DE102008000536A1 - Exhaust-gas turbocharger for internal combustion engine of vehicle, has brake body connected with shaft in torque proof manner such that brake body lies in contact with housing while exceeding allowed maximum speed of shaft - Google Patents

Abstract

The turbocharger has a turbine rotor (3) and a compressor rotor (7) connected with a shaft (5) in a torque proof manner. A brake body is connected with the shaft in a torque proof manner such that the brake body lies in contact with housing (1) while exceeding allowed maximum speed of the shaft. The brake body is connected with a brake element (23) such that the brake element is directly or indirectly connected with the shaft. The brake element is integrated into the turbine rotor, the compressor rotor or a bearing bush (19).

Description

State of the art

turbocharger be both at the diesel process and after the Ottover internal combustion engines are increasingly used. reasons therefor are the increase torque and power and efficiency benefits and emission behavior.

in the Operation reach the wheels and the shaft of the turbocharger speeds up to 300,000 per Minute.

If, for example, by a faulty control of the boost pressure control the maximum permissible speed significantly exceeded it may cause the compressor wheel or turbine wheel to rupture come. The debris a broken wheel can through the exhaust pipe to other components of the internal combustion engine, such as to the valves in the cylinder head of the engine or in a soot particle filter or get a catalyst in the exhaust aftertreatment system. There can the debris considerable damage cause. Therefore, the bursting of parts of the exhaust gas turbocharger preferably to avoid. In conventional Exhaust gas turbochargers can not exclude rupture under all circumstances be so the case the exhaust gas turbocharger is carried out with a correspondingly large wall thickness, at least to Prevent the cracked parts of the ruptured wheel the turbocharger housing leave.

These huge wall thickness to lead, especially on the turbine side, where high temperature resistant nickel base alloys have to be used at comparatively high material costs. Also goes with the large wall thicknesses of the housing a high weight. This also reduces the overall weight of the Exhaust gas turbocharger to what the efforts the vehicle manufacturer, after a reduction in vehicle weight, runs counter. Furthermore, have housing with big ones Wall thickness one size thermal inertia the exhaust gas turbocharger result, which in particular during cold start the internal combustion engine, the heating of the subsequent exhaust aftertreatment devices, like soot particle filters and catalysts delayed. This is also undesirable.

Disclosure of the invention

Of the The invention is based on the object to provide an exhaust gas turbocharger, whose rotating components are reliably protected against bursting and consequently as a result of additional measures, such as thick-walled and burst-proof housings can be waived.

These Task is according to the invention in a Exhaust gas turbocharger for an internal combustion engine with a housing, with a shaft, with a Turbine impeller and with a compressor impeller, wherein the turbine impeller and the compressor impeller rotatably connected to the shaft, solved by that rotatably connected to the shaft at least one brake body, and that the at least one brake body when crossing a maximum permissible speed the shaft in contact with the housing arrives.

According to the invention is thus provided that the brake body reaches the housing before reaching the bursting speed and thereby the shaft slows down. This will be reliable Reaching the bursting speed prevented. As a result, it can too not to burst the wheels or other components of the exhaust gas turbocharger come. Therefore, the Wall thickness of the housing of the Exhaust gas turbocharger can be significantly reduced, which is beneficial to the material costs, the weight and the thermal inertia of the exhaust gas turbocharger according to the invention effect.

In further advantageous embodiment of the invention is provided that or the brake body are connected to a braking element or integral part of the brake element, and that the brake element directly or indirectly rotatably connected to the shaft.

there For example, the brake element can be designed as a separate component, in particular as a disk-shaped component be. Alternatively, it is also possible the brake element in the compressor impeller, a bearing bush, a Disc of the thrust bearing or the turbine wheel to integrate. Preferably, the integration of the brake element in the bearing bush of the thrust bearing or the compressor impeller, since there the thermal Load of the braking element are lower.

In a further advantageous embodiment of the invention, it is provided that the load limit of the connection between the brake body and brake element is reached at the maximum permissible speed of the shaft. This means that when the permissible maximum speed of the shaft is exceeded, the connection between the brake body and brake element is plastically deformed, so that the brake body moves radially outward and begins to grind on the housing of the exhaust gas turbocharger. As a result, a further speed increase of the shaft is prevented. With increasingly greater braking torque, for example due to the self-reinforcement, it can also happen that the cohesive connection between the brake body and brake element breaks. Then the brake body wedged increasingly solid between brake element and housing and the shaft of the exhaust gas turbocharger is braked.

It has proven to be advantageous, the brake body via one or more webs to connect with the braking element and thereby produce these webs, that between brake body and brake element at least one slot is present.

