DE102016108743A1 - Internal combustion engine with a rotatable about its axis rotor - Google Patents

Abstract

Internal combustion engine (1) with a rotor (2) which is rotatable about a rotation axis (3). The rotor (2) has three working spaces (5), which are divided by slides (12, 13, 14, 31) at three points of a housing (9) into subspaces. After admission, a working gas in front of two slides (13, 14) abutting one another, compressed, displaced into a working gas reservoir (22) between the two slides (13, 14) from which the working gas after further rotation of the rotor (2) back into the Working space (5) flows where it is burned and drives the rotor (2). According to the invention, a working gas reservoir is provided which can be completely emptied by means of a disk.

Description

The invention relates to an internal combustion engine having a housing and a rotor arranged in the housing, wherein the rotor is rotatable about an axis of rotation and has at least one recess on its circumference, which extends over a limited peripheral portion, at both ends of the rotor on an inner wall the housing and which includes a working space between the rotor and the inner wall of the housing, wherein the housing is formed with a circular and concentric to the rotor inner cross-section and having an inlet and an outlet for a working gas. In this case, the housing has a first inwardly and outwardly movable separator, which is arranged between the inlet and the outlet, wherein the first separator rests on the circumference of the rotor and the at least one working space divides when the at least one working space in the region first disconnector is located. In addition, the housing has a further inwardly and outwardly movable second separator, which rests on the circumference of the rotor, the at least one working space divides when the at least one working space is in the region of the second separator, and which is arranged such that it is located in the area of the at least one working space when the at least one working space communicates neither with the inlet nor with the outlet. In addition, the housing has a working gas storage, in which the rotor displaces working gas from the at least one working space when a subspace of the at least one working space in the direction of rotation of the rotor before the second separator decreases with rotating rotor, and from which the working gas in the direction of rotation Rotor behind the second separator flows back into the at least one working space. In the internal combustion engine, the working gas burns in the at least one working space in the direction of rotation of the rotor behind the second separator, wherein the at least one working space is separated from the working gas storage during combustion. For this purpose, the working gas storage on a gas control, wherein the second separator comprises at least two valves for controlling gas control, and include slide of the two slide valves the working gas storage.

A generic internal combustion engine is disclosed in the publication WO 2012/130226 A1 known. This discloses an internal combustion engine with a rotor which is rotatable about a rotation axis. The rotor preferably has three working spaces, which are divided by trained as a slide separator at three points of a housing in subspaces. After the inlet, a working gas in front of two sliders of a separator, which abut each other compressed, displaced in a working gas storage between the two sliders, from which the working gas after further rotation of the rotor flows back into the working space, where it is burned and drives the rotor.

In this known internal combustion engine recesses of the rotor form the working spaces, these being of a bottom of the recesses, symmetrically arranged on the rotor cam-like raised areas, an inner wall of the housing at the raised points in the system, and of the separators or sliders of the housing are formed. Two of these three working spaces supply compressed working gas, while combustion takes place in the third working space. A disadvantage is considered that the transfer of the working gas in the used for combustion subspace of the working space, which is arranged in the direction of rotation of the rotor behind the second separator, is heavily lossy. This is essentially due to the removal of the working gas reservoir from this subspace and by the slide valves used for the gas control. The closer the working gas reservoir is in each case to the partial space of the working space provided for combustion of the working gas, the shorter and more effective the disadvantageous supply line becomes. In addition, the duration of the filling process of the corresponding subspace is considered to be hindering especially at high speeds. The opening, filling and closing of the working gas reservoir takes so much time that the boost pressure for the combusting subspace of the working space is reduced.

Based on the above-mentioned prior art, the present invention seeks to propose a way that causes a more effective filling and emptying of the working gas storage and thus leads to improved efficiency of the internal combustion engine.

This object is achieved by an internal combustion engine having the features of the independent claim 1. Further preferred embodiments of the invention can be found in the dependent claims.

Thereafter, the internal combustion engine according to the invention, with a housing and a rotor disposed in the housing, which is rotatable about a rotation axis, an inwardly and outwardly movable second separator having at least two slide valves, each with a slide for gas control, wherein the slide the two slide valves include the working gas storage together with a third slide. In this case, the third slide is displaceably guided between and along the other two slides and designed as a gas shifter for stored in the working gas storage working gas. He is between the two sliders of the two Slider valves relative to the working gas reservoir arranged slidably so that it determines the volume of the working gas storage. He can change this volume between a maximum and a minimum capacity, the third slide displaced there during insertion into the working gas storage befindliches working gas from the working gas storage and when running from the working gas storage allows the inflow of working gas in the working gas storage. The third slide is in the working gas storage this preferably completely raumausfüllend displaced, so that the capacity working gas storage can be reduced to zero. In this case, the third slide in its cross-sectional shape is preferably completely adapted to the geometry of the working gas reservoir. so the working gas storage is completely emptied.

These three slides of the second separator are controlled by the rotation of the rotor and / or the rotation of the shaft to which the rotor is connected. This can be mechanical or derived from the rotor or electronically. Preferably, the sliders become desmodromic, i. guided by force control. By radial lowering / lifting of the three Scheiber relative to the working space of the working gas reservoir is filled in his working direction rotating rotor and emptied.

The internal combustion engine according to the invention has in accordance with that of WO 2012/130226 A1 known prior art, a rotor and a housing having a circular and concentric with the rotor inner cross section, wherein an imaginary axis of the circular inner cross section is an axis of rotation of the rotor. In particular, the housing has a cylindrical inner circumference. Conceivable, however, are other, for example, spherical or hollow inner walls of the housing or a hollow cone or two or more hollow cones with opposite cone angles. The circular inner cross-section of the housing of the internal combustion engine according to the invention allows a bearing of the rotor inside the housing with a rotating only about the axis of rotation rotor without this must also move radially in an orbit or otherwise.

Basically, it is about a rotation of the rotor relative to the housing, it may also rotate the rotor and the housing rotatably or even both the rotor and the housing, but with different speeds and / or in different directions rotate. When reference is made below to a rotation of the rotor, a rotation of the rotor relative to the housing and in a direction of rotation is meant.

