JP6364331B2 - Turbine housing - Google Patents

Description

  The present invention relates to an exhaust turbine housing (turbine housing) in a turbocharger, and more particularly to a turbine housing with a water cooling jacket.

  A conventional general turbine housing is a cast product by casting. The advantages of the cast housing are that the degree of freedom in setting the shape is large and the productivity is good, and that the use of heat-resistant steel and high rigidity are easy and the durability is excellent. In recent years, the exhaust gas temperature has increased with the improvement in fuel efficiency of the engine, and therefore, iron-based materials such as austenite tend to be used. However, although austenite is excellent in heat resistance and the like, it has a drawback of high cost. In addition, iron-based castings are heavy and have the disadvantage that there is a limit to thinning them.

  As an attempt to reduce the weight and cost of the turbine housing as compared with the conventional ones, proposals have been made to make the housing main body made of stainless steel plate or made of an aluminum alloy with a water cooling jacket (hereinafter simply referred to as “water cooled aluminum”). However, the turbine housing made of stainless steel sheet has the disadvantage that it is very difficult to achieve both function (endurance reliability, etc.) and cost due to manufacturing problems in parts that require high precision machining and deformation due to thinning. There is. On the other hand, according to the turbine housing made of water-cooled aluminum, an aluminum material can be used by providing a water-cooled jacket, and there is an advantage that material costs can be reduced compared to austenite. However, aluminum has a considerably higher thermal conductivity than cast iron (the thermal conductivity of aluminum at 300 ° C .: 233 (W / m · K), whereas the thermal conductivity of cast iron at 300 ° C .: 31 (W / m · k). K) degree). For this reason, the heat of the exhaust gas flowing in the turbine housing is excessively transmitted to the water cooling jacket through the aluminum housing wall, resulting in a decrease in heat or kinetic energy due to excessive cooling of the exhaust gas, and in turn a decrease in supercharging performance. It has become. Further, since the cooling water flowing through the water cooling jacket is excessively heated, it is necessary to improve the cooling performance on the engine side (that is, increase the capacity of the radiator), resulting in an increase in cost.

  Patent Document 1 discloses an example of a turbine housing with a water cooling jacket. According to Patent Document 1, the main body of the turbine housing (10) is a cast part made of an aluminum alloy or other metal. In order to form the hollow chamber (12) around the housing body, two shell members (14, 16) are provided, and a cooling jacket (18) is constituted by these shell members. In addition, at least one flow element (28) for guiding the coolant is provided inside the cooling jacket (18) and on the outer periphery of the housing body. FIG. In 1 and 2, the flow elements are depicted in the form of ridges.

International Publication WO2009 / 106166

  The present invention is intended to overcome the disadvantages of conventional water-cooled aluminum turbine housings while taking advantage of the advantages of conventional cast turbine housings. That is, an object of the present invention is to prevent a decrease in supercharging efficiency by avoiding a decrease in heat or kinetic energy due to excessive cooling of the exhaust gas flowing through the exhaust gas flow path as much as possible, and cooling through the water cooling jacket. It is an object of the present invention to provide a turbine housing with a water cooling jacket capable of reducing the amount of water.

The present invention is provided between a scroll main body section that internally defines and forms a storage chamber of an exhaust turbine and an exhaust gas passage surrounding the exhaust chamber, and an outer wall surface of the scroll main body section. A turbine housing comprising a shell defining a water-cooled jacket,
The scroll body is configured as a casting made of an iron-based material,
On the outer wall surface of the scroll main body portion, a flow path partitioning portion that divides the inside of the water cooling jacket into two cooling water flow paths is provided, and a plurality of heat radiation convex portions or uneven portions are provided ,
The flow path partition has a starting point in the vicinity of the inlet port of the scroll main body, extends from the starting point along the exhaust gas flow path, and reaches an end point at a position about half the circumference of the side surface of the scroll main body. Extended,
The flow path partition having a starting point and an ending point is
An inflow-side cooling water channel that guides the cooling water from the cooling water inlet to the end point along the channel partition; and
Outflow side cooling that flows along the inflow side cooling water flow path to the back of the water cooling jacket and guides the cooling water that is reversed and reversed when reaching the end point toward the cooling water outlet, along the flow path partitioning portion. A turbine housing characterized in that a water flow path is provided .

  The shell is preferably made of sheet metal or resin.