This Slit can be made by sawing, Eroding or can be produced by laser cutting. Advantageous Laser cutting is, first, the high productivity, the low Thickness of the slot and the possibility with almost all forms, be it straight, curved or otherwise shaped Slots in the component, which forms brake element and brake body, to shape.

In further advantageous embodiment of the invention is provided that between the at least one slot and a radius jet, an angle> 0 ° available is. This is when breaking the cohesive connection between the brake body and Bremselement a clamping action between the brake body and brake element on the one hand and casing and brake body achieved on the other hand, which leads to a rapid deceleration of the shaft.

Further Advantages and advantageous embodiments of the invention are the subsequent drawing, the description and the claims can be removed. All described in the drawing, the description and the claims Features can both individually and in any combination with each other invention essential be.

It demonstrate:

1 a schematic representation of an exhaust gas turbocharger according to the invention,

2 and 3 Various embodiment of inventive brake body

In 1 is a housing of the exhaust gas turbocharger with the reference numeral 1 Mistake. The housing 1 can be formed in one or more parts, depending on the requirements in the production and installation of the exhaust gas turbocharger.

As is well known, exhaust gas turbochargers have a turbine part that is in 1 is arranged on the right and a compressor section, which in 1 is located on the left. In the turbine part is a turbine wheel 3 rotatable on a shaft 5 stored.

At the left end of the shaft 5 is a compressor impeller 7 appropriate. The combustion air to be compressed flows to the compressor impeller 7 in the axial direction and leaves it in the radial direction. The direction of movement of the combustion air to be compressed is in 1 through arrows 9 indicated. In the right part of the case 1 is an inlet spiral 11 formed by the ejected from the engine, not shown exhaust gas to the turbine runner 3 is supplied.

Of the Bursting protection according to the invention Can with all types of exhaust gas turbochargers, especially in turbochargers with variable turbine geometry or with sliding sleeve (not shown) are used.

The radial bearing of the shaft 5 takes place by two mutually spaced slide bearings 13 , It can, as in 1 represented, a so-called floating bush bearing or a so-called Einbuchsenlagerung (not shown) may be provided.

To the on the shaft 5 to absorb acting axial forces is on the housing 1 a bearing disc 15 arranged in one of two bearing sleeves 17 and 19 formed groove dips. The thrust bearing sleeves 17 and 19 are rotatable with the shaft 5 connected.

To prevent oil from entering the compressor impeller 7 is an oil deflector 21 intended.

In 1 two alternative embodiments of the burst protection according to the invention are formed. Usually it is sufficient to provide a burst protection.

In the first embodiment is on the first bearing sleeve 19 a disc-shaped brake element 23 formed in a suitably dimensioned paragraph 25 of the housing 1 rotates. It has the brake element 23 no contact with the housing 1 ,

To prevent on the brake element 23 fortified and in 1 not visible brake body in the axial direction can "wander" is the housing 1 designed so that the brake element 23 , only a small distance, for example, half a millimeter, to the braking element 23 in the axial direction. On the in 1 right side of the brake element 23 is the oil deflector 21 designed so that it is the walking of the braking element 23 prevented in the axial direction.

In 1 is another second execution form of a braking element according to the invention 23 shown. In this embodiment, the braking element 23 on the compressor impeller 7 educated. As in the first embodiment, the brake element is 23 in a paragraph 25 of the housing 1 added.

For integrating the brake element 23 in the compressor impeller 7 (second embodiment) speaks the larger diameter and thus the better braking effect, while for the integration of the braking element 23 in the bearing bush 19 (first embodiment) speak the ease of manufacture and the lower production costs. Alternatively, it would also be possible to use the brake element 23 form as a separate component and with the shaft 5 rotatably connect. This third embodiment is in 1 not shown.

Based on 2 and 3 Various embodiments of the brake element according to the invention are shown below and explains its function.

In 2 is a front view of a first embodiment of a brake element according to the invention 23 as well as the housing 1 and the related paragraph 25 in the case 1 shown. The brake element 23 is, in simple terms, designed as a flat disc, the rotation with the shaft 5 is connected and in which 2 illustrated embodiment rotates counterclockwise.

At the brake element 23 are two brake bodies 27 educated. The brake body 27 are arranged offset by 180 ° to each other, so that the brake element 23 together with the brake bodies 27 balanced in normal operation.

