EP0599195A1 - Inlet conduit of a combustion engine with a throttle system - Google Patents

Abstract

The intake duct (1) of an internal combustion engine has a venturi-like wall portion (8) with which an axially displaceable throttling element (7) interacts. The throttle system thus represents a venturi nozzle with its favourable flow characteristics. The throttling element (7) is positioned by a variable magnetic field. At the same time, this magnetic field causes the throttling element (7) to perform microvibrational movements, allowing an air-bearing cushion to form between this throttling element (7) and a supporting element (10). Advantageous constructional arrangements are described. <IMAGE>

Description

The invention relates to a throttle system in the intake duct of an internal combustion engine with an axially displaceable throttle body interacting with a venturi-like wall section, and is based on DE 27 26 146 C2.

In addition to the usual throttle valves, by means of which the fresh air quantity entering the cylinders, in particular quantity-controlled internal combustion engines, is metered and thus the internal combustion engine operating point is set, other throttle systems were also known, such as the throttle device shown in the above-mentioned document for a multi-cylinder internal combustion engine. A displaceable spindle-shaped throttle body is provided, which cooperates with a Venturi wall section and thus forms a Venturi nozzle which can be changed in the cross section. Such an arrangement is characterized by extremely low flow losses, so that the throttle losses can be significantly reduced compared to the conventional throttle valves. However, the actuating mechanism in the throttle device known from DE 27 26 146 C2 is disproportionately complex and causes relatively high flow losses again. Furthermore, the known state of the Technique of the throttle body at least temporarily on the venturi-like wall section, with undesirable mechanical wear and tear.

It is therefore an object of the present invention to provide an actuating device for a throttle system which is improved in comparison with this.
To achieve this object it is provided that the positioning of the throttle body takes place by means of a changeable magnetic field, for which purpose at least one coil surrounding a part of the throttle body is provided. Advantageous further developments of the invention are the content of the subclaims.

According to the invention, the throttle body is positioned by means of a magnetic field, so that large-volume actuating devices, which would constitute an obstacle to flow, are not required. Rather, it is possible to arrange one or more magnetic coils, which generate the corresponding variable magnetic field, on the throttle body itself or within the same, as a result of which there is no significant additional space requirement that goes beyond the geometric dimensions of the throttle body. All that is required are guides of some kind for the throttle body. However, a support body provided for this purpose can also be substantially adapted to the dimensions of the throttle body and thus, together with it, form a quasi dynamic flow unit, which at most has a slightly higher flow resistance than the throttle body alone. For example, the essentially rotationally symmetrical throttle body can be hollow-cylindrical, so that it is possible to arrange the support body coaxially to the throttle body partially within this hollow cylinder / throttle body. The support body itself can be fastened to the wall of the intake duct via one or more webs, each web, viewed in the channel direction, being so narrow that it does not represent an essential flow obstacle. Furthermore, the support body can also carry the magnet coil (s), which then, when viewed in the direction of flow, likewise essentially lie within the throttle body which is present anyway and thus likewise do not form an obstacle to flow. However, it is also possible to arrange the magnetic coils on the throttle body itself or, in an alternative embodiment, to provide it outside of the intake duct. In the latter case, the magnetic coils surround the intake duct in the region of the throttle body and thus generate a magnetic field correspondingly positioning the throttle body within the intake duct.

As already explained, the throttle body can be guided through a support body. This guide should be almost free of frictional forces in order to be able to position the throttle body quickly and precisely with low energy requirements. A possible embodiment for this is a magnetic bearing, ie the throttle body is not only positioned in the axial direction or in the direction of the intake duct by magnetic fields, but is also held within the intake duct and centrally by magnetic fields to the venturi section. However, since magnetic storage requires a high level of control, a storage air cushion can be provided as a much more elegant solution. Such air bearings, which are also essentially free of frictional forces, only require a continuous movement between the bearing or the guide and the object to be stored or guided. In the present case, this means that the throttle body must continuously carry out micro-oscillating movements, so that there is a gap between them the throttle body and the support body can build a storage air cushion. These micro-oscillating movements of the throttle body are in turn initiated by the magnetic fields that also position the throttle body. The bearing air cushion can be formed between a bearing bush, which is provided in the support body, and a guide rod guided therein, which carries the throttle body. Of course, the surfaces of the bearing partners, ie for example the bearing bush and the guide rod, are designed to be suitable for air bearings. For this purpose, for example, corresponding structures can be provided in silicon carbide surfaces.

