JP2009228450A - Variable displacement supercharger - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a variable displacement supercharger capable of suppressing the freezing by preventing water from being accumulated in a link chamber. <P>SOLUTION: The variable displacement supercharger includes a variable nozzle mechanism 53 capable of adjusting a turbine flow rate, and a support ring 1 for supporting a part of the variable nozzle mechanism 53 while being sandwiched by a turbine housing 51c and center housing 54. The support ring 1 contains a drain hole 2 and a vent hole 3. The turbine housing 51c contains a drainage hole 4. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a variable displacement supercharger capable of adjusting a turbine flow rate, and more particularly to a variable displacement supercharger including a variable nozzle mechanism.

  As a variable capacity supercharger capable of changing the turbine flow rate according to the operating condition, for example, a variable capacity turbocharger using a variable nozzle mechanism as shown in FIG. 5 is known. Here, FIG. 5 is a cross-sectional view showing a variable displacement supercharger provided with a conventional variable nozzle mechanism. In addition, the supercharger equivalent to the variable capacity | capacitance supercharger shown in FIG. 5 is disclosed by patent document 1 and patent document 2, for example.

  A conventional variable capacity turbocharger includes a gas turbine 51 that rotates a turbine blade 51a by supplying exhaust gas, a compressor 52 that sucks air through an impeller 52a that is coaxially connected to the turbine blade 51a, a gas, And a variable nozzle mechanism 53 configured to adjust a supply amount of the fluid by disposing a vane 53a having a blade shape in a cross section in a fluid supply path 51b of the turbine 51 so as to be rotatable.

  The external form of such a variable capacity turbocharger is as follows: a turbine housing 51c that constitutes the casing of the turbine 51; a compressor housing 52b that constitutes the casing of the compressor 52; a turbine disk 51d having a turbine rotor blade 51a; And a center housing 54 that supports a rotating shaft 54a that connects the two. Further, exhaust gas is supplied to the fluid supply path 51b from a scroll portion 51e formed on the outer periphery of the turbine housing 51c.

  The variable nozzle mechanism 53 includes an annular shroud 53b fixed to the turbine housing 51c, an annular support ring 53c supported between the turbine housing 51c and the center housing 54, and an interval between the shroud 53b and the support ring 53c. A pin 53d to be held, a plurality of vanes 53a rotatably supported between the shroud 53b and the support ring 53c, and a vane driving mechanism for rotating the vane 53a are configured. The vane drive mechanism is rotatably supported by the rotation shaft 53e connected to the vane 53a, the nozzle link plate 53f connected to the rotation shaft 53e, the center housing 54, and connected to the nozzle link plate 53f. The drive shaft 53g, and a connecting member 53h for connecting the piston rod such as an external diaphragm cylinder and the drive shaft 53g. The positions and postures of the support ring 53c and the nozzle link plate 53f are held by an annular support ring 55 that is sandwiched between the turbine housing 51c and the center housing 54.

JP 2002-332854 A JP 2006-125588 A

  As shown in FIG. 5, a fixed space (hereinafter referred to as a link chamber 56) is formed among the variable nozzle mechanism 53, the center housing 54, and the support ring 55. Further, since the support ring 55 is sandwiched between the turbine housing 51c and the center housing 54, the outer end side of the link chamber 56 is sealed. On the other hand, on the inner end side of the link chamber 56, exhaust gas flows into the link chamber 56 through a gap between the rotation shaft 53e of the vane 53a and the nozzle link plate 53f. When the water vapor in the exhaust gas is cooled, water accumulates in the link chamber 56 and may freeze in some cases. Since the nozzle link plate 53f, which is a part of the vane drive mechanism, is disposed in the link chamber 56, the nozzle link plate 53f does not move when water accumulated in the link chamber 56 is frozen. This causes problems such as deformation or failure of the part.

  The present invention has been devised in view of the above-described problems, and an object thereof is to provide a variable capacity supercharger capable of suppressing freezing so that water does not collect in the link chamber.

  According to the present invention, in the variable capacity supercharger having a variable nozzle mechanism capable of adjusting a turbine flow rate and a support ring that is supported by a portion of the variable nozzle mechanism while being sandwiched by a housing, the support ring There is provided a variable capacity supercharger characterized in that a drain hole is formed. It is preferable that the drain hole is formed at a position which is on the lower side in the vertical direction when the variable capacity supercharger is installed.

  The support ring may have a vent hole. At this time, the sum total of the opening area of the drain hole and the gas vent hole is set larger than the sum of the opening areas of the gaps formed in the space formed by the support ring, the housing, and the variable nozzle mechanism. It is preferable. Furthermore, a drain hole for discharging water discharged from the drain hole to the outside of the support ring to the inside or outside of the exhaust gas passage may be formed in the housing.

