FR2746849A1 - FUEL TURBOCHARGER - Google Patents

Abstract

A turbocharger with turbocharging comprises a turbine rotor (14), a compressor rotor (13) connected to the turbine rotor by a shaft (30), a housing (10) rotationally supporting the shaft via a radial bearing (15), a thrust bearing (18) and a cylindrical sleeve (19) which is mounted on the shaft between the thrust bearing and the compressor rotor, a sealing plate fixed to the housing while maintaining a predetermined clearance between the compressor rotor and its wall portion and having a cylindrical inner part which extends towards the thrust bearing and in which the sleeve is mounted and an outer projecting portion which is formed on the end of the part cylindrical and which extends outwards in the diametrical direction so as to form a circular groove with the wall part and a sealing ring (20) arranged between the cylindrical internal part of the sealing plate and a circumferential outer part of the sleeve.

Description

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  The present invention relates to a turbo-

supercharged compressor.

  A conventional turbocharger is described, for example, in the publication No. 59 (1984) -39734 made available to the public of the Japanese utility model application. This turbocharger has a turbine rotor and a compressor rotor which is connected to the turbine rotor by a shaft. The shaft is supported in rotation on a housing by means of a radial bearing and a thrust bearing. Bushings are mounted on the shaft between the radial bearing and the compressor rotor. The bushings are rotated with the shaft in the same body. A sealing plate comprising a walled part which is opposite the compressor rotor with a given clearance is fixed to the housing at its external part. The sealing plate has an inner cylindrical part in which the sleeve is mounted with clearance. A sealing ring is arranged between the outer circumferential surface of the sleeve and the inner circumferential surface of the inner cylindrical part of the sealing plate. . A deflector is arranged between the sealing plate and the thrust bearing so as to intercept the oil spouting into

  the direction of the sealing plate.

  In the supercharged turbocharger of the prior art mentioned above, the oil which gushes out under the effect of the rotation of the sleeve is prevented by the deflector from going directly to the sealing plate. However, the oil which falls along the deflector is able to invade the part separating the external circumferential surface of the sleeve and the internal circumferential surface of the internal cylindrical part of the sealing plate. Therefore, there is the risk of an oil leak to the compressor rotor. It is therefore an object of the present invention to provide an improved supercharged turbocharger which overcomes the disadvantage

set out above.

  Another object of the present invention is to provide an improved turbocharger which prevents the oil from leaking.

  in the direction of the compressor rotor.

  To achieve the above objects, an improved turbocharger is provided which comprises a turbine rotor, a compressor rotor connected to the turbine rotor by a shaft, a housing supporting the shaft in rotation by means of a radial bearing. , a thrust bearing and a cylindrical sleeve which is mounted on the shaft between the thrust bearing and the compressor rotor, a sealing plate fixed to the housing while maintaining a predetermined clearance between the compressor rotor and its part wall and having a cylindrical inner part which extends towards the thrust bearing and in which the sleeve is mounted and an outer projecting part which is formed on the end of the cylindrical part and which extends outwards in the diametrical direction so as to form a circular groove with the wall part and a sealing ring disposed between the cylindrical inner part of the sealing plate and part

  outer circumference of the sleeve.

  The present invention will be well understood

  during the following description made in connection with

  the accompanying drawings, in which: Figure 1 is a sectional view of a first embodiment of a turbocharger with supercharging according to the present invention; Figure 2 is a sectional view of a second embodiment of a turbocharger with supercharging according to the present invention; Figure 3 is a partially enlarged view of Figure 2; Figure 4 is a side view of a deflector of Figure 2; and Figure 5 is a sectional view taken on

  along line A-A in Figure 4.

  A supercharged turbocharger according to the preferred embodiments of the present invention will be described in connection with the drawings.

annexes.

  Figure 1 shows a first embodiment of the present invention. In Figure 1, a cast iron housing 10 has a pair of axial holes 10a. A shaft 30 is rotatably supported in the axial holes 10a by means of radial bearings 15 and 16. The radial bearings 15 and 16 are rotatably mounted in the axial holes 10a and are prevented from moving axially in opposite directions by circlips fixed in the axial holes 10a, respectively. The radial bearing 16 cannot move to the right side of FIG. 1 due to contact with a large diameter part which is formed

on the tree 30.

