DE102015203788A1 - Internal combustion engine with a device for pulse charging and method for operating such an internal combustion engine - Google Patents

Abstract

Internal combustion engine with at least one cylinder, in which each cylinder has at least one inlet opening, wherein an intake pipe (1a) of the intake system (1) connects to each inlet opening and each inlet opening is equipped with a valve to obstruct the inlet opening or in the context of a charge exchange and a device (2) for impulse charging with at least two pivotable flaps (3a, 3b) is provided, in which - the at least two flaps (3a, 3b) diametrically opposite and each with a stationary leg to form a bearing (6a, 6b) are mounted on a wall (1b) of the intake system (1), - the at least two flaps (3a, 3b) each in a closed position with a free leg opposite the stationary leg on a support serving as support and along the intake system (1) a web longitudinal axis (7b) passing through the web (7a) and close the intake system (1), and - the at least two flaps (3a, 3b) in an open position release the intake system (1), wherein - each flap (3a, 3b) on the free leg is provided with at least one permanent magnet (4a, 4b), the orientation of the Magnetic fields of the permanent magnets (4a, 4b) of the at least two flaps (3a, 3b) with respect to the web (7a) is diametrically opposite, and - the web (7a) is equipped with an energizable coil (7c).

Description

• – die mindestens zwei Klappen diametral gegenüberliegend und jeweils mit einem ortsfesten Ende unter Ausbildung einer Lagerung an einer Wandung des Ansaugsystems gelagert sind,
• – die mindestens zwei Klappen in einer Schließstellung jeweils mit einem dem ortsfesten Ende gegenüberliegenden freien Ende an einem als Auflager dienenden und das Ansaugsystem entlang einer Steglängsachse durchquerenden Steg aufliegen und das Ansaugsystem verschließen, und
• – die mindestens zwei Klappen in einer Offenstellung das Ansaugsystem freigeben.

The invention relates to an internal combustion engine having at least one cylinder, wherein each cylinder has at least one inlet opening for supplying fresh air via the intake system, wherein each inlet opening is followed by a suction line of the intake system and each inlet opening is provided with a valve to obstruct the inlet opening or release in the context of a charge exchange, and a device for impulse charging is provided with at least two pivotable flaps, in the

• - The at least two flaps are diametrically opposite and each mounted with a stationary end to form a bearing on a wall of the intake system,
• - The at least two flaps in a closed position in each case with a stationary end opposite the free end of a serving as a support and the intake system along a longitudinal web axis crossing web and close the intake system, and
• - The at least two flaps in an open position release the intake system.

Furthermore, the invention relates to a method for operating the device for pulse charging of such an internal combustion engine.

In the context of the present invention, the term internal combustion engine includes diesel engines and gasoline engines, but also hybrid internal combustion engines that use a hybrid combustion process, as well as hybrid drives, which in addition to the internal combustion engine include an electric motor that can be connected to the engine, which receives power from the internal combustion engine or as switchable auxiliary drive additionally delivers power.

In recent years, there has been a trend toward small, supercharged engines, with supercharging primarily a method of increasing performance by compressing the air needed for the engine combustion process. The economic importance of these engines for the automotive industry continues to increase.

Frequently, an exhaust gas turbocharger is used for charging, in which a compressor and a turbine are arranged on the same shaft. The hot exhaust stream is supplied to the turbine and relaxes with energy release in the turbine, causing the shaft to rotate. The energy emitted by the exhaust gas flow to the turbine and finally to the shaft is used to drive the compressor, which is also arranged on the shaft. The compressor conveys and compresses the charge air supplied to it, whereby a charging of the cylinder is achieved. Advantageously, a charge air cooler is provided downstream of the compressor in the intake system, with which the compressed charge air is cooled before entering the at least one cylinder. The radiator lowers the temperature and thus increases the density of the charge air, so that the cooler to a better filling of the cylinder, d. H. contributes to a larger air mass. There is a compaction by cooling.