The brake body 27 are each through two slots 29 from the rest of the brake element 23 separated. The two slots 29.1 and 29.2 do not touch, leaving between the slits 29.1 and 29.2 at the in 2 illustrated first embodiment of a web 31 with a width X is present. The dimensioning of the bridge 31 Now done so that the bridge 31 in normal operation, that is at all speeds below the maximum permissible speed of the exhaust gas turbocharger, that of the brake bodies 27 can transfer to him exerted centrifugal forces. Only when the maximum permissible speed is exceeded significantly, the material of the brake element 23 or the bridge 31 deformed plastically, or it comes even to the break of the bridge 23 ,

As a result, the brake body moves 27 radially outwards and finally comes into abutment with the recess 25 of the housing 1 ,

Through the between brake body 27 and recess 25 applied braking forces, the brake body shifts 27 relative to the brake element 23 and thereby wedges itself with the part of the slot 29.2 , the brake element 23 is available. This position of the brake body 27 is in 2 shown in dashed lines.

By doing that, the slot 29.2 with a radius beam 33 of the braking element 27 encloses an angle> 0 °, wedges the brake body 27 with the brake element 23 or in the area of the slot 29.2 and with the case 1 in the area of the recess 25 , This will be the braking element 23 and with it the wave 5 braked and blocked, so that a bursting of the wheels is reliably prevented.

The slots 29.1 and 29.2 can be made in a variety of ways, such as by milling, sawing, EDM or laser cutting.

Of course, always make sure that the brake element 23 and the brake bodies 27 at intact bridges 31 are well balanced. Therefore, it is recommended in most cases two 180 ° opposite arranged brake body 27 provided.

In 3 are further embodiments of inventive brake body 27 shown. However, here is only one brake body 27 shown. A second embodiment of a brake body 27 is in the upper part of the 3 shown. Here is the brake body 27 through a slot 29.3 acting as a secant to the outer diameter of the brake element 23 is executed, formed. Because the slot 29.3 the outer diameter of the braking element 23 not quite reached on both sides, two bridges remain 31 stand, which are also to be dimensioned so that only when exceeding the maximum permissible speed, these webs 31 plastically deformed and thus the brake body 27 migrates radially outwards.

At the in 3 lower part of the below drawn brake body 27 are the slots 29.4 and 29.5 formed as a quarter circles, so that a total of three bars 31 between brake element 23 and brake body 27 available.

At the in 3 on the right side of the brake element illustrated embodiment, the slots 29.6 executed straight and there are again three bars 31 between brake body 27 and brake element 23 educated. As can be seen from the representation of the different geometries of the brake body 27 in the 2 and 3 results are in the design of the brake body 27 lots Degrees of freedom available.

Important criteria for the design of the brake body are the reproducible dimensioning of the webs 31 , because of the cross section, inter alia, the speed depends, above which the brake body 27 migrates radially outwards. Furthermore, the manufacturing processes used, such as sawing, milling or laser cutting are also important in the design of the brake body 27 or the slots 29 and the bridges 31 ,

Claims (8)

Exhaust gas turbocharger for an internal combustion engine with a housing ( 1 ), with a wave ( 5 ), with a turbine wheel ( 3 ) and with a compressor impeller ( 7 ), wherein the turbine wheel ( 3 ) and the compressor impeller ( 7 ) rotatably with the shaft ( 5 ), characterized in that at least one rotationally fixed to the shaft ( 5 ) connected brake body ( 27 ) is provided, and that the at least one brake body ( 27 ) when a maximum permissible speed of the shaft is exceeded ( 5 ) in contact with the housing ( 1 ). Exhaust gas turbocharger according to claim 1, characterized in that the or the brake body ( 27 ) with a braking element ( 23 ) and that the brake element ( 23 ) rotatably directly or indirectly with the shaft ( 5 ) connected is. Exhaust gas turbocharger according to claim 2, characterized in that the brake element ( 23 ) is formed as a separate component. Exhaust gas turbocharger according to claim 2, characterized in that the brake element ( 23 ) in the compressor impeller ( 3 ), a bearing bush ( 19 ) or the turbine wheel ( 7 ) is integrated. Exhaust gas turbocharger according to one of the preceding claims, characterized in that the load limit of the compound ( 31 ) between the brake body ( 27 ) and braking element ( 23 ) is reached at the maximum permissible speed of the exhaust gas turbocharger. Exhaust gas turbocharger according to one of claims 2 to 5, characterized in that the brake body ( 27 ) via one or more webs ( 31 ) with the braking element ( 23 ), and that between brake body ( 27 ) and braking element ( 23 ) at least one slot ( 29 ) is available. Exhaust gas turbocharger according to claim 6, characterized in that at least one slot ( 29.2 ) and a radius jet ( 33 ) of the braking element ( 23 ) include an angle () greater than zero degrees (> 0 °). Exhaust gas turbocharger according to one of the preceding claims, characterized in that the brake body ( 27 ) is secured in the axial direction ( 1 . 21 ).