The throttle body can already be positioned by means of the magnetic field according to the invention in that a corresponding metallic element of the throttle body, for example the guide rod, is exposed to this changeable magnetic field. A particularly fine control and in particular also the micro-oscillating movement required to form the air cushion bearing can be produced in a significantly improved manner if a permanent magnet interacts with the magnetic field caused by the magnetic coils. This permanent magnet can in turn be part of the throttle body and, for example, form a structural unit with the guide rod of the throttle body, i. H. the guide rod itself is permanently magnetic. A permanent magnet can also be provided on the support body in order to help the throttle body in a defined position when the internal combustion engine is at a standstill and the solenoid coil is inactive.

Fig. 1a

eine Prinzipdarstellung eines ersten Ausführungsbeispieles für ein erfindungsgemäßes Drosselsystem in einem Ansaugkanal im Schnitt,

Fig. 1b

den Schnitt A-A aus Fig. 1a,

Fig. 2

die Einzelheit X aus Fig. 1a,

Fig. 3a

ein weiteres Ausführungsbeispiel gemäß der Darstellung in Fig. 1a, sowie

Fig. 3b

den Schnitt A-A aus Fig. 3a.

Further advantageous features are contained in subclaims 6, 9, 10. These and other features that are possibly essential to the invention also result from the following Description of two preferred embodiments. It shows

Fig. 1a

1 shows a basic illustration of a first exemplary embodiment of a throttle system according to the invention in an intake duct,

Fig. 1b

the section AA from Fig. 1a,

Fig. 2

the detail X from Fig. 1a,

Fig. 3a

a further embodiment as shown in Fig. 1a, and

Fig. 3b

the section AA from Fig. 3a.

Reference number 1 denotes an intake duct leading to a cylinder, not shown, of an internal combustion engine. As is known, there are two inlet valves 2 at the downstream end of the intake duct 1. With its upstream end, the intake duct 1 opens into an air collection housing 3, within which an air filter 4 can be provided. In the vicinity of the inlet valves 2, an injection valve 5 also opens into the intake duct 1, via which fuel an air flow passing through the intake duct 1 and via the inlet valves 2 into the internal combustion engine cylinder can be supplied.

A throttle system for influencing the size of the air mass flow flowing through the intake duct 1 is also integrated in the intake duct 1. This throttle system essentially consists of a throttle body 7 which can be displaced axially in the direction of the arrow 6 and which cooperates with a venturi-like wall section 8 of the intake duct 1. The wall section 8 having a venturi profile thus forms together with that of the inlet valves 2 facing front area of the throttle body 7 a Venturi nozzle, which is known to be characterized by minimized flow losses.

According to both exemplary embodiments, the throttle body is, as can be seen, hollow-cylindrical and has an essentially conical tip. In the embodiment according to FIG. 1, this hollow cylindrical section is carried with the tip by a guide rod 9, which in turn is guided by a support body 10. In the exemplary embodiment according to FIG. 3, the hollow-cylindrical throttle body 7, which has a tip, is guided axially displaceably within the likewise hollow-cylindrical support body 10 in the direction of the arrow 6.

The positioning, ie the displacement of the throttle body 7 according to the direction of arrow 6 into a desired position, throttling the intake air mass flow, takes place by means of a variable magnetic field. This magnetic field is generated electrically, for which purpose at least one coil 11 (FIG. 3) or two coils 11, 11 ′ (FIG. 1) arranged next to one another are provided. This coil (s) 11, 11 'surrounds / surround part of the throttle body 7. In the exemplary embodiment according to FIG. 1, these coils 11, 11' surround the guide rod 9 and for this purpose are concentric with this on a bearing bush 12 provided for the guide rod 9, which in turn is part of the support body 10. In the exemplary embodiment according to FIG. 3, the coil 11 is located as a winding directly on the throttle body 7. In the exemplary embodiment according to FIG. 1, the stationary magnetic field generated by the coils 11, 11 'thus acts on the guide rod 9, while in the exemplary embodiment according to FIG. 3, in which the coil 11 or the magnetic field is displaceable according to arrow 6, the magnetic field interacts with a stationary iron rod 10 ′ attached to the support body 10.

