DE1116941B - Hot gas turbocharger - Google Patents

Description

Hot gas turbocharger The invention relates to a hot gas turbocharger, in which the impellers of the fan and the turbine, which are designed as radial wheels on both sides of an air-cooled, closed bearing body on one horizontal shaft are cantilevered and facing away from the bearing body Sides axially suck in air or let out hot gas, with the bearing body only on the fan housing is attached, while the fan and turbine housing by a the bearing body are connected at a distance surrounding the jacket. Such machines, which are preferably used as gas turbines or as exhaust gas turbochargers arose from the need for high performance with relatively small dimensions to achieve. Close assembly is particularly necessary in the case of exhaust gas turbochargers; because these machines are as close as possible to an internal combustion engine in order to make good use of the energy must be attached.

In order to improve the thermal efficiency, efforts are made to to set the temperature at the turbine as high as possible. With the tight assembly of the various machine parts, such as the turbine, blower and the one in between Bearing bodies, but are then special measures to protect the storage against the high temperature required.

It is known to surround the bearing body with a cooling jacket which a coolant is forced through. Water can be used as a coolant or air can be used, whereby the cooling air is either taken from the fan, whereby its efficiency deteriorates, or by additional, of the Turbine driven conveyor is driven, thereby increasing the usable power the turbine is reduced, or finally comes from the driving wind of a vehicle, thereby reducing the actual performance of the machine driving the vehicle.

A hot gas turbocharger of the type specified above is now according to FIG Invention characterized in that in a manner known per se, the jacket is about has the overall length of the bearing body and that the jacket is provided with openings, which allow a free flow of ambient air through the shell space, which Dissipates heat from the bearing body solely by convection.

In this hot gas turbocharger, the impellers are on both sides of the Bearing body, and the invention is concerned with the task at this per se compact design without the consumption of additional energy a good and even load-dependent To create cooling. The one-sided attachment of the bearing body to the fan housing prevents noticeable heat from flowing in on the way over the connection of the bearing body. There continues to be the connection between the fan housing and the turbine housing not over the bearing body, but over a body surrounding this body at a distance, known coat takes place, the by the mechanical connections from Heat dissipating from the turbine housing can only reach the fan housing, from where it is is discharged.

Thus, first of all, the heat is supplied by means known per se reduced in the direction of the bearing body.

Furthermore, turbines and fans are used in a known manner work radially. In this way you get a relatively large free Distance between the inner boundary walls of the turbine and fan housing, which is less because of a reduction in thermal radiation than because of a as free and unimpeded air circulation as possible is appropriate. With axial turbines There must always be space on both sides of the blading for feed or discharge of the gases are used, whereby inevitably the free space between the two housings is significantly reduced.

Furthermore, the jacket and the bearing body are given in a manner known per se Way about the same length. This measure also serves to enable a free Air circulation.

This air circulation penetrates openings and provided in the jacket is a free flow of ambient air through the jacket, which heat the end discharges the bearing body solely by convection, d. i.e., he uses himself as much as possible completely and exclusively those energies that reach the bearing body and can cause disturbances there. So he makes use of those to be destroyed Energies and not the energies that can be used in the blower should. In this way, a flow of cooling air is generated without the charger or an engine power is withdrawn, so that the efficiency of the overall system compared to the known systems is improved.

In addition, the cooling is adapted to the needs in a special way. If the machine starts up when the outside temperature is low, the bearings and First heat the bearing oil. The usual forced cooling prevents this, whereas the convection cooling according to the invention only starts when the bearings are sufficient have warmed. On the other hand, the effect of forced cooling stops immediately when the machine is shut down after full load, so that then the heat of the turbine housing Crawl over the shaft or other connecting paths to the bearing body and will heat it up inadmissibly. The convection cooling according to the invention works but also after the machine has been shut down, so that the bearings are reliably protected will.

It should also be noted that the invention is only of a special type the existing connection between the turbine housing and the fan housing. So it does not require any additional weight, but sets the total weight of the Machine by eliminating additional cold rooms, cooling jackets, coolant drive means as well as by enabling a particularly compact design. This crowded Type of construction is particularly important in truck engines because it is under the bonnet there is little space and you have to move the loader close to the engine. Also enables it takes up little space to put the loader in the right place on the engine, functionally through the routing of the exhaust pipes and the air inlet pipes is conditional.