The advantage of an exhaust gas turbocharger compared to a mechanical supercharger is that there is no mechanical connection to the power transmission between the supercharger and the internal combustion engine or is required. While a mechanical supercharger obtains the energy required for its drive completely from the internal combustion engine and thus reduces the power provided and thus adversely affects the efficiency, the exhaust gas turbocharger uses the exhaust gas energy of the hot exhaust gases.

The charge is - as already mentioned - the increase in performance. The air required for the combustion process is compressed, which allows each cylinder per working cycle, a larger air mass can be supplied. As a result, the fuel mass and thus the medium pressure can be increased.

The charge is a suitable means to increase the capacity of an internal combustion engine with unchanged displacement or to reduce the displacement at the same power. In any case, the charging leads to an increase in space performance and a lower power mass. If the displacement is reduced, the load spectrum can be shifted to higher loads, where the specific fuel consumption is lower.

Charging thus supports the constant effort in the development of internal combustion engines to minimize fuel consumption, d. H. to improve the efficiency of the internal combustion engine.

The design of the exhaust turbocharger often causes difficulties, in principle, a noticeable increase in performance in all speed ranges is sought. In the prior art, however, a torque drop is observed when falling below a certain speed. This torque drop becomes understandable if it is taken into account that the boost pressure ratio depends on the turbine pressure ratio. For example, if the engine speed is reduced, this leads to a smaller exhaust gas mass flow and thus to a smaller turbine pressure ratio. This has the consequence that at lower speeds the boost pressure ratio and the boost pressure also decrease, which is synonymous with a torque drop.

The torque characteristic of a supercharged internal combustion engine can be improved by using multiple turbochargers, for example, by several parallel turbines of smaller turbine cross-section, with successively connected turbines with increasing exhaust gas, or by means of several series-connected exhaust gas turbocharger, of which an exhaust gas turbocharger as a high pressure stage and an exhaust gas turbocharger serves as a low pressure stage.

In addition to charging by means of an exhaust gas turbocharger and / or mechanical supercharger, the so-called impulse charging is known from the prior art, in which the intake line of a cylinder can be closed upstream of the inlet opening by means of a device or is temporarily closed. During the charge change, the intake line initially remains closed when the intake valve is open, so that an underpressure builds up progressively downstream of the device as part of the intake stroke. If the intake is then released suddenly by opening the device, the negative pressure accelerates the air column located in the intake, which enters the cylinder with a high pulse. In this way, the filling of the cylinder is increased by means of pulse charging. The effects are those already described in connection with the turbocharger. By means of pulse charging, in particular the torque characteristic of the internal combustion engine can be improved at low speeds. In particular, the pulse charging device must have fast switching times and sufficient tightness to accomplish effective pulse charging.

A device for pulse charging describes, for example, the German Offenlegungsschrift DE 199 08 435 A1 , As with the device of the type mentioned, two pivotable flaps are provided, which are mounted diametrically opposite and each with a stationary end to form a bearing on a wall of the intake system. The two flaps are formed as thin soft iron sheets and lie in a closed position each with a stationary leg opposite the free leg on serving as a support and the intake system along a web longitudinal axis traversing web, whereby the intake system is closed. The two flaps are biased by spring elements in the closed position and held by magnetic fields in the closed position. The magnetic fields are generated by energizable coils, which are integrated in stationary belonging to the flaps frame parts near the storage of the flaps.

As part of the intake stroke, the flaps are then opened at energized coils due to the downstream pressure acting on them. In this case, the flaps are detected by magnetic fields of other provided in the wall of the intake system energized coils and pulled into abutment, d. H. spent in full open position. If the energization of the latter coils is set with the intake valve closed, the flaps move back into the closed position as part of a pivoting movement under the influence of their spring elements.