FIG. 2 shows the exemplary embodiment according to FIG. 1 in the area of the coils in detail. The bearing bush 12 can be seen, which is connected to the outer wall 14 of the support body 10 via an annular web 13. The support body 10 or its outer wall 14 is fixed in the interior of the intake duct 1 via webs 15 which, as can be seen, are supported on the wall of the intake duct 1. This can also be seen from FIGS. 1 a, 1 b, and it can also be seen from this that the throttle body 7 in this first exemplary embodiment surrounds the outer wall 14 of the support body 10 in regions.

2 shows, the guide rod 9 of the throttle body 7 is designed as a permanent magnet and has a magnetic north pole on the left side and a magnetic south pole on the right side. If the two coils 11, 11 'are each subjected to the opposite current direction, the north pole and the south pole of the permanent magnetic guide rod 9 experience a force in the same direction, for example to the left, because of the magnetic fields generated within the coils 11, 11' that the throttle body 7 is then also moved to the left. If you reverse the polarity of the two coils 11, 11 ', ie if you apply the opposite direction of current, the throttle body 7 is also accelerated in the opposite direction, namely to the right. By targeted application of the coils 11, 11 ', it is thus possible to impress a desired direction of movement on the throttle body 7. If this polarity reversal oscillation is superimposed on another polarity reversal oscillation with a higher clock frequency, the throttle body 7, including its guide rod 9, can be set into a micro-oscillation according to the direction of the arrow 6. With this micro-vibration can build up a storage air cushion between the guide rod 9 and the bearing bush 12. To improve the design of this air cushion, the surfaces of the guide rod 9 and the bearing bush 12 involved can have correspondingly designed structures, for example in silicon carbide surfaces.

The same storage principle is also possible in the embodiment of FIG. 3. Here, too, the throttle body 7 can be set into a micro-oscillating movement by reversing the polarity of the magnetic field formed by the coil 11, so that a bearing air cushion is built up between the throttle body 7 and the support body 10. It is not necessary that the component interacting with the magnetic field of the coil (s) 11, 11 'is designed to be permanently magnetic. It is also sufficient to carry out the corresponding component - in the exemplary embodiment according to FIG. 3 the iron rod 10 ', in the exemplary embodiment according to FIG. 1 the guide rod 9 - in a highly conductive metal. This also makes it possible to impart a micro-oscillating movement to the throttle body 7 when the magnetic field forms a gradient by changing the coil current over time.

It applies to both exemplary embodiments that now, after the throttle body 7 carries out micro-oscillatory movements and is thereby displaceably mounted in relation to the support body 10 in the direction of the arrow 6, the throttle body 7 with its center of oscillation can be displaced in the direction of the arrow 6 by appropriate variation of the vibration amplitudes. This means that by increasing the vibration amplitudes to the left, the throttle body 7 is moved in its entirety to the left, that is to say the vibration center around which the throttle body 7 executes its micro-oscillatory movements is shifted to the left. Conversely, the throttle body 7 is shifted to the right, so that the vibration amplitudes directed to the right are larger than the amplitudes directed to the left. The vibration characteristic required in each case can be easily achieved by suitably changing the magnetic fields, ie by suitably controlling the coils 11, 11 '. As can easily be seen from FIGS. 1a, 3a, the free flow cross section in the intake duct is reduced when the throttle body 7 is shifted to the left, and is increased when it is shifted to the right. A displacement movement of the throttle body 7 to the left thus reduces the amount of intake air entering the cylinder of the internal combustion engine, while conversely a displacement of the throttle body 7 to the right results in a higher internal combustion engine power output due to the larger amount of intake air.

Fig. 1a shows as a further detail that the end of the support body 10 facing the air collection housing 3 is also designed to be streamlined in order to keep the flow resistance caused by the entire throttle system as low as possible. Furthermore, this figure shows an emergency stop 16 provided at the right-hand end of the guide rod 9. This emergency stop 16 prevents the throttle body 7 from falling out of the support body 10 in the direction of the inlet valves 2, for example when the internal combustion engine is at a standstill. Rather, with such a movement, the emergency stop 16 comes to rest on the support body 10 and thus prevents a further movement of the throttle body 7 in the direction of the inlet valves 2.
During operation of the internal combustion engine and the throttle system, however, it is not possible at all for the throttle body 7 to leave the support body 10. This is prevented by a safety-related advantage This arrangement, which can be seen, inter alia, by looking at FIG. 2: namely, if the right-hand south pole of the guide rod 9 leaves the right-hand coil 11, in which it experiences a movement to the left, then if the poles 11, 11 'are not reversed in time this south pole into the coil 11 'which, according to the above explanations, also has a south pole on the right-hand side, so that the guide rod 9 is braked or stopped due to the magnetic repulsion then present. With the movement pulse reversing in the direction, the throttle body 7 with its guide rod 9 is thus moved to the right again. It should be expressly pointed out that this effect also occurs without influencing the coil currents and can therefore also be used to control the movement of the throttle body 7.