  On the left side of a part of the shaft 30 on which the radial bearing 15 is rotatably mounted, a small diameter part is formed on the top. A cylindrical sleeve 17 having a rim portion at its end on the right side is mounted on the small diameter portion of the shaft 30 so that the rim portion can be in contact with an end surface on the left side of the bearing radial 15 or with a stepped part of the shaft 30. On the left side of the small diameter part of the shaft 20, a cylindrical sleeve 19 is mounted on the top so as to be contiguous with the sleeve 17. The sleeve 19 has an overhanging part 19a which is formed at its end on the right side so as to extend outwards in the diametrical direction and which is in contact with the end on the left side of the socket 19. The diameter of the surface on the side the left side of part 19a is larger than that of the surface on the left side of part 19a and a conical surface is formed on the outer circumferential portion of part 19a. A circular groove is formed on an outer circumferential part of a cylindrical portion of the sleeve 19 and an oil seal (ring

  seal) 20 is mounted in the circular groove.

  On the left side of the axial holes 10a of the housing 10, a large diameter hole lod is formed on the top and a sealing plate 21 having an internal cylindrical part in which the sleeve 19 is mounted in a fluid-tight manner via of an oil seal 20 is pressed into the large hole

diameter l0d.

  On the small diameter part of the shaft 30 which is on the left side with respect to the sleeve 19, a compressor rotor 13 is mounted on the top and a nut is tightened on the end of the small diameter part of the shaft 30 so as to compress the rotor 13 towards the sleeve 19. Thus, the sleeve 17 and the sleeve 19 are clamped between the surface on the right side of the rotor 13 and a stepped part between the small diameter part and the part central of the shaft 30 and are in a state in which they cannot rotate with the shaft 30 and the rotor 13 of the compressor in a body. Now, a given clearance is maintained between the surface on the right side of the rotor 13a of the compressor and a wall portion of the sealing plate 21 which is formed on the end of the left side. A thrust bearing 18 which is fixed in the large diameter hole 10d of the housing 10 is inserted between the rim part of the sleeve 17 and the projecting part 19a of the sleeve 19 which are opposite to each other. The housing 10 has oil passages 10b for supplying oil to the radial bearings 15 and 16. The thrust bearing 18 has an oil supply hole 18a which communicates with the oil passages 10b of the housing 10 so as to supply oil to the parts subjected to friction between the thrust bearing 18 and the flange portion of the sleeve 17 and between the thrust bearing 18 and the protruding part 19a of the sleeve 19. A compressor housing 11 wherein the rotor 13 of the compressor is arranged is fixed in an airtight manner to the housing 10 and has an air inlet and an air outlet. The air inlet communicates with an air intake pipe (not shown) and the air outlet communicates with an engine intake manifold

(not shown).

  At the end, right side, of the shaft 30, a turbine rotor 14 which is disposed in the turbine housing 12 is fixed there. The housing 12 is fixed in an airtight manner to the housing 10 and has an exhaust gas inlet and an exhaust gas outlet. The exhaust gas inlet is airtight connected to the engine exhaust manifold (not shown) and the exhaust gas outlet is airtight connected to the outlet line exhaust gas (not shown). Thus, when the engine (not shown) starts, the exhaust gas enters the inlet for exhaust gas, causing the rotation of the rotor 14 of the turbine. The rotor 13 of the compressor then rotates via the shaft 30 so that the air is

supercharged.

  In this embodiment, a projecting outer part 21a is formed on the right-hand end of the cylindrical inner part of the sealing plate 21 which is opposite to the projecting part 19a of the sleeve 19. The part 21a extends outward in the diametrical direction so as to form a circular groove with the wall portion of the sealing plate 21 and has a conical shape

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  which corresponds to a conical part formed on a connecting part between the cylindrical part and the projecting part l9a of the sleeve 19. An upper end of the projecting external part 21a is opposite to the projecting part 19a with a small predetermined play. According to this embodiment, when the supercharged turbocharger operates, the oil is supplied to the parts subjected to friction situated between the thrust bearing 18 and the flange portion of the bush 17 and between the thrust bearing 18 and the part protruding 19a from the socket 19 by

  through the oil supply hole 18a.

  The oil gushes outward in the diametrical direction under the effect of centrifugal force and gushes obliquely and outward in the diametral direction along the conical surface of the outer circumferential part of the part 19a under the effect of centrifugal force. The oil which gushes strikes the inner circumferential surface of the sealing plate 21 and falls along the inner circumferential surface of the sealing plate 21. Then, the oil is entrained in a drainage hole 10C formed on the housing 10. In addition, the oil falls along the walled part of the sealing plate 21 and the circular groove between the walled part and the projecting external part 21a and

  is then routed to the drainage hole lOc.