The rotor of the internal combustion engine according to the invention has at least one recess on its circumference, which extends over a limited peripheral portion. Viewed in the circumferential direction of the rotor is located at both ends of the recess on the inner wall of the housing, the system in principle, for example, with sealing strips, as they are known in the Wankel engine can take place. At least one working space is formed by the at least one recess on the circumference of the rotor, which is bounded on the outside by the inner wall of the housing and on the inside by the rotor or a base of the recess of the rotor. Laterally, the recess may be limited for example by end walls of the housing of the internal combustion engine or side walls of the recess of the rotor.

Upon rotation of the rotor in the intended direction of rotation of the work space formed by the recess of the rotor runs around. Here, a working gas successively performs the known from a four-stroke internal combustion engine power strokes inlet, compression, combustion and expansion and exhaust, wherein combustion and expansion are regarded as a power stroke. The four acts are assigned as in a Wankel engine four peripheral portions of the housing. The inlet may be a suction or an influx of a compressed gas from a compressor, turbocharger or the like. The combustion can be initiated by auto-ignition or spark ignition as known from internal combustion engines. The working gas may already be a combustible gas or gas mixture at the inlet, wherein the gas mixture may also be a mixture of one or more gases and one or more liquids and one or more solids.

The working gas may also be non-combustible and a combustible material (fuel) are supplied only before or during combustion, as is known for example from the diesel engine.

The housing of the internal combustion engine according to the invention has an inlet and an outlet for the working gas, which are circumferentially offset from each other and preferably adjacent, i. in the circumferential direction have little distance from each other to have the largest possible part of the circumference for the power strokes available.

Furthermore, the internal combustion engine has two separators, a first of which is arranged between the inlet and the outlet. Another second disconnector is arranged between the first disconnector and an ignition or spark plug in the direction of rotation of the rotor in front of the glow plug or spark plug. The two separators are movable inwards and outwards and share the at least one working space in two subspaces, if the at least one working space is in the area of the respective disconnector. In the direction of rotation of the rotor is the one part of the working space in front of the separator and the other behind the separator. During the rotation of the rotor, the volume of the subspace, which is in the direction of rotation of the rotor in front of the separator, decreases, and the volume of the subspace in the direction of rotation behind the separator increases. The separators are in particular slides, which are guided in the housing, for example, pivotally and / or displaceably movable inwardly and outwardly on a straight or a non-straight path, wherein the direction of movement may be radial, but need not be. For example, the separators are urged inwardly against the rotor by spring loading so that they move inwardly as a working space enters their area upon rotation of the rotor. If a bottom of the working space at the end of it again rises outward to the inner wall of the housing, the separator moves back outward. The further second separator is offset in the circumferential direction and arranged so that the at least one working space communicates neither with the inlet nor with the outlet when the further separator is in the region of the at least one working space. Between the other separator and the one separator, combustion and expansion of the working gas take place. Between the first separator and the second separator inlet and compression of the working gas.

In addition, the internal combustion engine according to the invention has a working gas storage, in which the working gas passes between the compression and the combustion. During its rotation, the rotor displaces the working gas from the subspace of the working space, which is the direction of rotation of the rotor before the other second separator and whose volume is reduced by the rotation of the rotor, in the working gas storage. When displacing from the working space in the working gas storage, the working gas is preferably, but not necessarily, further compressed. From the working gas storage, the working gas flows back into the working space, preferably in the same working space from which it has been previously displaced in the working gas storage, but in the subspace of the working space, which is located behind the second separator in the direction of rotation and its volume by the rotation of the rotor increases. After flowing from the working gas storage in the working space, the working gas is burned in the working space. The pressure generated by the combustion of the working gas drives the rotor in rotation, it acts in the circumferential direction between the other separator and a front in the direction of rotation of the rotor end of the at least one working space, whereby the combustion pressure of the working gas causes a torque to the rotor.

The internal combustion engine according to the invention has the advantage that it has no reciprocating masses. The movement of the rotor is exclusively a rotation without imbalance provided the rotor has no such. The exclusive rotation of the rotor allows the cross-sectionally circular, in particular hollow cylindrical inner cross section of the housing, whereby the housing is simple and thus inexpensive to produce. Another advantage of the invention is a relatively uniform rotation of the rotor. Another advantage is the simple mechanics of the internal combustion engine according to the invention with the rotatable rotor and the two separators, i. the first and second separators, as moving parts, the invention does not exclude additional moving parts, such as a third inwardly and outwardly movable separator.

Another advantage of the internal combustion engine according to the invention is a linear enlargement of the volume of the subspace of the working space in the direction of rotation of the rotor behind the other second separator, in which the combustion takes place. The linear volume increase appears favorable for a uniformly spreading flame front or a uniform volume increase of the working gas due to the combustion. The linear volume increase of the subspace of the working space in which the combustion takes place should contribute to a good efficiency of the internal combustion engine.

An additional advantage of the internal combustion engine according to the invention is a large lever arm, with which the pressure of the combustion working gas acts on the rotor, namely in its outer region. The separators of the internal combustion engine can be replaced without disassembling the engine from the outside. Conceivable is a hydrodynamic bearing of the rotor in the housing.

The internal combustion engine according to the invention is provided in particular for hydrogen or a mixture of natural gas and hydrogen as fuel, which flows either mixed with air and / or oxygen as working gas through the inlet or in the direction of rotation of the rotor only after the second separator, ie for combustion, in the at least one working space or flows into the working gas storage, for example, is injected.

The internal combustion engine has a gas control for the displacement of the working gas from the at least one working space in the working gas storage and / or from the working gas storage in the at least one working space. The gas control may include one or more valves, the movement of which is, for example, mechanically derived from or from the rotor or electronically controlled. The list is not finally. For this purpose, the second separator on at least two slide valves. Preferably, slides of the slide valves, for example, spring-loaded inwardly pressed against the rotor and mechanically moved during the rotation of the rotor and thereby controlled. The slides of the two slide valves include the working gas reservoir. For example, at least one of the two slides has a recess which is covered by the other slide and forms the working gas reservoir. The recess is preferably elongated and preferably extends in the longitudinal direction in at least one of the slides of the two slide valves, the working gas storage. The third slide closes together with the other two slides of the second separator the working gas storage. In this case, the third slide is slidably guided along the other two slides and inserted into the at least one working gas storage recess of the two slides of the slide valves of the second separator. It is preferably adapted to the cross-sectional shape of the elongated recess and acts as a gas shifter for the working gas stored in the working gas storage. It is in particular longitudinally displaceable back and forth between the two slides of the two slide valves in the recess forming the working gas reservoir.