  According to the above-described variable capacity supercharger of the present invention, the drain hole is formed in the support ring that forms part of the link chamber (a space formed by the support ring, the housing, and the variable nozzle mechanism) in which water is likely to accumulate. As a result, water accumulated in the link chamber can be discharged outside the link chamber, and water can be prevented from collecting in the link chamber. Therefore, the malfunction and failure of the variable nozzle mechanism due to freezing of water in the link chamber can be suppressed. In particular, by arranging the drain hole on the lower side in the vertical direction, water accumulated in the link chamber due to gravity can be easily discharged out of the link chamber.

  In addition, by forming a gas vent hole in the support ring, it is possible to make it difficult for soot in the exhaust gas to adhere to the variable nozzle mechanism, and to reduce the cause of failure and wear. Furthermore, by setting the opening area of the vent hole or drain hole larger than the opening area of the gap in the link chamber, the exhaust gas can be positively discharged from the vent hole or drain hole.

  Further, by forming a drain hole for discharging the water discharged outside the link chamber to the inside or outside of the exhaust gas passage, the water accumulated in the link chamber can be discharged more effectively to the outside of the link chamber. In particular, when draining into the exhaust gas flow path, it is not necessary to form a hole communicating with the outside of the supercharger, and therefore it is possible to drain without reducing the efficiency of the supercharger.

  Hereinafter, an embodiment of the present invention will be described with reference to FIGS. Here, FIG. 1 is a sectional view showing a variable capacity supercharger according to the present invention. In addition, the same code | symbol is attached | subjected about the same component as the conventional variable capacity | capacitance supercharger shown in FIG. 5, and the overlapping description is abbreviate | omitted.

  The variable capacity supercharger of the present invention shown in FIG. 1 includes a variable nozzle mechanism 53 capable of adjusting the turbine flow rate, and a support that supports a part of the variable nozzle mechanism 53 while being sandwiched between the turbine housing 51c and the center housing 54. The support ring 1 is formed with a water drain hole 2 and a gas vent hole 3, and the turbine housing 51 c is formed with a drain hole 4. In the illustrated variable capacity supercharger, the vertical direction in the figure matches the vertical direction when the variable capacity supercharger is installed in a vehicle or the like.

  FIG. 2 is a perspective view of the support ring 1. The support ring 1 includes a flange portion 1a that is sandwiched between the turbine housing 51c and the center housing 54, a cylindrical portion 1b that extends toward the turbine 51 in the axial direction of the rotating shaft 54a, and a support portion that is reduced in diameter. 1c. The support portion 1c has a step portion 1d, and the support ring 53c and the nozzle link plate 53f are supported by the support portions 1c before and after the step portion 1d.

  The inner side of the cylindrical portion 1b of the support ring 1 forms the inner peripheral surface of the link chamber 56, and the water generated when the exhaust gas flowing into the link chamber 56 is cooled is vertical inside the cylindrical portion 1b. It tends to collect in the lower direction. Accordingly, as shown in FIGS. 1 and 2, the drain hole 2 is formed at a position on the lower side in the vertical direction of the cylindrical portion 1 b of the support ring 1. The radius of the drain hole 2 may be a size that allows the water accumulated in the link chamber 56 to be discharged. However, when the water discharge speed of the drain hole 2 is slow, it is assumed that the water is frozen without being completely discharged. Further, a plurality of drain holes 2 may be formed on the lower side in the vertical direction of the cylindrical portion 1b.

In addition, when exhaust gas flows into the link chamber 56 through a gap between the rotation shaft 53e of the vane 53a and the nozzle link plate 53f or the like, if the exhaust gas stays in the link chamber 56, exhaust gas traps on the rotation shaft 53e. It adheres and causes troubles in the rotation of the vane 53a, or wear of the rotation shaft 53e is accelerated. Therefore, the gas vent hole 3 is formed in the cylindrical portion 1 b of the support ring 1 so that the exhaust gas flowing into the link chamber 56 can be discharged. Here, the gas vent hole 3 is formed on the upper side in the vertical direction which is opposite to the water drain hole 2 (phase difference 180 °), but is not limited thereto. The opening area of the gas vent hole 3 is ideally set to be larger than the sum of the opening areas of the gaps generated in the link chamber 56 so that the exhaust gas can be actively discharged from the gas vent hole 3. . Here, if the sum of the opening areas of the gaps generated in the link chamber 56 is S and the radius of the gas vent hole 3 is r, the radius r of the gas vent hole 3 is set so as to satisfy πr ² > S. . For example, when the sum S of the opening areas of the gaps generated in the link chamber 56 is 10 mm ² , the radius r is set to about 2 mm. Further, the “gap generated in the link chamber 56” can be actually replaced with “gap generated between the rotation shaft 53e and the support ring 53c”. In this case, the sum S of the opening areas can be expressed as S = the opening area of the gap formed between each rotation shaft 53e and the support ring 53c × the number of the rotation shafts 53e. The number of rotating shafts 53e is, for example, about 11, but varies depending on the type and capacity of the supercharger.