  Thus, it is certain to prevent the oil from making an invasion in the direction of the oil seal 20 from the clearance separating the upper end from the part

  external projection 21a and the projecting part 19a.

  Figures 2 to 5 show a second embodiment of the present invention. In Figures 2 to 5, the same parts as in Figure 1 are represented by the same reference numbers. In this second embodiment, as shown in FIG. 3, the axial length of the projecting external part

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  21a of the sealing plate 21 is smaller than in the first embodiment. The upper end of the part 21a is opposite to an inner circumferential part of a flat central part 22b of a deflector 22 which is arranged parallel to the projecting part 19a of the sleeve - 19 while

  now a little predetermined game.

  As shown in FIG. 4 and in FIG. 5, the deflector 22 comprises the flat central part 22b which is opposite to the projecting part 19a and which has a central hole for mounting the bushing 19, a conical part 22a which extends to from the outer end of the flat central part 22b in the direction of the rotor 13 of the compressor while having a decreasing diameter, a walled part which extends vertically from one end of the conical part 22a towards the outside in the diametrical direction and which is fixed to an internal hole 21b of the sealing plate 21 at its external end 22d, an open part 22f which is formed on part of the lower portions of the wall part and of the part conical 22a, respectively, and which opens onto a circular groove 22c formed between the wall part and the conical part 22a outwards in the diametrical direction and a guide portion 22e which s 'extends from a portion of the flat central part 22b obliquely and outwards while

passing through the open part 22f.

  In this embodiment, the oil spouting from the projecting part 19a strikes the wall part of the deflector 22 and falls along this part. Part of the oil passes through the circular groove 22c and is conveyed to the drainage hole 10c via the open part 22f and the guide part 22e. Therefore, it is ensured that the oil does not invade in the direction of the oil seal 20 from the clearance

  the flat central part 22b and the projecting part 19a.

  In addition, even if by chance the oil invades in the direction of the oil seal 20 from the clearance separating the flat central part 22b and the projecting part 19a, the oil is sprayed by centrifugal force and the oil thus sprayed falls into the circular groove formed between the wall part of the sealing plate 21 and the projecting external part 21a. Therefore, the oil is prevented from

leak to the oil seal 20.

  As explained above, according to the present invention, since the oil sprayed by centrifugal force falls along the wall portion and into the circular groove of the sealing plate, it cannot leak in the direction of the rotor of the

compressor.

  Furthermore, according to the present invention, the deflector having the flat central part, the conical part, the wall part, the open part and the guide part can be placed in the sealing plate. In this case, since the oil projected by the centrifugal force falls along the wall part, of the circular groove formed between the flat central part and the wall part, it is ensured that the oil does not can leak in the direction

of the compressor rotor.

  The present invention is not limited to the embodiments which have just been described, it is on the contrary subject to modifications and

  variants which will appear to those skilled in the art.

Claims (3)

  1 - Turbocharger with supercharging, characterized in that it comprises: - a turbine rotor (14), - a compressor rotor (13) - connected to the turbine rotor by a shaft (30), - a housing (10) rotationally supporting the shaft by means of a radial bearing (15), a thrust bearing (18) and a cylindrical bush (19) which is mounted on the shaft between the thrust bearing and the compressor rotor, - a sealing plate (21) fixed to the housing while maintaining a predetermined clearance between the compressor rotor and its walled part and having a cylindrical inner part which extends towards the thrust bearing and in which the sleeve is mounted and an outer projecting part which is formed on the end of the cylindrical part and which extends outwards in the diametrical direction so as to form a circular groove with the walled part, and - a sealing ring (20) disposed between the inner part a cylindrical seal plate and a circumferential outer part from the socket.   2 - Turbocharger according to claim 1, characterized in that the sleeve has a part (19a) which projects outwards in the diametrical direction and which is in contact with the thrust bearing. 3 Turbocharger according to claim 2, characterized in that a deflector (22) is arranged in the sealing plate and has a flat central part opposite to the part which projects and which has a central hole for mounting the socket, and a conical part which extends from the outer end of the flat central part in the direction of the compressor rotor while having a decreasing diameter, a walled part which extends vertically from one end from the tapered part towards the outside in the diametrical direction and which is fixed to the sealing plate at its external end, an open part which is formed on a part of the lower portions of the wall part and of the conical part, respectively, and which leads to a circular groove formed between the wall part and the conical part outwards in the diametrical direction and a guide part which extends from a po rtion of the oblique flat central part and   outwards while passing through the open part.