The filling of the working gas reservoir takes place as follows. First, a raised position of the rotor moves to the second separator with the gas control, in which the three sliders provided include the working gas storage. The front in the direction of rotation slider of the two slide valves is lowered down to the bottom of the working space of the rotor and the rear in the direction of rotation slide of the two slide valves from the bottom of the working space. He is withdrawn to the inner wall of the housing from the working space. The third slide is also retracted relative to the other two slides, so that it does not close the recess provided in one or both slides of the slide valves as a working gas storage laterally. In this position, working gas can flow into the at least one slide of the two slide valves provided recess upon rotation of the rotor, since the working gas storage can communicate with the arranged in the direction of rotation before the second separator rear compartment of the working space. The working gas reservoir forms a unit with the rear compartment in this state. With the further movement of the raised portions of the rotor, the rotor pushes the working gas located in the rear part of the space in the working gas storage, while the working gas, advantageously without flow through another spatially remote valve or an additional connection channel, i. directly into the working gas storage. The closure of the working gas storage takes place at the moment when the rear in the direction of rotation raised position of the rotor, which limits the rear compartment in the direction of rotation rear, reaches the slide of the front spool valve and lifts it from the bottom of the working space to the inner wall of the housing. The compressed working gas is now enclosed in the working gas storage and thus stored there. The two slides of the slide valves are now at the same distance from the inner wall and are not above this. Behind the moving further raised position of the working space of the rotor initially lowers in the direction of rotation front slide of the two slide valves down to the bottom of the working space of the rotor, wherein between the raised position of the rotor and the rear slide in the direction of rotation a front part space in the direction of rotation as a combustion chamber forms. The other rear slider remains meanwhile withdrawn. After the front slide of the two slide valves has reached the bottom of the working space, the third slide, which moves in the direction of the bottom of the working space, which initially moves into the recess of the rear slider, it increasingly fills and thus located there Working gas displaced into the newly formed, enlarging front part of the working space. If the third slide emptied the recess of the rear slider, the rear slider in the direction of rotation is then lowered together with the third slide, which acts as a gas exhauster, to the bottom of the working space. In this case, the third slide fills more and more the recess of the front slide and thereby displaces the working gas located there completely in the front part of the working space. At this moment, all three slides of the second separator touch the bottom of the working space of the rotor and form a massive partition, which opposes the now occurring combustion and its combustion pressure.

An embodiment of the invention provides that the first separator has a slide valve for controlling the gas inlet of the working gas in the at least one working space, wherein the slide valve is connected on one side to the inlet of the housing for the working gas and a slide of the slide valve an inlet channel for the working gas has in the at least one working space. When pushing the slide of the first separator in the direction of the bottom of the working space, an access for the working gas from the inlet of the housing to the direction of rotation front partial space is created, which persists until the slider is withdrawn or pushed back from the working space. This also has the advantage that a faster and thus more effective filling of the working space is done with working gas. This leads in particular at high speeds of the Motors to a higher boost pressure for the working gas storage and thus to an improved efficiency of the internal combustion engine. An inlet channel of the slider of the first separator opens out of the slider in the direction of a front edge in the direction of rotation of the rotor.

Preferably, the rotor of the internal combustion engine according to the invention on three equally shaped and uniformly distributed over the circumference arranged recesses, which include three working chambers between the rotor and the inner wall of the housing. Three equally distributed over the circumference arranged working chambers, each extending over slightly less than 120 ° in the circumferential direction, seem ideal for a synchronization and high efficiency of the internal combustion engine. Deviations both in the number of working chambers as well as in their distribution and / or extension over the scope as well as their shape does not exclude the invention.

An embodiment of the invention provides that the base of the at least one recess in a peripheral portion extends in a circular arc and concentric with the axis of rotation of the rotor. This allows a sealing abutment of the separator at the bottom of the recess when the separators are designed, for example, as a slide. In the circumferential direction at both ends of the circular arc-shaped portion, the bottom of the at least one recess of the rotor rises outwardly to the inner wall of the housing. In particular, at the front end of the at least one recess in the direction of rotation, its base rises steeply outward as far as the inner wall of the housing or, viewed inversely, slopes steeply from the inner wall to the arcuate section of the base. This section of the bottom of the recess, which extends from the inner wall of the housing to the circular arc-shaped portion of the bottom of the recess, is hereinafter also referred to as the front edge of the recess. The steepness of the flank of the recess is limited by a maximum speed at which the two separators of the front, in the direction of rotation of the rotor from the inner wall of the housing inwardly to the arcuate portion of the bottom of the recess falling edge of the recess can follow. At the rear end of the recess in the direction of rotation, its base preferably rises more flatly up to the inner wall of the housing, in order to keep the acceleration of the separators provided low. The at the rear in the direction of rotation of the rotor rear end of the recess to the inner periphery of the housing rising portion of the bottom of the recess is also referred to as the trailing edge.

