite freely the blade support stroke. l., the originality of this machine will so that the lower stroke ° ~ e of the blades d ~ will not be circular, and that accelerations and decelerations ~ us of these during rotations will absorbed by the connection and the ~ c ~ straightening thereof (Fig.15,16 ~) Different .sequences and fl ~; x.âons and rL ~ drf; ssom.ents of these will possible without changing the ccancept of the present invention.
This brings us to another. type of machine created from supports not circular. I ~ 'we can indeed assume poly induction will ; superimposed, either parallel supporting single consecutive blades.
By such an arrangement the gold will create differential machines, but with non-circular cylinders: and a movement of blades reminiscent of that post or retro rotary machines. L, 'we note that we can alternate the post or retrorotatory source of support in such a way as to produce the maximum expansion on the one hand, and blocking effect on the other When the blades of these machines are supported horizontally, note that we can also close the cylinder by the base and so produce new channbres., lower, these machines will therefore chamber holes, possible, upper, dïff ~ r ~ ntials, and lower, It should be noted, moreover, that when the blade is supported by gears hoop, there is the possibility of ~. ~ outer a third gear, which will come angulate Ia pushed from the pal ~~ on it It will also be noted that in the basic differential stuff, the cylinder can be configured as having (in the form of a tire, which will allow easier segmentation of each of the blades, their stroke transverse recalling that ~; a cylinder I ~ 'we can therefore produce hybrid machines, the lower part of each List of patents and application for patents First series patents I) Canadian patent 1,160,911 issued on January 24, 1984 (filed on March 29, October 1981 under ro 389, 266) for Motor energy 2) Canadian patent ro 1,16'7,337 granted on May 5, 1984 (filed on 27 May 1983 under ro 42 ~~, C) 73) for Cylindrical cloisonings of motors and compressors.

3) Canadian Patent No. 1.16'ë- ~~ l, 130, issued September 11, 1984 ( filed on September 21, 1983 under No. 43'7, 268) for Solutions derived from ener ~ etiQUe motor., 4) Canadian Patent No. 1,209, issued August 8. 1986 (filed August 11 1983 under No. 440,645) for Energy engines II
5) Canadian Patent No. 1,229.,? 49, issued January 12, 198? (filed on March 18, 1985 under the number ~ 4? 6,? 20} for Energy machine III
6) Canadian patent application no 2,056, 168-8, filed on 25 November 1991, for Energy Machine with Rocker Pistons, during the procedure ', ~) Canadian Patent Application No. 2,045, ??? - 5, filed June 26 1991 for semi transmittive induction energy machine, in procedural course.
8) Canadian patent application no 2, U56, 168-8, filed on 25 November 1991, for Eneri machine; simulated induction ethics _Second patents ~ s ~ rie Note: all of these bre ~ rets are currently underway international.
9) Canadian patent application no 2,29,7, 393 tabled on February 2, 200 (), for Energy engine backflow 10) Canadian patent application, no 2.30'x ', 870 filed March 15, 20C1 il., for Poly energy motor induction 1. l) Carradian patent application no 2,3 i 0, 4 ~ 7 filed May 23, 2001 :), for Energy Muting Traction

12) Canadian patent application 2,310,488 filed on May 2: 3, 2001, for Polyturbine Energy and backflow

13) Canadian patent application no 2,: 310, 489 filed May 23, 20 () 1, for the Dual Energy Engine levels Third series patents These patents form all of the patents arising directly from the realization of protot ~ i ~ e, s, functional ~~ roduïts by EMI Canada

14) Ca ~ r ~ adienne patent application. no, 2,330, 591 filed on 9 January 2001 for Complementary engine constructions backflow

15) Patent application:., Number 2,3 56,43 5 for Anti-backflow motor II deposited on July 3, 2001

16) Patent application rtvo 2,346, I 90. ~ Filed on July 7, 2001 for Second complementary version of engines backflow

17 17) Patent application., For Eolienne energétï, _ Que (not filed)

18) Patent application, for Energy wind turbine II (at file)

19) Patent application., For Compressive hydraulic pump ( to place )

20) Patent application., For Flexible blades motor (to file)

21) Patent application. "For rotary energy valves (to file)