By the way, in the normal operation state of the variable capacity supercharger, the temperature of the exhaust gas is high, so that the exhaust gas flowing into the link chamber 56 is difficult to liquefy. That is, when the moisture of the exhaust gas flowing into the link chamber 56 is in a evaporated state, the drain hole 2 does not function as a drain hole, but rather can function as a vent hole. Therefore, the sum of the opening areas of the drain holes 2 and the gas vent holes 3 can be set to be larger than the sum of the opening areas of the gaps generated in the link chamber 56. Here, assuming that the sum of the opening areas of the gaps generated in the link chamber 56 is S, the radius of the drain hole 2 is R, and the radius of the gas vent hole 3 is r, (πR ² + πr ² )> S is satisfied. The radius R of the water drain hole 2 and the radius r of the gas vent hole 3 are set. For example, when the sum S of the opening areas of the gaps generated in the link chamber 56 is 10 mm ² , (radius R, radius r) may be set to (1.5 mm, 1.5 mm), or (1 mm , 2 mm), or (2 mm, 1 mm).

  Here, FIG. 3 is a cross-sectional view of the cylindrical portion 1b of the support ring 1, wherein (A) is the embodiment shown in FIG. 2, (B) is a first modification, and (C) is a second modification. Show.

  As shown in FIG. 3A, in the cylindrical portion 1b of the support ring 1 shown in FIG. 2, one drain hole 2 is formed on the lower side in the vertical direction, and one gas vent hole 3 is formed on the upper side in the vertical direction. Is formed. Here, the drain hole 2 is formed at the bottom in the vertical direction and the gas vent hole 3 is formed at the top in the vertical direction. In the present invention, the lower side in the vertical direction means the lower half of the support ring 1. The upper side in the vertical direction means the upper half range of the support ring 1. Therefore, even when a pair of drain holes 2 and gas vent holes 3 are formed, the arrangement is not necessarily limited to the arrangement shown in FIG.

  In the first modification shown in FIG. 3B, two drain holes 2 are formed on the lower side in the vertical direction of the cylindrical portion 1b of the support ring 1, and one gas vent hole 3 is formed on the upper side in the vertical direction. Yes. Also in the first modified example, the arrangement is not limited to the illustrated arrangement, and the center ring 54 or the turbine housing 51c is rotated by rotating the support ring 1 so that one drain hole 2 is arranged at the lowest in the vertical direction. You may make it fit in. The central angle α of the two drain holes 2 can be set in a range of 0 ° <α <180 °, but the central angle α is set to 120 ° in FIG. In addition, what is necessary is just to set so that the central angle (alpha) may approach 0 degrees, when wanting to speed up drainage.

  In the second modification shown in FIG. 3 (C), the water drain holes 2 and the gas vent holes 3 are formed evenly at the four locations of the cylindrical portion 1b of the support ring 1. In this case, the lowermost hole is the water draining hole 2, the uppermost hole is the gas venting hole 3, and the two holes in the middle are basically the gas venting hole 3. It can also function. Also in the second modified example, the arrangement is not limited to the illustrated arrangement, and the support ring 1 is rotated by 45 ° from the state shown in FIG. 3C so as to be fitted to the center housing 54 or the turbine housing 51c. Also good. In this case, the two holes on the lower side in the vertical direction function as the drain holes 2, and the two holes on the upper side in the vertical direction function as the gas vent holes 3.

  In any case of the second modification and the third modification described above, the sum of the opening areas of the gas vent holes 3 may be set to be larger than the sum of the opening areas of the gaps generated in the link chamber 56. Alternatively, the sum of the opening areas of the drain holes 2 and the gas vent holes 3 may be set to be larger than the sum of the opening areas of the gaps generated in the link chamber 56. The “gap generated in the link chamber 56” may be replaced with “gap generated between the rotation shaft 53e and the support ring 53c”.

  Next, the drain hole 4 will be described. The drain hole 4 shown in FIG. 1 is a hole for discharging the water discharged from the drain hole 2 into the exhaust gas passage. In FIG. 1, the horizontal hole formed in the wall surface part which comprises the scroll part 51e of the turbine housing 51c is used as the drainage hole 4. FIG. By forming the drain hole 4, the water discharged from the drain hole 2 can be discharged into the scroll part 51e, and can be vaporized by the high-temperature exhaust gas flowing through the scroll part 51e. Further, in order to smoothly discharge the water discharged from the drain hole 2 from the drain hole 4, it is preferable to form the drain hole 4 at a position equal to or less than the horizontal position of the drain hole 2. A plurality of drain holes 4 may be formed. Thus, when draining the water discharged from the drain hole 2 into the exhaust gas flow path, it is not necessary to form a hole communicating with the outside of the supercharger, thereby reducing the efficiency of the supercharger. It can be drained without any problems.