An embodiment of the invention provides a double compression. For this purpose, the rotor has at least two recesses on its circumference, which are offset in the circumferential direction to each other and include at least two working spaces between the rotor and the inner wall of the housing. Preferably, the work spaces adjoin one another in the circumferential direction and are separated from each other only by a point at which the rotor rests against the inner wall of the housing between the work spaces. This also applies to a rotor with more than two recesses and more than two working spaces. An additional, outwardly and inwardly movable third separator is arranged in the direction of rotation of the rotor behind the one first and before the other second separator. The third separator divides a working space, which is located in its area, into two subspaces. In the area of the additional third separator is a working space in the direction of rotation of the rotor behind the first and before the second separator. Based on the four power strokes of the internal combustion engine, the further second separator is in the peripheral portion in which the working gas is compressed. An overflow line connects a working space, which connects in the region of the additional third separator, with a working space, which is located in the direction of rotation of the rotor behind the additional and before or in the region of the other second separator. Strictly speaking, the overflow connects the subspace of a working space, which is in the direction of rotation of the rotor in front of the third separator, with the subspace of the other working space, which is in the direction of rotation of the rotor in front of the second separator. The overflow line can be closed. If the overflow line is open, displaces the working space, which is located in the region of the additional separator, with a rotation of the rotor working gas from the subspace, which is in the direction of rotation of the rotor in front of the additional third separator, in the working space, located in the another second separator is located, in its subspace, which is in the direction of rotation in front of the second separator. Because both subspaces reduce their volumes during the rotation of the rotor, the compression of the internal combustion engine increases, in particular, it doubles. The internal combustion engine has in this embodiment of the invention an additional inlet for the working gas in the direction of rotation of the rotor behind the additional separator, through which the working gas flows in the direction of rotation of the rotor behind the additional third separator in the working space. If only a small compression is desired, the overflow is closed and it compresses only the working space in the direction of rotation of the rotor behind the third separator and before the second separator. The working space in front of the additional third separator is vented so that it does not build up any pressure that would slow the rotor.

A further embodiment of the invention provides that the third separator a Slider valve for controlling the gas inlet of the working gas in the at least two working spaces, wherein the slide valve is connected on one side with a further second inlet of the housing for the working gas and a slide of the slide valve has a further inlet channel for the working gas in the at least one working space. When pushing the slide of the third separator in the direction of the bottom of the working space access for the working gas from the second inlet of the housing for working gas to the front in the direction of rotation partial space is created, which also remains until the slide is withdrawn from the working space or is pushed back. This also has the advantage that a faster and thus more effective filling of the working space is done with working gas. An inlet channel of the slide of the third separator opens out of the slide in the direction of a front edge in the direction of rotation of the rotor.

An embodiment of the invention provides for cooling the working gas in the direction of rotation of the rotor behind the first and before the other second separator. Preferably, the inner wall of the housing is cooled in this area. In this area, the working gas is compressed and thereby heats up. The cooling of the working gas is comparable to the charge air cooling of an internal combustion engine with a mechanical compressor or turbocharger with the proviso that in the internal combustion engine according to the invention, the working gas is cooled in the engine and must not be led to the outside to cool. The cooling of the working gas during the compression allows a higher compression and improves the efficiency. In addition, it reduces thermal stress on the internal combustion engine. The same purpose is a cooling of the overflow, if one exists. The double compression enables effective intercooling of the working gas in the overflow line, thereby reducing the thermal load on the internal combustion engine, allowing for an increase in total compression from the inlet of the working gas to the flow into the working gas reservoir at the end of the compression or until the start of combustion. As a result, the efficiency of the internal combustion engine can be increased.

A further development of the invention provides an internal combustion engine with a plurality of rotors which are arranged coaxially next to one another, preferably on a common shaft, in a manner fixed against relative rotation. The rotors are angularly offset from each other, which means that their working spaces are offset from each other in the circumferential direction. Preferably, the offset is chosen so that the work spaces are distributed as evenly as possible over the circumference, which means that the four working cycles, which can also overlap, are evenly distributed to achieve the most even running of the rotors. The working gas is separate in the work spaces, the work spaces do not communicate with each other. The offset of the rotors is possible, for example, by a shaft with a profile, for example a polygonal shaft, a wave profile, a splined profile or the like, and a complementary hole profile of the rotors.

An embodiment of the invention provides a fuel inlet, for example a fuel injection, into the working gas reservoir, into which the compressed working gas flows. This embodiment of the invention extends a period of time that is available for a mixture of the working gas with the fuel until the beginning of the combustion. In addition, the mixing of the working gas with the fuel is improved by turbulence of the working gas when flowing from the working gas storage in the working space in the direction of rotation of the rotor behind the other second separator where the combustion takes place.

An embodiment of the invention provides for a design of the internal combustion engine as a glow starter motor. This refinement is provided in particular for operation of the internal combustion engine with hydrogen or a fuel which burns with similar rapidity or as part of the fuel. This embodiment of the invention simplifies the internal combustion engine because it does not require controlled ignition.

The spatially closed working gas storage, in which working gas can be collected from one or more work spaces, has clear advantages over a conventional turbocharger, with which the working gas storage can be compared in its function. The controlled working gas storage works independently of speed, requires no bypass, has no so-called turbo lag, generates a higher boost pressure at all speeds, has a simple structure. It works with engine speed, stores compressed working gas with the help of the previous ignition energy and causes by the direct compression increased internal efficiency.

The invention will be explained in more detail with reference to an embodiment shown in the drawing. The four figures show a radial section of an internal combustion engine according to the invention with different rotational positions different rotational positions of a rotor and different working gas conditions. The drawing is to be understood as a simplified, not to scale schematic representation for explanation and understanding of the invention.

The drawing is to be understood as a simplified and schematic representation for understanding and explaining the invention.

The illustrated in the drawing, the internal combustion engine according to the invention 1 has a rotor 2 on, around a rotation axis 3 is rotatable. The rotor 2 has three recesses 4 at its periphery, the workrooms 5 form. The recesses 4 are distributed uniformly over the circumference, that is offset by 120 ° to each other and extend in the circumferential direction over a little less than 120 °. A reason 6 the recesses 4 runs in a circumferential middle section 7 circular arc-shaped and concentric with the axis of rotation 3 , At a front end in the direction of rotation, the ground rises 6 the recesses 4 relatively steep, but not radial, outward to an inner wall 8th a housing 9 of the internal combustion engine 1 , At a rear end in the direction of rotation, the ground rises 6 the recesses 4 of the rotor 2 flatter outward to the inner wall 8th of the housing 9 , The direction of rotation of the rotor 2 , Which means a given direction of rotation, is indicated in the drawing with the circular arc arrow P. The to the inner wall 8th of the housing 9 rising sections of the reason 6 the recess 4 are also referred to as front and rear flanks 35 . 36 designated.