22) Patent application, for Energy wedge motor (to file) Guatrièrr patents ~ e series

23) Patent application rbcn 2,342,442, filed on March 22, 2001, for Generalization of poly inductive motors

24) Patent application: no 2,342,438, filed on March 22, 2001 for Bridges for motors, poly inductive

25) Patent application nuo 2, 341,7'98, filed March 22, 2001 for New uoly inductions of poly energy turbines

26) Patent application No. 2,341,801, filed March 22, 2001 for Synthesis ~: lobal of single blade inductive pop motors

27) Patent application No. 2,340,950, filed March 22, 2001, for Differential polyturbine

28) Patent application r ~ o 2,340, 954, filed March 16, 2001, for mounting will be transmïttifs of ~ oly induction motors rétrorotative Cinguième series patents Note: all of these ~, if; mandes are ready for deposit

29) Patent application v. Anadienne, filed July 9, 2001, 2,354,200 for Energy engine with retroactive injection

30) Energy pedal

31) Dual-energy motor

32) Ideal cylindrical shapes for poly inductive motors

33) Energy-efficient coffee maker:

34) Power machines; ~ simplified ideal forms 3 5) Driving machines: ~ ideal forms simplified II and widespread 36) Straight wind turbines 37) Piston engine with ang attack, ulaire 38) Poly inductive supports for rocker machines split 39) Complicity of post and retro machine structures 4 ~ U) Retroactive injection engines II
4.1) Pump machine figures 4.3) Self-pumped energy machine 1 4 ~ 4) Ideal shape driving machine III
45) Self pumped machine II
46) Polycored gears 47) Bi-rotativ polyinductible machine 48) Poly inductive machine with horizontal piston 49) Final synthesis of poly inductive machines 50) Poly inductive machines with supports by structured gears 51) Combination of semi turbines, poly turbines, meta turbines 52) Differential semiturbine II
S3) Poly inductive machines by equidistant supports 54) Final synthesis of poly inductive machines II
55) Geometric upgrade of poly inductive machines rWe therefore think that there is enough material to estimate it the name of retro rotati: f '~, i any engine whose driving faction se_ rproduced in the opposite direction to that of la-hale, We think, of ~ read, guc; , this material is sufficiently elaborate ~~ our legitimize the name of rotary post, for machines whose pale has its dynamics in the raw sense that of its motorization, and in which the blade also work ra ~ dement ue its motorisatüon, whereas in its rry version; ~ roo inductive it works three times more slowly .
We ~ ensense that the mayiè ~~ e is also sufficient to speak of machine inductive pole in the ~ rinç; ipaux following directions. ~.
-_ a) like machines ~ n which the ~ aale is actuated dynamically by more than one means of motorization combination b) in which the means of motorization put in combination allow dynamic combination of retro and post rotary jibs machine l Brief description of the works L, a Figure 1 shows the diver ~ y types of supports developed by ourselves, prior to the present, ipermettarlt: to support the parts of retro and post rotary machines; s in general, ~ (eur first state, as in their second state, such as ~: ~ c> ly turbines this metaturbines.
I, a figure 2 recalls one dc: v ires methods of blade guide and shows how to get better torque by off-center the hoop gear.
I, a figure 3 recalls the method of mounting by poly cam gear I, a figure 4 shows the various types of machines to which the same mounting methods can be applied.
r ~ a Figure 5 recalls that pouir gears of the same size, the moving closer or farther away: point of attachment points from the center induction gears introduces a geometric variant which allows to harden or soften: ïr the resulting shape l ~ a Figure 6 shows that if the ~: ~ r ~ subtracts from fà, we equal a certa> lle value to a post rotative form, we flatten this form.
I, a figure 7 shows, mechanic: luement, that occurs when the motorization is produced from the outside, the same resulting form can Be produced, but this fors elongated, since the geometric component d ~ c ~ blade tip is produced this time around the interior. This way of doing things can therefore be applied to retro and post rotary machines, as well as poly turbines l ~ a Figure 8 shows a variant of the last form obtained, this .cariant being midway v, between this one and the kinds of cylinders in ball already offered by nor. ~ s themselves for the type of dil support:
f ~ polycamed gears.