  Next, another embodiment of the variable capacity supercharger according to the present invention will be described. Here, FIG. 4 is a partial sectional view showing another embodiment of the variable capacity supercharger according to the present invention, (A) is the second embodiment, (B) is the third embodiment, (C ) Shows the fourth embodiment. In addition, the same code | symbol is attached | subjected about the same component as the variable capacity | capacitance supercharger shown in FIG. 1, and the overlapping description is abbreviate | omitted.

  In the second embodiment shown in FIG. 4A, the drain hole 2 is formed in the support ring 1 and the drain hole 4 shown in FIG. 1 is omitted. In such an embodiment, the water accumulated in the link chamber 56 is discharged from the drain hole 2 into a space 41 surrounded by the outer peripheral surface of the support ring 1 and the turbine housing 51c. In particular, this embodiment is effective when the amount of water accumulated in the link chamber 56 is small. Since the space 41 is close to the scroll part 51e through which the high-temperature exhaust gas flows, the water discharged into the space 41 is vaporized by the high-temperature exhaust gas flowing through the scroll part 51e.

  In the third embodiment shown in FIG. 4 (B), a drain hole (drain hole 42) for draining water discharged into the space 41 to the outside is formed in the second embodiment shown in FIG. 4 (A). It is. In this embodiment, the drain hole 42 is formed in the turbine housing 51 c that forms the space 41. The drain hole 42 is formed by, for example, a drain reservoir 42a and a pore 42b as illustrated. The drain hole 42 is formed, for example, by forming a hole capable of screwing a drain bolt into the turbine housing 51c and forming a drain bolt or a groove capable of draining when the drain bolt is screwed into the turbine housing 51c. .

  In the fourth embodiment shown in FIG. 4C, a drain hole 42 serving as a drain hole is formed in a turbine housing 51c constituting the scroll part 51e. By forming the drain hole 42 at this position, the water discharged from the drain hole 2 can be drained to the outside. As shown in FIG. 4C, when the scroll portion 51e projects downward from the horizontal position of the drain hole 2, the drain hole 4 may be formed obliquely downward.

  The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention.

It is sectional drawing which shows the variable capacity | capacitance supercharger which concerns on this invention. It is a perspective view of a support ring It is sectional drawing in the cylinder part of a support ring, (A) is embodiment shown in FIG. 2, (B) is a 1st modification, (C) has shown the 2nd modification. It is a fragmentary sectional view which shows other embodiment of the variable capacity | capacitance supercharger which concerns on this invention, (A) is 2nd embodiment, (B) is 3rd embodiment, (C) is 4th embodiment. Show. It is sectional drawing which shows the variable capacity | capacitance supercharger provided with the conventional variable nozzle mechanism.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Support ring 1a Flange part 1b Cylinder part 1c Support part 1d Step part 2 Drain hole 3 Gas vent hole 4,42 Drain hole 41 Space 42a Drain pool 42b Pore 51 Turbine 51a Turbine blade 51b Fluid supply path 51c Turbine housing 51d Turbine disk 51e Scroll unit 52 Compressor 52a Impeller 52b Compressor housing 53 Variable nozzle mechanism 53a Vane 53b Shroud 53c Support ring 53d Pin 53e Rotating shaft 53f Nozzle link plate 53g Drive shaft 53h Connecting member 54 Center housing 54a Rotating shaft

Claims (5)

In a variable capacity supercharger having a variable nozzle mechanism capable of adjusting a turbine flow rate, and a support ring that supports a part of the variable nozzle mechanism while being sandwiched between housings,
A variable capacity supercharger, wherein a drain hole is formed in the support ring.   2. The variable capacity supercharger according to claim 1, wherein the drainage hole is formed at a position that is vertically downward when the variable capacity supercharger is installed. 3.   The variable capacity supercharger according to claim 1, wherein the support ring has a vent hole.   The sum of the opening areas of the drain holes and the gas vent holes is set to be larger than the sum of the opening areas of the gaps formed in the space formed by the support ring, the housing, and the variable nozzle mechanism. The variable capacity supercharger according to claim 3, wherein   2. The variable capacity supercharging according to claim 1, wherein a drain hole for discharging water discharged from the drain hole to the outside of the support ring into or out of an exhaust gas passage is formed in the housing. Machine.