A disadvantage of the device according to the DE 199 08 435 A1 Among other things, the flaps are opened only as a result of the attacking negative pressure and closed exclusively by means of spring elements. The coils or magnetic fields serve primarily to hold the flaps in the open position or in the closed position. As a result, the flaps can not be pivoted as desired, especially not closed against a not yet reduced vacuum.

Against this background, it is an object of the present invention to provide an internal combustion engine according to the preamble of claim 1, which has an improved pulse charging.

Another object of the present invention is to provide a method of operating the pulse charging apparatus of such an internal combustion engine.

• – die mindestens zwei Klappen diametral gegenüberliegend und jeweils mit einem ortsfesten Schenkel unter Ausbildung einer Lagerung an einer Wandung des Ansaugsystems gelagert sind,
• – die mindestens zwei Klappen in einer Schließstellung jeweils mit einem dem ortsfesten Schenkel gegenüberliegenden freien Schenkel an einem als Auflager dienenden und das Ansaugsystem entlang einer Steglängsachse durchquerenden Steg aufliegen und das Ansaugsystem verschließen, und
• – die mindestens zwei Klappen in einer Offenstellung das Ansaugsystem freigeben, die dadurch gekennzeichnet ist, dass
• – jede Klappe an dem freien Schenkel mit mindestens einem Permanentmagneten ausgestattet ist, wobei die Orientierung der Magnetfelder der Permanentmagnete der mindestens zwei Klappen bezüglich des Stegs diametral entgegengesetzt ist, und
• – der Steg mit einer bestrombaren Spule ausgestattet ist.

The first sub-task is solved by an internal combustion engine having at least one cylinder, wherein each cylinder has at least one inlet opening for supplying fresh air via the intake system, wherein a suction line of the intake connects to each inlet opening and each inlet opening is equipped with a valve to the inlet opening to be blocked or release in the context of a charge exchange, and a device for impulse charging is provided with at least two pivotable flaps, in which

• - The at least two flaps are diametrically opposite and each mounted with a stationary leg to form a bearing on a wall of the intake system,
• - The at least two flaps in a closed position in each case with a stationary leg opposite the free leg on a serving as a support and the intake system along a longitudinal web axis crossing web and close the intake system, and
• - The at least two flaps in an open position release the intake system, which is characterized in that
• - Each flap on the free leg is equipped with at least one permanent magnet, wherein the orientation of the magnetic fields of the permanent magnets of the at least two flaps is diametrically opposite with respect to the web, and
• - The bridge is equipped with an energizable coil.

Starting from the closed position, the flaps of the device according to the invention are opened by the coil of the web is energized and in the direction that the magnetic field of the coil repels the magnetic fields of the permanent magnets and thus the flaps. The fact that the orientation of the flap-associated permanent magnets and their magnetic fields is diametrically opposite, the flaps can be pivoted with the energization of a single coil and transferred to the open position. The intake system is released in this way.

As in the prior art, the opening operation of the flaps is assisted in the context of an intake stroke by a negative pressure built up downstream of the flaps. In contrast to the prior art, however, the opening of the flaps is not accomplished solely by means of negative pressure, but actively controlled and forced by energizing the coil of the web.

This allows on the one hand, the realization of comparatively short opening times and thus an effective pulse charging and on the other hand opening the valves regardless of the present pressure downstream of the flaps. Consequently, the flaps can also be opened several times during a change of charge with the cylinder open on the intake side, in order to release the intake system several times, which can be advantageous.

Starting from flaps located in the open position, the flaps can be brought into the closed position by the energization of the coil of the web is terminated. Since the permanent magnets of the flaps tighten because of their diametrically opposite orientation, the associated flaps pull each other into the closed position. Consequently, no spring elements or return springs must be provided, which bias the flaps toward the closed position and pivot.

If the energization of the coil of the bridge is not only terminated, but vice versa, the magnetic field of the coil attracts the permanent magnets of the flaps and actively supports the closing of the flaps. This allows the realization of comparatively short closing times.