The inner wall 8th of the housing 9 is cylindrical and concentric with the axis of rotation 3 of the rotor 2 , The rotor 3 lies at three sublime places 10 between his recesses 4 , flat and sealing on the inner wall 8th of the housing 9 with "sealing" is not necessarily meant a hermetically sealed system, but rather a good compromise between a good sealing effect, which allows a good compression and combustion with low pressure losses with low frictional resistance and low wear.

The recesses 4 of the rotor 2 close the workrooms 5 between the rotor 2 inside and the inner wall 8th of the housing 9 outside. Close to the side end walls 11 of the housing 9 the workrooms 5 ,

In the case 9 There are five sliders 12 . 13 . 14 . 38 . 31 guided radially displaceable, wherein at least the slider 12 . 13 . 14 . 31 of optional spring elements 15 . 16 . 17 . 32 inside against the rotor 2 or the reason 6 his the workrooms 5 forming recesses 4 be charged. The five sliders 12 . 13 . 14 . 38 . 31 form three separators 18 . 19 . 27 that the workrooms 5 when they are in the area of the slider 12 . 13 . 14 . 38 . 31 or at least the slides 12 . 13 . 14 . 31 in the workrooms 5 are divided into two subspaces, one of which is in the direction of rotation P of the rotor 2 before and the other behind the separator 18 . 19 . 27 located.

The disconnectors 18 . 19 . 27 are circumferentially offset by about 120 ° to each other. A first separator 18 the three separators 18 . 19 . 27 is located between an inlet 20 and an outlet 21 , wherein in the direction of rotation P of the rotor 2 the inlet 20 over the first separator 18 indirectly and the outlet 21 immediately before the first disconnector 18 directly into the respective workspace 5 lead. The first separator 18 has a slide valve for controlling the gas inlet of the working gas in the at least one working space 5 on, with the inlet 20 connected, with a slider 12 the slide valve at its periphery an inlet channel 39 for the working gas in the at least one working space 5 having. The entrance channel 39 is so outside of the slider 12 arranged that a connection from the inlet 20 to the workroom 5 only exists when the slider 12 moving inwards, especially at the bottom 6 the working space 5 forming recess 4 is applied. The entrance channel 39 flows out of the slide 12 in the direction of a front edge in the direction of rotation 35 of the rotor 2 ,

The spring-loaded slides 12 . 13 . 14 . 31 lie sealingly on a circumference of the rotor 2 or at the bottom 6 the recesses 4 at. The seal is not necessarily hermetically sealed but as it is to the places 10 at which the rotor 2 between the recesses 4 on the inner wall 8th of the housing 9 is present, has been described.

The two other sliders 13 . 14 lie against each other at least on the outer circumference and form together with the additional third Scheiber 38 another second separator 19 , which is about 240 ° in the direction of rotation P of the rotor 2 offset to the first separator 18 is arranged. Inside, the two further slide 13 . 14 Recesses on which a working gas storage 22 Make that on the rotor 2 axially facing away from the third slide 38 is limited. With the third slider 38 controlled in the working gas storage trapped working gas controlled completely from the working gas storage 22 in the workroom 5 displace. Mutually facing inner edges of the two other slides 13 . 14 are of oblique grooves 23 broken, not the entire inner face of the slider 13 . 14 break through.

In the direction of rotation P of the rotor 2 points the internal combustion engine 1 just behind the second separator 19 a glow plug 24 to a self-ignition.

It is also possible auto-ignition, as is known from diesel engines, or a spark ignition with a spark plug, as it is known from Otto and Wankel engines. The fifth slider 31 is here as an additional slider 31 denotes, it forms an additional third separator 27 , He is about 120 ° to the other sliders 12 . 13 . 38 . 14 or separators 18 . 19 in the case 9 arranged in the direction of rotation P of the rotor 2 behind the one slider 12 and before the other sliders 13 . 14 . 38 and in the circumferential direction approximately in a middle between the other sliders 12 . 13 . 14 , in the longer peripheral portion between the other sliders 12 . 13 . 14 , The additional slider 31 is thus arranged in the area in which the working gas is compressed.

In the direction of rotation P of the rotor 2 close to the additional slider 31 goes overflow line 28 starting in the direction of rotation P of the rotor 2 a piece in front of the other sliders 13 . 14 . 38 in a workroom 5 empties. The overcurrent line 28 runs in the illustrated embodiment advantageously completely in the housing 9 , However, this is not necessarily so. The overflow line 28 is with a switching valve 33 closable, close to an orifice of the overflow line 28 in the workroom 5 in front of the three other sliders 13 . 14 . 38 is arranged. With this switching valve 33 is also the workspace 5 in the direction of rotation P of the rotor 2 in front of the additional slider 31 vented. Another inlet 29 in a workroom 5 is near the additional fifth slider 31 intended. The further inlet 29 opens in the direction of rotation P of the rotor 2 over the third separator 27 indirectly in a workroom 5 , The third separator 27 has a slide valve for controlling the gas inlet of the working gas in the at least one working space 5 on, with the inlet 29 connected, with a slider 31 the slide valve at its periphery an inlet channel 40 for the working gas in the at least one working space 5 having. The entrance channel 40 is so outside of the slider 31 arranged that a connection from the other inlet 29 to the workroom 5 only exists when the slider 31 moving inwards, especially at the bottom 6 the working space 5 forming recess 4 is applied. The entrance channel 40 flows out of the slide 31 in the direction of a front edge in the direction of rotation 35 of the rotor 2 ,

As the working gas, air is provided, as fuel, a mixture of hydrogen and natural gas in the ratio of about 1: 2. An operation of the internal combustion engine 1 using only hydrogen as fuel is also possible. In principle, other gases, such as oxygen as working gas and liquid fuels such as gasoline, diesel or kerosene, combustible gases or combustible solids, such as coal dust, as a fuel, or mixtures of such substances are possible.