L, a figure 9 proposes a first way to support the blade, by supports by equidistant polycamed gears here rc; rotary I, a figure 10 shows a similar method of supports, this time by post rotary supports. These are two ways of producing support introduce the idea of hybrid polycam supports.
I, in Figure 11 shows the central stroke of the blade, and this time proposes a cerntral support method, using polycamid equidistant gears I, a figure 12 also proposes a method of central support, but tette times retrorc ~ tatïve.
I ~ a Figure 13 completes the figure, by proposing a method of guidance directional of the blade pa.r polycamera rack gear L, a figure 14 pushes further the notion of polycamé gear, in applying the concept of hybridity, allowing to produce the forms even more pronounced balloons and rectangles.
I ~ a Figure 15 shows that we can also apply The idea of machines rotary non-circular center with semi semifinals> ~~ already differential developed by us-memo, and to produce semi turbines with strong compressive capacity. .
Figure 16 shows that the case of sernitcrrbines with a non-circular center can also be applied to machines whose cylinders are also not circular.
ï ~ detailed description of the figures L, a figure 1 shows the various types of supports developed by ourselves, prior to the present., allowing to support the parts of retro and post rotary machines in general, <i. their original state, like at second state ovens, such as looly turbines ~ all metaturbines.
please consult all of our work for further details on each of the dL methods which are as follows a) by mono rotary induction b) by poly inc: luction c) by hoop gear d) by gear ~ g ~ e intermediate e) by overlapping ~. superimposed internal ages f) by juxtaposed internal gears g) by engrena ~, E ~ polycamés h) by intermediate hoop gear i) by poly ~ cams equidistant uges j) by gear structures k) by engrenn.ges eccentriqueç;
1) by poly in ~~ single luction m) by off-center hoop gears n) by poly inw: encircled and external luction All these methods can also be applied, producing them however with gear <> of external support to post machines inductive, as well as poly turbines, semiturbines and motors with pistons and rotor cylinder Figure 2 recalls, as acquired knowledge necessary for the present, one of these metl ~ o ~ of guide of rotary blade, by example here the hoop gear method, can be used in reversing the gears .. In this method, the center of the blade is supported by an eccentric or preferably by the crankpin of a crankshaft 1. as for its c ~ rr ~ oriental friendliness, it is obtained by the participation of three gears, i.e. the induction gear of blade 2, fixedly connected to blade, the support gear, connected fixed way to the side of the engine, and a trc ~ isi ~ me gear, that l, ('~ n will say hoop gear 4 rotatably mounted on the crankshaft sleeve key such a way to connect these first two gears. 11 should be noted that this gear can be. replaced by cane; chain 6..Lastly, by adding a third gear, a ~; free e 7, ~ '~ an will produce an angulation of the blade attack on the system 8. In this example, the rotation of the crankshaft 9 drives a retro rotation dc hoop gear 1 ~ which s ~ e transmits to the blade by e; rut ~ delivery of sari p ~ rc ~ pre gear. 11 On consult our previous work on this subject for an assessment more depth.
IJa figure 3 recalls, as acquired knowledge necessary for the presents, the method of morphing by polycame gears In this method, we re ~ wient to the mono inductive way of achieving retro and post rotary machines. However we will put in combination of so-called polycamed gears, which awaited the complicity of their eccentricities dwells ° have coupled throughout their rotation.
deformations will reproduce a form of blade movement which although similar to that achieved by standard gears, will produce accelerations and decelerations: ~ t blade ions that will allow figures more ; Appropriate. In the case for example of post rotary machines, one will change from a standard cylinder shape 12 to a cylinder shape in a balloon 13, or again in a: almost rectangular cylinder shape.
In b of the same figure, dc ;; ~ ,, f ~ ngrenages pol ~~ camés are used for a triangular I3oorang engine type retrodrotative machine. one can by these gears either sharpen the shape of the cylinder, or ~ even more rounded. In lc: in two cases we increase the compression of this type of machine L, a figure 4 shows the various types of machines to which the same mounting methods can be applied. mainly, we note the rotor cylinder machines a), the rotary machines and post rotary b) poly-structure machines of the poly turbine type c) differential machines d), irregular cylinder machines of metaturbine type I, FIG. 5 recalls that for gears of the same size, the approximation or distance ~; ~ n ~ ent of the attachment points of the center The induction gears introduce a geometric variant which allows to harden or soften:, ir ~ the resulting form I ~ a Figure 6 us more lorécisément in the subject of this invention. In this one we show that if we subtract from a curve given, for example that of the cylinder of a rotary engine, a value equal geometric, we flatten this shape.
I ~ a Figure 7 shows, mechanically, this occurs when the motorization is produced from outside, for example using two c; nsemble poly inductive arranged in superposition 14, leading a rod 15 connected to the blade ï 6 ~ or to the palic structure 17.
tThis way of doing things, because it lengthens the length of the amplitude of the fluctuation of the blade tip will define a cylinder shape <rllongée which will allow ph ~ o ~ ctuire much more compression and by consequently to produce the post rotary diesel type. In c of the same figure, we can ape; rceroir the diverse positions of the pale lice that same type of machine.
t, the same resulting form is then produced, but this time so Elongated, since the geometric aorta with blade tip is produced this time inside the mechanical system and not towards 'exterior .. This way of: fa ~ ïre can therefore be applied to retro and post rotary machines, as well as poly turbines L, a figure 8 shows how to modify this new shape of cylinder, this variant being at rrli chea ~ nin between this one c ~ i and the kinds of cylinder in a balloon already offered by ourselves ~ and recalled ~ in Figure 3, for 1c: type of support known as polycammed gears. what we can notice, this figure is lin ° ~ ite between retro machines, post rotary and linear. Indeed, the shape of the cylinder seems to have two curvatures 18 such a post rotary form ~ e ~. However, the point of the blade stops 19 in right in the middle of this curvature, which would force us to interpret this arc like, in reality two identical consecutive arcs. The machine would have then four sides and not two ~ and would be dcmc. rather retroactive, according to our law of sides .. Finally, the central stroke of the blade is finally fairly straight 20, which brings this machine closer to conventional piston piston I, a figure 9 proposes a first way of supporting the blade, by supports by polycamid equidistant gears, here retro-rotating:
Three polycamed inductiorw gears 21 will be mounted on rotating on the crank pins, '22 of a crankshaft. The focal point of each of these gears 2;: 3 will be connected to the piston. hes gears induction will be coupled to a support gear also polycamed 4, and recalling, according to the lc, ~ i gears. equidistant, the shape of the cylinder The pivoting of the induction gears will cause the piston exactly in the desired shape. The vilehrequïn will transmit the outside power by ~ Kn central axis.
Interesting fact: the positioning of ZSpermettre candles an angular explosion on the piston blade. . The push will indeed tractive on point to and active and angled on points b and c.
Figure 10 shows a similar method of support, this time by post rotary supports. These two ways of producing support introduce the idea of hybrid polycam supports. In and ~ and, We note that here the support mesh is external 26. As for c, induction gears, they will have a form; quite particular, in that that they will be polycamed in the two dry. 11 s will indeed be both eccentrics 28 and incentrics 29. This is why they will be called polycamed hybrids. Since we can ~;, note that this machine can be motivated as much by external as internal gears, we gild that it is of birative type. In general, one can produce a form retro-rotary by standard retro-rotary gears, or post rotary gears poh ~ oamé and vice versa a post shape standard rotary by en ~; r ~ en rotages post rotary ~ standard and retro-rotating polycamé. In this case, polycamerous gears are always required, because the machine. ny, t higher level, level which would require several superimposed poly induction to achieve it holyinductively with standard gears.
I ~ a Figure 11 reveals more prëc ~ ïsëment the originality of the central race of this type of machine. Which unlike post and retro machines rotary is similar to ceLlc; cylinder 30, not circular 31. As the central stroke is similar to that of the points, we can use mechanical similar to those already proposed to support the axis c; entral., as shown in b ..
I ~ a figure 12 proposes it aLKSSi a method of central support, but this time in a retroactive manner, a method which will seem to us, first view give more dc :; ~ power ~, since forces, rather than to be blocked will produce levers. The procedure used here will be therefore similar to that found in our rectilinear motors and in our poly turbines. Uncv r> ïelle crankshaft or induction rod 32 will be fitted with an induction gear and rotatably mounted on the crankpin of a crankshaft ov on an eccentric 33. It is like in several of our retroactive machines, we see that when the blade is at are extremity, the downward force produced; by explosion 34 product leverage on the 3 S gears and retroactively activates the crankshaft 36.