With the internal combustion engine according to the invention, the object underlying the invention is achieved, namely an internal combustion engine provided which has an improved pulse charging.

According to the invention, the permanent magnets of the flaps are oriented differently, so that the orientation of the magnetic fields of these permanent magnets is diametrically opposite. Reference is made to the field lines between the south pole and the north pole of the magnets. In the present case, this means that the south pole of the permanent magnet of a flap faces the bridge and the north pole of this permanent magnet is facing away from the bridge, while the south pole of the permanent magnet of the other flap faces away from the bridge and the north pole of this permanent magnet faces the bridge (see also figure description) , By reversing the current direction in the coil of the web, the flaps can be tightened once and repelled another time.

Further advantageous embodiments of the internal combustion engine are discussed in connection with the subclaims.

Embodiments of the internal combustion engine in which the web is streamlined in the flow direction are advantageous, so that the web of the air flow guided in the intake system offers the least possible resistance and the pressure loss in the flow direction over the web is as low as possible.

In the context of the present invention, the direction of flow is the main flow direction of the air flow in the intake system, ie. H. the direction in which the air essentially flows. In general, the flow direction is predetermined by the center axis of the intake pipe or the intake system.

In this context, embodiments of the internal combustion engine in which the web has a lenticular or elliptical profile in a section transverse to the web longitudinal axis are advantageous.

Advantageous embodiments of the internal combustion engine, in which the Bestrombare coil of the web has a winding transverse to the flow direction. According to the invention of a winding transversely to the flow direction, if the longitudinal axis of the coil is aligned transversely to the flow direction or runs.

The pulse charging device according to the invention requires a certain orientation of the coil and its winding. To be able to generate a magnetic field with the coil, with which the permanent magnets can be repelled and the flaps can be pivoted, the longitudinal axis of the coil must be aligned transversely to the flow direction and perpendicular to the web longitudinal axis.

Then, the magnetic field of the energized coil is aligned in such a way that one flap of the south pole and the other opposing flap faces the north pole and vice versa in reverse current direction.

In this connection, therefore, embodiments of the internal combustion engine in which the winding of the coil is a winding about a virtual axis which runs perpendicular to the web longitudinal axis are also advantageous.

Embodiments of the internal combustion engine in which the web is rotatably mounted and rotatable about the web longitudinal axis are advantageous. If the web then still has a certain extent transverse to the web longitudinal axis, for example because the web has a lenticular profile, the web has a flap-like shape and can be used by means of twisting to charge movement. An increased charge movement in the intake system or in the cylinder supports the mixture preparation, in particular the homogenization of the cylinder fresh charge.

Embodiments of the internal combustion engine in which at least one flap is manufactured using fiber-reinforced plastic are advantageous.

Unlike the flaps of the DE 199 08 435 A1 , which also assume the function of an anchor as a thin soft iron sheets and are magnetically formed, the flaps according to the invention need not be made of magnetic materials.

This circumstance can be used advantageously, for example by making the flaps using fiber reinforced plastic. Such flaps have a weight advantage over soft iron sheets, which offers advantages in terms of pivoting times or adjustment times. In addition, a made of plastic and therefore elastic flap ensures a high density of the device in the closed position of the flaps. Under certain circumstances, the flap has such a high elasticity that the flap is kinked during the opening during the pivoting or the pivoting operation is a buckling of the flap, so that a flap part is pivoted about an axis in the flap. Such flaps would then inherently a spring element immanent. In other words, the spring element would already be an integral part of the flap, without which an additional component would have to be provided and mounted.