The internal combustion engine according to the invention 1 works on the four-stroke principle, its function and the states of the working gas in one of the working chambers 5 are subsequently during a rotation of the rotor 2 described. Upon rotation of the rotor 2 in the intended direction of rotation P working gas flows through the inlet 20 in one of the workrooms 5 that is in the area of the inlet 20 located, one ( 1 ). A volume of the subspace of the workspace 5 in the direction of rotation of the rotor 2 behind the first separator 18 increases by the rotation of the rotor 2 so that the internal combustion engine 1 the working gas sucks. However, it is also a charged combustion engine 1 possible, ie that the working gas is under pressure and into the working space 5 flows. During the rotation of the rotor 2 passes over one of the three raised places 10 of the rotor 2 at which the rotor 2 on the inner wall 8th of the housing 9 is present, the one slide 12 of the first separator 18 , this being the slider 12 pushes outward, which is behind the sublime spot 10 back inside the workroom 5 forming, in the direction of rotation P of the rotor 2 next recess 4 shifts. This opens the slide valve of the first separator 18 so that working gas from the inlet 20 over the entrance channel 39 of the slider 12 in the direction of rotation after the disconnector 18 located part of the work space 5 can flow. When driving over the slide 12 of the first separator 18 separates the sublime place 10 at the back of the workroom 5 the workroom 5 from the inlet 20 , the working gas is in the workroom 5 locked in.

The partial volume of the working space 5 in the direction of rotation P of the rotor 2 in front of the additional slider 31 shrinks by the rotation of the rotor 2 , whereby the working gas is compressed in this sub-volume and through the overflow 28 in the workroom 5 flows, which is in the direction of rotation P of the rotor 2 in front of the workroom 5 is located, from which the working gas through the overflow line 28 flows. The changeover valve 33 in the overflow line 28 is open.

Upon further rotation of the rotor 2 passes over one of the three raised places 10 of the rotor 2 at which the rotor 2 on the inner wall 8th of the housing 9 is applied, the slide 31 of the third separator 27 , this being the slider 31 pushes outward, which is behind the sublime spot 10 back inside the workroom 5 forming, in the direction of rotation P of the rotor 2 next recess 4 shifts. This opens the slide valve of the third separator 27 so that working gas from the further inlet 29 over the entrance channel 40 of the slider 31 in the direction of rotation after the separator 27 located part of the work space 5 can flow. When driving over the slide 31 of the third separator 27 separates the sublime place 10 at the back of the workroom 5 the workroom 5 from the inlet 29 , the working gas is in the workroom 5 locked in.

By the rotation of the rotor 2 increases the volume of the subspace of the working space 5 in the direction of rotation P of the rotor 2 behind the additional slider 31 , whereby the working gas is sucked. Here, too, an inflow of the working gas under pressure is possible. Upon further rotation of the rotor 2 cross the sublime spot 10 at which the rotor 2 on the inner wall 8th of the housing 9 is applied and in the direction of rotation P of the rotor 2 at the front end of the workspace 5 located, the two other slider 13 . 14 and the sublime place 10 with which the rotor 2 on the inner wall 8th of the housing 9 is applied and at the in the direction of rotation P of the rotor 2 rear end of the workroom 5 is over passes the additional slider 31 , making this working chamber 5 from the inlet 29 is disconnected. The volume of the subspace of the workspace 5 moving in the direction of rotation P of the rotor 2 before the other sliders 13 . 14 . 38 is down, shrinking. The working gas is in the working space 5 compressed.

In the workroom 5 the compressed working gas flows out of the overflow line 28 , which increases the compaction, almost doubled. The double compression can be switched off by the changeover valve 33 in the overflow line 28 in the direction of the workspace 5 closed and out to a vent 34 is open. That's the workspace 5 in direction of rotation P in front of the additional slider 31 is vented, is opened. In direction of rotation P before the additional slider 31 is not compressed by it.

While the two other sliders 13 . 14 in the circular arc-shaped middle section 7 of the reason 6 the recess 4 sealing at the bottom 6 issue ( 1 ), is due to the rising trailing edge 36 of the reason 6 of the workroom 5 only the front in direction of rotation P further slider 14 with its continuous inner edge sealing ( 2 ). The in the direction of rotation P of the rotor 2 rear further slides 13 connects through the oblique groove 23 as in 2 to see the subspace of the workroom 4 in the direction of rotation P of the rotor 2 before the other separator 19 with the working gas storage 22 between the two other sliders 13 . 14 , The two other sliders 13 , 14 move as well as in 2 to be seen by their attachment to the rising trailing edge 36 of the workroom 5 outward and against each other. By shifting the slider 13 . 14 against each other, the working gas storage closes 22 , At first the slide shifts 13 to the outside and then only the slide 14 , where before and / or with the displacement of the slider 13 . 14 the third slider 38 of the second separator 19 also moved outwards. Accordingly, the volume of the working gas storage increases 22 from the recess of the slider 14 and the slider 13 is formed together. Thus, this is due to the rotation of the rotor 2 condensing working gas from the work space 5 to the oblique groove 23 in the direction of rotation P of the rotor 2 front of the two other slides 13 . 14 and about it in the working gas storage 22 crowded. By its rotation, the rotor closes 2 then the working gas storage 22 with the compressed working gas, so this in the working gas storage 22 is included.

In a peripheral portion before the additional third separator 27 and before the other second separator 19 shows the case 9 a cooling 25 on, which is represented in the drawing by cooling fins. The cooling 25 of the housing 9 cools the working gas during compression in the work area 5 in the direction of rotation P of the rotor 2 before the third separator 27 and before the second separator 19 what a higher compression of the internal combustion engine 1 allows, thereby improving its efficiency and reduces thermal stress. In the area of the overflow line 28 shows the case 9 also a cooling shown by cooling fins 37 on.

The compression and displacement of the working gas from the working space 5 ends when the sublime place 10 in the direction of rotation P of the rotor 2 rear end of the workroom 5 the three other sliders 13 . 14 . 38 overruns. Both slides 13 . 14 lie together with the other Scheiber 38 sealing at the raised point 10 so that the working gas storage 22 both from the workroom 5 in the direction of rotation P of the rotor 2 before as well as from the workroom 5 moving in the direction of rotation P of the rotor 2 behind the sublime place 10 of the rotor 2 between the two workspaces 5 is located, is separated ( 3 ).