1a, 2 also show, as a further detail, a permanent magnet 17 which is likewise fastened to the support body 10 or to the outer wall 14 thereof and serves to provide a rest position of the throttle body 7 when the internal combustion engine is at a standstill and thus the coils 11, 11 'are not energized define. This permanent magnet 17 interacts with the permanent magnet guide rod 9.

Furthermore, electrical supply lines 18 for the coils 11, 11 ′ can be seen in FIG. 2, which are integrated in a web 15 or applied to a web 15. Furthermore, these webs 15 can simultaneously be designed as air mass meters. For this purpose, the elements required for this purpose of a known hot film air mass meter can be applied to these webs.

Fig. 3b shows a gap between the throttle body and the venturi-like wall section 8, which a passage of the air mass flow required for idling the internal combustion engine. The arrangement can also be made so that the throttle system described is statically leaky, but dynamically leaky. This dynamic tightness is then a consequence of the micro vortices formed in the gap between the throttle body 7 and the venturi-like wall section 8. In order to allow an air mass flow sufficient for idling operation to reach the internal combustion engine cylinder via the intake duct 1, a bypass 19 is provided to the venturi-like wall section 8. This bypass 19 can also advantageously form a fluid coanda zone at a downstream end near the inlet valves 2, which allows a relatively low air mass flow preferably to flow via the lower inlet valve 2 into the internal combustion engine cylinder (not shown) in order to achieve desired turbulence in the latter to create. However, this and other details may well be designed differently from the exemplary embodiments shown, without leaving the content of the claims. For example, a throttle system according to the invention can also be arranged in a common intake duct for all internal combustion engine cylinders, although the arrangement shown close to the inlet valves 2 of a cylinder-specific intake duct 1 is of particular advantage.

Claims (10)

Throttle system in the intake duct (1) of an internal combustion engine with an axially displaceable throttle body (7) interacting with a venturi-like wall section (8),
characterized in that the positioning of the throttle body (7) takes place by means of a variable magnetic field, for which purpose at least one coil (11, 11 ') surrounding a part of the throttle body (7) is provided. Throttle system according to claim 1,
characterized in that the substantially rotationally symmetrical throttle body (7) is guided through a support body (10) arranged coaxially to the latter. Throttle system according to claim 2,
characterized in that the support body (10) is fastened to the wall of the intake duct (1) via at least one web (15). Throttle system according to one of the preceding claims,
characterized in that the support body (10) and / or the throttle body (7) carries the coil (s) (11, 11 ') generating the changing magnetic field. Throttle system according to one of the preceding claims,
characterized in that the support body (10) and / or the throttle body (7) carries a permanent magnet (17, guide rod 9). Throttle system according to one of the preceding claims,
characterized in that the throttle body (7) has a substantially conical tip, to which an essentially hollow cylindrical section adjoins, within which a guide rod (9) carrying an emergency stop (16) is provided, and which sectionally supports the support body (10) records. Throttle system according to claim 6,
characterized in that the guide rod (9) is permanent magnet. Throttle system according to one of the preceding claims,
characterized in that the throttle body (7) continuously executes micro-oscillating movements by suitable actuation of the coil (s) (11, 11 '), so that an air cushion is built up between the throttle body (7) and the support body (10), for which the corresponding surfaces of the throttle body (7), in particular the guide rod (9), and the support body (10), in particular a bearing bush (12) are designed accordingly. Throttle system according to one of the preceding claims,
characterized in that an air quantity or air mass measuring device is integrated in the support body (10) and / or its webs (15). Throttle system according to one of the preceding claims,
characterized in that a bypass (19) to the venturi-like wall section (8) is provided.

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