Embodiments of the internal combustion engine in which the web is manufactured using at least one magnetic material are advantageous. As a result, the magnetic field of the current coil of the web and thus the attractive and repulsive field forces could be strengthened. It can ferromagnetic materials are used, which contain so-called elemental magnets that are aligned in Weis'schen districts parallel to each other or can be aligned. This means that an external magnetic field twists the direction of the elementary magnets in the ferromagnetic material so that they are parallel to the external magnetic field. Alternatively, paramagnetic materials can be used which, unlike ferromagnetic materials, have non-zero magnetization only as long as they are in an external magnetic field.

Embodiments of the internal combustion engine in which each flap is equipped with a spring element which forces the flap towards the closed position are advantageous. Even if such spring elements are not required due to the principle according to the invention, such spring elements can be used to support the closing process.

In this connection, embodiments of the internal combustion engine in which the spring element is formed integrally with the flap are advantageous, so that the flap and the spring element form a monolithic component. In addition to the already described plastic flap with buckling capability, which is intrinsically inherent in a spring element, the flap could also be deformable, for example, as a leaf spring be bendable. A flap in the form of a leaf spring could be immovably mounted with a stationary leg on the wall of the intake system, d. H. be fixed. Since no movable storage, but only a fixed storage is required, storage simplifies considerably.

Embodiments of the internal combustion engine in which a refuelable auxiliary coil in the wall of the intake system is provided for each flap downstream of the storage are advantageous. The auxiliary coils can take on a wide variety of tasks.

Starting from flaps located in the open position, the flaps can be brought into the closed position by the auxiliary coils are energized in such a way that the magnetic fields of the auxiliary coils repel the magnetic fields of the permanent magnets and thus move the flaps in the closed position.

If the current supply of the auxiliary coils is reversed, the magnetic field of the auxiliary coil attracts the associated flap and actively supports the opening of the flap. This can help to shorten the opening hours.

The auxiliary coils can also be used to hold the flaps in the open position.

Embodiments of the internal combustion engine in which the intake system passing through the device for charging the impulse is designed as a vibration tube are advantageous. In this case, the length of the vibration tube is usually designed for a specific speed range in which a particularly good filling is to be achieved, for example, to the lower speed range of the internal combustion engine, which often has a poor torque characteristics. Under certain circumstances, the vibration tube is variable in length, designed for example as a switchable vibration tube.

Embodiments of the internal combustion engine in which the intake system has a rectangular cross section in the region in which the device is provided for pulse charging are advantageous. A rectangular or polygonal cross section simplifies the geometry of the device, in particular the flaps considerably.

The second sub-task on which the invention is based, namely to disclose a method for operating the device for pulse charging an internal combustion engine of the type described above, is achieved by a method characterized in that, starting from flaps located in the closed position, the coil of the web in the Is energized type that repel the magnetic field of the coil and the magnetic fields of the permanent magnets of the flaps, whereby the flaps are transferred to the open position and the intake system is released.

The comments made in connection with the internal combustion engine according to the invention also apply to the inventive method.

Advantageous are process variants in which the at least one inlet opening is released by actuating the associated valve for the purpose of charge exchange before the coil of the web is energized.

Advantageous are process variants in which the coil of the web is energized at least twice during the charge cycle in order to release the intake system at least twice.

Advantageously, process variants in which, starting from located in the open position flaps the energization of the coil of the web is terminated, whereby the flaps are transferred to the closed position and the intake system is closed.

Process variants can also be advantageous in which, starting from the flaps located in the open position, the current of the coil of the web is reversed, so that the magnetic field of the coil attracts the permanent magnets of the flaps, whereby the flaps are transferred to the closed position and the intake system is closed.

For operating a device in which an energizable auxiliary coil in the wall of the intake system is provided for each flap downstream of the storage process variants are advantageous, which are characterized in that the auxiliary coils are energized in such a way that the magnetic field of an auxiliary coil and the Magnetic field attract the at least one permanent magnet of the associated flap, whereby the transfer of the flaps is supported in the open position and / or the flaps are held in the open position.