Through a fuel inlet 30 fuel gets into the working gas reservoir 22 injected. The fuel is hydrogen or a mixture of natural gas and hydrogen in the ratio of about 2: 1. Other fuels can also be injected. Also possible is a fuel injection into the workspace 5 in direction of rotation P behind the other sliders 13 . 14 . 38 , There may be fuel in addition or instead of in the working gas storage 22 be injected. There is also an injection of water into the workspace 5 in the direction of rotation P of the rotor 2 behind the two other sliders 13 . 14 , where the working gas is burned, to an internal cooling for the purpose of thermal relief and / or to increase the efficiency of the internal combustion engine 1 possible (not shown). The fuel injection into the working gas storage 22 and / or the working space 5 in the direction of rotation P of the rotor 2 behind the sliders 13 . 14 . 38 if done by the inlets 20 . 29 incoming working gas is air without fuel. Through the inlets 20 . 29 It is also possible for working gas, which already contains fuel, ie a mixture of air and fuel, to flow in. In this case, the injection of fuel into the working gas reservoir 22 and / or in the workroom 5 in the direction of rotation P of the rotor 2 behind the two other sliders 13 . 14 omitted. It is also conceivable, however, additional fuel in the working gas storage 22 and / or the workspace 5 in the direction of rotation P of the rotor 2 behind the other sliders 13 . 14 . 38 inject.

Upon further rotation of the rotor 2 slide the two other slides 13 . 14 again at the of the inner wall 8th of the housing 9 to the circular arc section 7 of the reason 6 of the workroom 5 falling front edge 35 of the workroom 5 along, as it is in 4 you can see. It is in the direction of rotation P of the rotor 2 rear further slides 13 with its continuous inner edge sealing at the flank 35 on, whereas the oblique groove 23 in the direction of rotation P of the rotor 2 front further slider 14 the working gas storage 22 with the workspace 5 connects, now in the direction of rotation P of the rotor 2 behind the two other sliders 13 . 14 located. Because the two other sliders 13 . 14 on the sloping front flank 35 in the direction of rotation P of the rotor 2 front end of the workroom 5 shifted against each other, opens the working gas storage 22 to the oblique groove 23 , While the rear in the direction of rotation slide 13 moving inward becomes the third slider 38 Forcibly controlled also moved inwards. The slider 38 displaces first the working gas from that part of the working gas storage 22 that of the rear slider in the direction of rotation 13 is formed. The corresponding part of the working gas flows out of this part of the working gas reservoir 22 in the subspace of the workspace 5 moving in the direction of rotation P of the rotor 2 behind the two other sliders 13 . 14 located. Continuing the rotor 2 then also slides in the direction of rotation rear slider 13 the two other sliders 13 . 14 together with the other slider 38 on the flank 35 off, with the slider 38 that's over the slider 14 laterally in the direction of the slide 14 protrudes, while the working gas from that part of the working gas storage 22 displaced, that of the front in the direction of rotation slide 14 is formed. The flow of the working gas from the working gas storage 22 in the workroom 5 ends when both more sliders 13 . 14 at the circular arc-shaped middle section 7 of the reason 6 of the workroom 5 with her the rotor 2 abut facing faces, as it 1 shows. Here is the working gas storage 22 through the further slide 38 completely emptied. The two other sliders 13 . 14 make up with the further slider 38 Thus, a gas control, which is the flow of the working gas from the at the rotation of the rotor 2 in front of the two other sliders 13 . 14 shrinking workspace 5 into the working gas storage 22 and then from the working gas storage 22 in the behind the two other sliders 13 . 14 during the rotation of the rotor 2 again enlarging working space 5 controls.

The working gas ignites when the two other slides 13 . 14 the working gas storage 22 have closed and the sublime place 10 of the rotor 2 with which the rotor 2 sealing on the inner wall 8th of the housing 9 is applied, the glow plug 24 has run over (shortly after the in 1 shown rotational position of the rotor 2 ), even on the glow plug 24 , It can also ignite in the manner of a diesel engine without glow plug itself or with a spark plug instead of the glow plug 24 to be detonated. Auto-ignition has the advantage that it does not require ignition control. The combustion of the working gas causes a pressure increase, which on the front edge 35 of the reason 7 of the workroom 5 acts and a torque on the rotor 2 causes it to its rotation drives. The working gas expands in the by the rotation of the rotor 2 increasing subspace of the workspace 5 in the direction of rotation P of the rotor 2 behind the other sliders 13 . 14 . 38 until the sublime place 10 at which the rotor 2 at the direction of rotation P of the rotor 2 front end of the workroom 5 on the inner wall 8th of the housing 9 is present, the outlet 21 has run over, leaving the work space 5 with the outlet 21 is connected and the working gas flows out. The cycle then starts again.

The described four-stroke cycle of the working gas takes place in all three working spaces 5 constantly held, so the rotor 2 is driven almost constantly to short interruptions, resulting in a relatively smooth running of the rotor 2 causes.

The movement of the four sliders 12 . 13 . 14 . 31 is determined by the contour of the rotor 2 So from the shape of the reason 6 the recesses 4 that the workrooms 5 form, and the bodies 10 between the workrooms 5 at which the rotor 2 on the inner wall 8th of the housing 9 is applied, controlled. The movement of the further slider 38 is due to the movement of the slider 13 . 14 coupled. The rotor 2 forms, so to speak, a cam which controls the movement of the slides 12 . 13 . 14 . 31 mechanically controls. This will be the movement of the third slider 38 of the second separator 19 derived. The two other sliders 13 . 14 that together with the pusher 38 the other separator 19 form at the same time also slide valves for gas control in and out of the working gas storage 22 in the manner described.

De rotor 2 is non-rotatably on a shaft by positive locking 26 added. The wave 26 has a splined profile and the rotor 2 a hole with a congruent counter profile on. The spline profile of the shaft 26 and the hole of the rotor 2 are chosen so that more rotors 2 with an angular displacement of, for example, 30 ° on the shaft 26 can be put on. The internal combustion engine 1 This can cause several rotors 2 coaxially side by side, which are separated by radial partitions. The angular offset of the rotors 2 is chosen so that the work spaces 5 the rotors 2 are offset uniformly in the circumferential direction to each other.