L, a figure 13 completes the figure, by proposing a method of guidance directional of the blade by gear in polycamera creed. one can be wondered, in summer and expected the proximity of this blade machine piston machines if there is. really need to guide the rotary displacement of the latter, fairly minimal. Corn, if it turns out necessary, the connection of an e; rn ~; ronage of "round induction 37 to two polycarbonate rack gears 38 will certainly solve the problem in the most simple and efficient way.
Figure 14 pushes further the notion of en ~ polycamé renage, in applying the notion of hybndï ~ t, allowing to produce the forms even more pronounced balloons and rectangles.
('was this figure, although something: little less jitter than the previous ones, if the control of the blade orientation is absolutely necessary ~ be advantageous. The double pc ~ lycame will allow the blade to lift in the center of its displacement, which will bring it closer to the ideal shape.
In addition, during the explosion, the crankshaft or the eccentric will be at a angular position 40, contrary to those on standard rotary machines and closer to poly turibï ~ nes.
Figure 15 shows that we can also apply the idea of machines rotary non-circular center with semi turbines said ~ iérentielles already developed by ourselves, and produce semi turbine with strong ~~ compressive capacity. .Dan, ~> aa simplest version, we assume here a central part 41 mounted; rotating in the center of the machine virtual or real, and each la, ~ 42, ratta <~ héc ~ at its end higher 43 at the top of this rotating part. Then suppose poly inductive assemblies: -, pre-ered ~ ment mounted on this part central, so as to work in combination with it producing non-circular races .l. ~ the blades will be attached by the low poly mechanics inc: luctives. Of course, as for polyturbines, all mecanics: poly inductive aniques cannot be applicable in such a sil: uation, and this insofar as we mean do not use flexible blades. The two attachment points must therefore remain equidistant. L:) polycamed gears will ensure possibility of making the machine. In this case, the acceleration and decelerations of the central parts compared. at the constant speed of upper parts of the blades will force tlexion 44 and straightenings 45 blades which will increase or decrease the size of the spaces between these; thus allowing explosions and expansions expansions In figure b, we realize; one of the mi ~ lt ~ ples f "rmes that can:
perform the central strokes of these machines. The form here achieves allows two sequences of f (t: ~ xion and deployment of the blades 46.
Figure 16 takes this matter further and shows that the case semiturbines with a noncircular center can also be applied to machine whose cylinders are also bare circular. To do this, we will need two sets of poly inductive bones per blade, each performing one of the two curvatures.