For operating a device in which an energizable auxiliary coil in the wall of the intake system is provided for each flap downstream of the storage, process variants can also be advantageous, which are characterized in that the auxiliary coils are energized starting from flaps located in the open position in that the magnetic field of an auxiliary coil and the magnetic field of the at least one permanent magnet of the associated flap repel, whereby the flaps are transferred to the closed position and the intake system is closed.

In the following the invention is based on an embodiment according to the 1a . 1b and 2 described in more detail. Hereby shows:

1a 2 schematically shows a section of the intake system and the device for pulse charging in the closed position according to a first embodiment of the internal combustion engine, partially in half section,

1b schematically the in 1a shown device for impulse charging in the open position, partially in half section, and

2 schematically the coil of the web in the 1a and 1b illustrated device for pulse charging.

1a schematically shows a portion of the intake system 1 and the device in the closed position 2 for pulse charging according to a first embodiment of the internal combustion engine, partially in half section.

The device 2 for impulse charging comprises two pivotable flaps 3a . 3b diametrically opposed and each with a stationary leg to form a bearing 6a . 6b on a wall 1b of the intake system 1 are stored. The two flaps 3a . 3b lie in the in 1a illustrated closed position each with a stationary leg opposite the free leg on a web 7a at. The rotatably mounted web 7a , which has a lenticular and thus streamlined profile, serves the flaps 3a . 3b as a support and passes through the intake system 1 along its longitudinal axis 7b , in the 1a is perpendicular to the drawing plane and around the the bridge 7a is rotatable. The intake system 1 is present through the flaps 3a . 3b locked.

Every flap 3a . 3b is on its free leg with a permanent magnet 4a . 4b equipped, the orientation of the magnetic fields of these permanent magnets 4a . 4b concerning the footbridge 7a is diametrically opposed. The jetty 7a itself is with an energizable coil 7c equipped with which a magnetic field to open the device 2 can be generated (see also 2 ). Because the permanent magnets 4a . 4b the flaps 3a . 3b Attracting themselves due to their diametrically opposite orientation, the associated flaps pull 3a . 3b in the case of a de-energized coil 7c each other in the closed position, whereby the tightness of the device 2 is increased in the closed position.

Starting from the in 1a shown closed position of the flaps 3a . 3b becomes the coil 7c of the footbridge 7a energized for the purpose of impulse charging in such a way that the magnetic field of the coil 7c and the magnetic fields of the permanent magnets 4a . 4b repel, causing the flaps 3a . 3b be transferred to the open position and the intake system 1 is released.

1b schematically shows the in 1a illustrated device 2 for impulse charging in the open position, partially in half section. The two flaps 3a . 3b give in the open position the intake system 1 free.

For every flap 3a . 3b is downstream of their storage 6a . 6b a refillable auxiliary coil 5a . 5b in the wall 1b of the intake system 1 provided, which can be used differently. The energized auxiliary coils 5a . 5b For example, the flaps 3a . 3b hold in the open position. With suitable energization of the auxiliary coils 5a . 5b pulls the magnetic field of the auxiliary coil 5a . 5b the associated flap 3a . 3b and in this way supports the opening process of the flap 3a . 3b ,

Starting from the in 1b Open position shown, the flaps 3a . 3b be transferred to the closed position by the auxiliary coils 5a . 5b be energized in the way that the magnetic fields of the auxiliary coils 5a . 5b and the magnetic fields of the permanent magnets 4a . 4b repel, causing the flaps 3a . 3b be moved to the closed position.