QUOTES INCLUDE IN THE DESCRIPTION

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Cited patent literature

• WO 2012/130226 A1 [0002, 0008]

Claims (10)

Internal combustion engine ( 1 ), with a housing ( 3 ) and one in the housing ( 3 ) arranged rotor ( 2 ), wherein the rotor ( 2 ) about a rotation axis ( 3 ) is rotatable and has at least one recess at its periphery, which extends over a limited peripheral portion, at both ends of the rotor ( 2 ) on an inner wall ( 8th ) of the housing ( 9 ) and which has a working space ( 5 ) between the rotor ( 2 ) and the inner wall ( 8th ) of the housing ( 9 ), the housing ( 9 ) with circular and to the rotor ( 2 ) is formed concentric inner cross-section and an inlet ( 20 ) and an outlet ( 21 ) for a working gas, the housing ( 9 ) a first inwardly and outwardly movable separator ( 18 ) located between the inlet ( 20 ) and the outlet ( 21 ), wherein the first separator ( 18 ) on the circumference of the rotor ( 2 ) and the at least one working space ( 5 ) if the at least one workspace ( 5 ) in the region of the first separator ( 18 ), the housing ( 9 ) a further inwardly and outwardly movable second disconnector ( 19 ), which at the periphery of the rotor ( 2 ), the at least one working space ( 5 ) if the at least one workspace ( 5 ) in the region of the second separator ( 19 ) and which is arranged such that it is located in the region of the at least one working space ( 5 ), if the at least one working space ( 5 ) with the inlet ( 20 ) with the outlet ( 21 ) communicates the housing ( 9 ) a working gas storage ( 22 ), in which the rotor ( 2 ) Working gas from the at least one working space ( 5 ) displaced when a subspace of the at least one working space ( 5 ) in the direction of rotation of the rotor before the second separator ( 19 ) with rotating rotor ( 2 ) and from which the working gas in the direction of rotation of the rotor ( 2 ) behind the second separator ( 19 ) back into the at least one workspace ( 5 ) flows, wherein the working gas in the at least one working space ( 5 ) in the direction of rotation of the rotor ( 2 ) behind the second separator ( 19 ) burns, the at least one work space ( 5 ) during combustion of the working gas reservoir ( 22 ) is separated and the working gas storage ( 22 ) has a gas control, and wherein the second separator ( 19 ) has at least two slide valves for gas control, and slide ( 13 . 14 ) of the two slide valves the working gas storage ( 22 ), characterized in that the second separator ( 19 ) a third slider ( 38 ), which together with the two other sliders ( 13 . 14 ) the working gas storage ( 22 ) and along the sliders ( 13 . 14 ) is displaceable, wherein the third slide ( 38 ) as Gasausschieber for in the working gas storage ( 22 stored working gas and between the sliders ( 13 . 14 ) opposite the working gas reservoir ( 22 ) is displaceable. Internal combustion engine according to claim 1, characterized in that the first separator ( 18 ) a slide valve for controlling the gas inlet of the working gas into the at least one working space ( 5 ), which communicates with the inlet ( 20 ), wherein a slider ( 12 ) of the slide valve has an inlet channel ( 39 ) for the working gas in the at least one working space ( 5 ) having. Internal combustion engine according to 1 or 2, characterized in that the rotor ( 2 ) three recesses distributed over the circumference ( 4 ), the three working chambers ( 5 ) between the rotor ( 2 ) and the inner wall ( 8th ) of the housing ( 9 ) lock in. Internal combustion engine according to one of the preceding claims, characterized in that the at least one recess ( 4 ) a reason ( 6 ) with a in a radial section of the rotor ( 2 ) circular arc and to the axis of rotation ( 3 ) of the rotor ( 2 ) concentric section ( 7 ), for which reason ( 6 ) of the at least one recess ( 4 ) in both circumferential directions to the inner wall ( 8th ) of the housing ( 9 ) increases. Internal combustion engine according to one of the preceding claims, characterized in that the rotor ( 2 ) at least two recesses ( 4 ) at its periphery, the at least two working spaces ( 5 ) between the rotor ( 2 ) and the inner wall ( 8th ) of the housing ( 9 ) that the internal combustion engine ( 1 ) an additional, inwardly and outwardly movable third separator ( 27 ) in the direction of rotation (P) of the rotor ( 2 ) behind the first separator ( 18 ) and before the second separator ( 13 ), which at the periphery of the rotor ( 2 ) and the workspaces ( 5 ), when they are in the area of the third separator ( 27 ), that the internal combustion engine ( 1 ) an overflow line ( 28 ), one of the working spaces ( 5 ), when in the direction of rotation of the rotor ( 2 ) behind the first separator ( 18 ), with another working space ( 5 ) connects when the other working space ( 5 ) in the direction of rotation of the rotor ( 2 ) before the second separator ( 19 ), and that the internal combustion engine ( 1 ) a further second inlet ( 29 ), which in the direction of rotation (P) of the rotor ( 2 ) behind the third separator ( 27 ) is arranged. Internal combustion engine according to claim 5, characterized in that the third separator ( 27 ) a slide valve for controlling the gas inlet of the working gas into the at least two working spaces ( 5 ), which communicates with the inlet ( 29 ), wherein a slider ( 31 ) of the slide valve a Inlet channel ( 40 ) for the working gas in the at least two working spaces ( 5 ) having. Internal combustion engine according to one of the preceding claims, characterized in that the overflow line ( 28 ) is closable and / or cooling ( 37 ) having. Internal combustion engine according to one of the preceding claims, characterized in that the housing ( 9 ) a cooling ( 25 ) in the direction of rotation of the rotor ( 2 ) behind the first separator ( 18 ) and before the second separator ( 19 ) having. Internal combustion engine according to one of the preceding claims, characterized in that the internal combustion engine ( 1 ) several, equiaxed and mutually rotatable rotors ( 2 ) whose working spaces ( 5 ) are separated from each other and offset from each other in the circumferential direction. Internal combustion engine according to one of the preceding claims, characterized in that the internal combustion engine ( 1 ) a fuel inlet ( 30 ) in the working gas storage ( 22 ) having.

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