The structural separation of the turbine housing from the bearing body is made possible it, the z. B. for commercial vehicles prescribed exhaust brake, usually in front of the turbine, behind it. The one when the exhaust brake is applied Higher gas pressure built up in the turbine housing can result in the inventive Design neither affect the bearings nor force propellant gases into the fan. on the other hand the arrangement of the exhaust brake behind the turbine results in a more favorable one Braking effect and due to the increased volume by the turbine housing Protection of the valves of the engine, since the falling pressure waves when the valve is closed The exhaust flap is reflected less steeply.

By using a turbine-side radiation protection the heat transfer to the bearing body continues to be reduced.

It is advantageous if the bearing body is from the fan side in the direction of the turbine housing tapers conically and has cooling fins. These measures also reduce heat absorption and increase the cooling effect. aside from that they increase the rigidity of the assembly. In the drawing is an exemplary embodiment for the subject matter of the invention shown schematically in axial section.

The shaft 1 carries the cantilevered turbine impeller 2 on the left and the fan impeller 3 on the right. Both wheels work radially. The shaft rests in the two bearings 4 and 5, which are held in the bearing body 6. The bearing body 6 is only directly connected to the fan housing 7 by a flange connection. The turbine housing 8, on the other hand, has no connection to the bearing body 6, but is connected to the fan housing 7 by the jacket 9 which freely encloses the bearing body 6. This jacket 9 has openings 10 below and above for the passage of the ambient air, so that the bearing body 6 is cooled by convection flow. Through these openings 10, the jacket 9 is given an approximately lantern shape.

The turbine housing 8 is attached to the shaft 1 by a tip seal 11, while the fan housing 7 is sealed by a corresponding seal 12 is sealed on the shaft 1. To also the transfer of radiant heat from the turbine housing 8 to prevent the bearing body 6 as far as possible, a radiation protection plate 13 is attached to the turbine housing. The jacket 9, which connects the turbine housing to the fan housing connects, can also be designed and approximately completely circular cylindrical or conical on the entire circumferential surface with corresponding, regularly distributed air passage openings be provided. But it can also be a particularly intensive flow around the bearing body to achieve _ instead of the circular cylindrical jacket only individual webs connect the two flanges on the turbine housing and fan housing. Particularly useful it is in this case, the webs as baffles for guiding the flow around the bearing body Train cooling air in the desired direction.

The bearing body is advantageous to support the effect of the cooling air 6 provided with cooling fins 14, as shown in the figure as a supplement in dash-dotted lines are shown.

The invention thus ensures that the heat transfer from the hot turbine housing to the bearing body and thus largely to the bearing is prevented and at the same time this bearing body is cooled. There is no connection exists between the turbine housing and the bearing body, no heat can there transmitted by line. Heat transfer by conduction can be from the turbine only to the fan housing, namely to the part of the fan housing from from which the heat is transferred to the compressed air, so that this heat energy is not is lost, but is fed back into the cycle. Through training of the connecting piece as an openwork jacket with the smallest possible cross-section however, this amount of heat is kept as low as possible. The invention enables intensive cooling of the bearing body due to the convection caused by it surrounding air.

Claims (5)

PATENT CLAIMS 1. Hot gas turbocharger, in which the radial impellers of the fan and the turbine on both sides of an air-cooled, closed bearing body are cantilevered on a horizontal shaft and axially suck in air or release hot gas on the sides facing away from the bearing body, with the bearing body only during blower and turbine housing are connected by a storage body having spaced surrounding jacket, data is attached to the fan housing, characterized by that in a known manner, the jacket (9) has approximately the length of the bearing body (6) and that the Shell (9) is provided with openings (10) which allow a free flow of ambient air through the shell space, which dissipates heat from the bearing body solely by convection. 2. Hot gas turbocharger according to claim 1, characterized in that that the fan housing (7) and the turbine housing (9) in a known manner are sealed on the shaft (1), between the bearing body (6) and the turbine-side Seal (11) enclosing the shaft and freely communicating with the shell space standing zone is present. 3. hot gas turbocharger according to claim 1 or 2, characterized characterized in that the turbine housing (8) after the bearing body (6) to a radiation protection (13). 4. hot gas turbocharger according to claim 1 or the following claims, characterized characterized in that the bearing body (6) extends from the fan side in the direction of the turbine side tapers conically. 5. Hot gas turbocharger according to claim 1 or the following claims, characterized in that the bearing body (6) has cooling fins (14). Documents considered: USA: Patent Nos. 2,042,533, 2,216,731, 2465846, 2484275, 2541850, 2578785, 2646210; VDI-Zeitschrift, 1941, p. 855; Luftwissen, 1943. p. 219.