Here are the flaps 3a . 3b bendable, leaving the flaps 3a . 3b Have an integral spring element, which supports the closing process, ie the associated flap 3a . 3b biased toward the closed position or force applied. The flaps 3a . 3b can therefore be fixed and immobile by means of fixed storage 6a . 6b on the wall 1b of the intake system 1 stored, ie fixed. This simplifies storage 6a . 6b considerably. With suitable energization of the coil 7c of the footbridge 7a pulls the magnetic field of the coil 7c the flaps 3a . 3b and in this way supports the closing of the flaps 3a . 3b ,

2 schematically shows the coil 7c of the footbridge 7a in the 1a and 1b illustrated device 2 for impulse charging. The energizable coil 7c has a winding around a virtual axis 7d , which simultaneously the longitudinal axis 7d the coil 7c represents. This longitudinal axis 7d runs in the 1a and 1b transverse to the flow direction and perpendicular to the web longitudinal axis 7b such that the south pole S of the magnetic field is the permanent magnet 4a the one flap 3a and the north pole N of the magnetic field to the permanent magnet 4b the other door 3b facing (see also figure description). By reversing the current direction in the coil 7c This orientation of the magnetic field changes so that the flaps 3a . 3b once dressed and repelled another time.

LIST OF REFERENCE NUMBERS

1

 intake system

1a

 suction

1b

 Wall of the intake system

2

 Device for pulse charging

3a

 first flap

3b

 second flap

4a

 Permanent magnet of the first flap

4b

 Permanent magnet of the second flap

5a

 energizing auxiliary coil of the first flap

5b

 energizable auxiliary coil of the second flap

6a

 Storage of the first flap

6b

 Storage of the second flap

7a

 web

7b

 Longitudinal axis of the bridge

7c

 energizable coil of the bridge

7d

 Longitudinal axis of the coil of the web, virtual axis of the winding

N

 North Pole

S

 South Pole

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 19908435 A1 [0013, 0015, 0036]

Claims (20)