Claims

claims Claim 1 A poly inductive machine in the sense of generalized acceptances made herein, using alone or in combination one or more blade guide and motorization means listed by us -same in all of our work Claim 2 A machine as claimed in 1, the central support of which is not circular Claim 3 A machine as described in 1, the blade of which has a quasi-shape triangular, and the cylinder is balloon-shaped, so that the explosion can occur at each end of the movement on a only on both sides of the pal at a time Claim 4 A machine such as in 1, and 2, are the poly inductive supports are made by the ends of the blades and by so-called polycamed gears Claim 5 A machine as defined 1, 2, the support of the blade is by the center, by a polycoupled poly inductive assembly claim 6 A machine as defined 1, 2, the support of the blade is by the center, by a poly rotary inductive assembly, comprising a induction rod Claim 7 A machine as described in 5.6, whose orientational part of the ple is ensured by a set of induction and support gears, the induction gear which can be characterized as polycamered rack gears A machine as described in 1, whose balloon shape of the cylinder is obtained by a mono inductive realization of the machine, but however realized with hybrid polycamera gears in combination Claim 8 A machine as defined in 3, made with several blades and differentially, each of these blades having a central stroke non-circular and a circular outer stroke, the combination of these races producing deflections and straightening of blades causing the compressions and expansions necessary for the explosion Claim 9 A machine, as defined in 7, whose outer stroke of the blades is not circular at the ends, but different, so as to produce the desired effects.