Internal combustion engine having at least one cylinder, in which each cylinder has at least one inlet opening for supplying fresh air via an intake system, wherein an intake line (15) is provided to each inlet opening (11). 1a ) of the intake system ( 1 ) and each inlet port is provided with a valve to obstruct the intake port or to release it in the context of a charge exchange, and a device ( 2 ) for impulse charging with at least two pivotable flaps ( 3a . 3b ), in which - the at least two flaps ( 3a . 3b ) diametrically opposite and each with a stationary leg to form a storage ( 6a . 6b ) on a wall ( 1b ) of the intake system ( 1 ), - the at least two flaps ( 3a . 3b ) in a closed position, each with a stationary leg opposite the free leg on serving as a support and the intake system ( 1 ) along a web longitudinal axis ( 7b ) crossing web ( 7a ) and the intake system ( 1 ), and - the at least two flaps ( 3a . 3b ) in an open position the intake system ( 1 ), characterized in that - each flap ( 3a . 3b ) on the free leg with at least one permanent magnet ( 4a . 4b ), wherein the orientation of the magnetic fields of the permanent magnets ( 4a . 4b ) of the at least two flaps ( 3a . 3b ) concerning the bridge ( 7a ) is diametrically opposed, and - the bridge ( 7a ) with an energizable coil ( 7c ) Is provided. Internal combustion engine according to claim 1, characterized in that the web ( 7a ) is streamlined in the flow direction. Internal combustion engine according to claim 2, characterized in that the web ( 7a ) in a section transverse to the web longitudinal axis ( 7b ) has a lenticular profile. Internal combustion engine according to one of the preceding claims, characterized in that the energizable coil ( 7c ) of the bridge ( 7a ) has a winding transverse to the flow direction. Internal combustion engine according to claim 4, characterized in that the winding of the coil ( 7c ) a winding around a virtual axis ( 7d ), which is perpendicular to the web longitudinal axis ( 7b ) runs. Internal combustion engine according to one of the preceding claims, characterized in that the web ( 7a ) is rotatably mounted and about the web longitudinal axis ( 7b ) is rotatable. Internal combustion engine according to one of the preceding claims, characterized in that at least one flap ( 3a . 3b ) is made using fiber reinforced plastic. Internal combustion engine according to one of the preceding claims, characterized in that the web ( 7a ) is made using at least one magnetic material. Internal combustion engine according to one of the preceding claims, characterized in that each flap ( 3a . 3b ) is equipped with a spring element which the flap ( 3a . 3b ) is subjected to force in the direction of the closed position. Internal combustion engine according to claim 9, characterized in that the spring element integral with the flap ( 3a . 3b ) is formed so that the flap ( 3a . 3b ) and the spring element form a monolithic component. Internal combustion engine according to one of the preceding claims, characterized in that for each flap ( 3a . 3b ) downstream of the storage ( 6a . 6b ) an energizable auxiliary coil ( 5a . 5b ) in the wall ( 1b ) of the intake system ( 1 ) is provided. Internal combustion engine according to one of the preceding claims, characterized in that the device ( 2 ) for impulse charging through the intake system ( 1 ) is designed as a vibration tube. Internal combustion engine according to one of the preceding claims, characterized in that the intake system ( 1 ) in the area where the device ( 2 ) is provided for impulse charging, has a rectangular cross-section. Method for operating the device ( 2 ) for impulse charging an internal combustion engine according to one of the preceding claims, characterized in that starting from located in the closed position flaps ( 3a . 3b ) the sink ( 7c ) of the bridge ( 7a ) is energized in such a way that the magnetic field of the coil ( 7c ) and the magnetic fields of the permanent magnets ( 4a . 4b ) of the flaps ( 3a . 3b ), whereby the flaps ( 3a . 3b ) are transferred to the open position and the intake system ( 1 ) is released. A method according to claim 14, characterized in that the at least one inlet opening is released by actuation of the associated valve for the purpose of charge exchange before the coil ( 7c ) of the bridge ( 7a ) is energized. Method according to claim 14 or 15, characterized in that the coil ( 7c ) of the bridge ( 7a ) is energized at least twice during the charge cycle to 1 ) at least twice. Method according to one of claims 14 to 16, characterized in that, starting from located in the open position flaps ( 3a . 3b ) the energization of the coil ( 7c ) of the bridge ( 7a ), whereby the flaps ( 3a . 3b ) are transferred to the closed position and the intake system ( 1 ) is closed. Method according to one of claims 14 to 16, characterized in that, starting from located in the open position flaps ( 3a . 3b ) the energization of the coil ( 7c ) of the bridge ( 7a ) is reversed so that the magnetic field of the coil ( 7c ) the permanent magnets ( 4a . 4b ) of the flaps ( 3a . 3b ), whereby the flaps ( 3a . 3b ) are transferred to the closed position and the intake system ( 1 ) is closed. Method according to one of Claims 14 to 18 for operating a device for pulse charging, in which for each flap ( 3a . 3b ) downstream of the storage ( 6a . 6b ) an energizable auxiliary coil ( 5a . 5b ) in the wall ( 1b ) of the intake system ( 1 ), characterized in that the auxiliary coils ( 5a . 5b ) are energized in such a way that the magnetic field of an auxiliary coil ( 5a . 5b ) and the magnetic field of the at least one permanent magnet ( 4a . 4b ) of the associated flap ( 3a . 3b ), whereby the transfer of the flaps ( 3a . 3b ) is supported in the open position and / or the flaps ( 3a . 3b ) are held in the open position. Method according to one of claims 14 to 19 for operating a device for pulse charging, wherein for each flap ( 3a . 3b ) downstream of the storage ( 6a . 6b ) an energizable auxiliary coil ( 5a . 5b ) in the wall ( 1b ) of the intake system ( 1 ) is provided, characterized in that, starting from located in the open position flaps ( 3a . 3b ) the auxiliary coils ( 5a . 5b ) are energized in such a way that the magnetic field of an auxiliary coil ( 5a . 5b ) and the magnetic field of the at least one permanent magnet ( 4a . 4b ) of the associated flap ( 3a . 3b ), whereby the flaps ( 3a . 3b ) are transferred to the closed position and the intake system ( 1 ) is closed.

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