[Action]
According to the present invention, the scroll main body portion that forms the accommodating chamber of the exhaust turbine and the exhaust gas passage surrounding it is made of a cast iron-based material having a thermal conductivity lower than that of aluminum. For this reason, it is possible to prevent the heat of the exhaust gas flowing through the scroll main body from being transmitted more than necessary to the cooling water flowing through the water cooling jacket, thereby avoiding excessive cooling of the exhaust gas, and thus excessive heat or kinetic energy. A decrease in supercharging efficiency due to a significant decrease can be prevented.
Further, in the turbine housing of the present invention, a plurality of heat radiating projections or projections are provided on the outer wall surface of the scroll body in addition to the flow path partition. These multiple heat-radiating projections or irregularities increase the contact area between the cooling water flowing through the water-cooling jacket and the outer wall surface of the scroll body to enable efficient heat transfer. Thus, the casting scroll main body can be cooled (inhibition of high temperature).

  In addition, the weight of the turbine housing with a water cooling jacket can be reduced by forming the shell for partitioning and forming the water cooling jacket outside the casting scroll main body from sheet metal or resin instead of casting.

  According to the turbine housing of the present invention, it is possible to prevent a decrease in supercharging efficiency by avoiding a decrease in heat or kinetic energy due to excessive cooling of the exhaust gas flowing through the exhaust gas flow path, and distribute the water cooling jacket. The required amount of cooling water can be reduced as compared with the prior art.

1 and 2 show an overall view of a turbine housing with a water-cooling jacket according to an embodiment of the present invention, in which (A) in FIG. 1 is a front view and (B) is a right side view. 2A is a rear view, and FIG. 2B is a plan view (top view). FIG. 3 is a schematic cross-sectional view taken along line XX in FIG. 4 is a schematic cross-sectional view taken along line YY of FIG. FIG. 5 is a side view of a casting scroll main body. FIG. 6 is a plan view (top view) of the casting scroll main body. (A)-(D) of FIG. 7 is the elements on larger scale which show the variation (structure example) of the convex part for heat dissipation provided in the outer wall surface of the casting scroll main-body part, or an uneven | corrugated | grooved part.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
As shown in FIGS. 1 to 4, a turbine housing with a water cooling jacket according to an embodiment of the present invention includes a scroll body 10 made of casting, first and second shells 21 and 22 made of sheet metal or resin, metal An inlet flange 30 made of metal and an outlet flange 40 made of metal are provided.

  In particular, as shown in FIGS. 3 and 4, the scroll main body 10 has a housing chamber 11 for an exhaust turbine (not shown) defined in the center region thereof, and is substantially annular at a position surrounding the exhaust turbine housing chamber 11 ( More specifically, it is a hollow casting part whose basic shape (the basic shape itself is publicly known) is that the exhaust gas passage 12 having a substantially spiral shape is partitioned. An inlet port 13 for introducing exhaust gas from the vehicle engine into the exhaust gas passage 12 is provided on the front side of the scroll main body 10 (left side in FIG. 4). Further, in the vicinity of the center of one side surface of the scroll main body 10 (right side in FIG. 3), the exhaust gas collected in the exhaust turbine housing chamber 11 via the exhaust gas passage 12 is exhausted from the vehicle (catalytic converter, muffler, etc.). An outlet port 14 is provided for discharging toward the air. The structure of the outer wall surface of the scroll body 10 will be described later.

  As shown in FIGS. 1 to 4, a first shell 21 and a second shell 22 are disposed outside the scroll body 10. The first and second shells 21 and 22 are respectively formed as cover-like members that cover the left half and the right half of the scroll main body 10, and the first and second shells 21 and 22 are formed. As a result of the combination, the scroll body 10 is wrapped in both shells. When the first and second shells 21 and 22 are attached to the scroll body 10, the water cooling jacket 23 is defined between the inner wall surfaces of both shells and the outer wall surface of the scroll body. The water cooling jacket 23 provides cooling water flow paths (24, 25) therein.

  As shown in FIG. 1 (A), FIG. 2 (A) and FIG. 4, the inlet flange 30 is attached to the position of the inlet port 13 of the scroll main body, and the inlet port 13 of the scroll main body is defined at the same position. The peripheral wall portion to be connected to the edge portions of the first and second shells 21 and 22 are connected. As can be seen from FIGS. 1A and 4, the inlet flange 30 is formed with a central opening 31 for exhaust gas communicating with the inlet port 13 in the central area, and below and above the central opening 31. A cooling water inlet 32 and a cooling water outlet 33 are formed at each position. The cooling water introduction port 32 and the cooling water outlet port 33 communicate with a cooling water flow path set in the water cooling jacket 23. The inlet flange 30 is a flange part for connecting the exhaust manifold and cooling system of the vehicle engine and the turbine housing with the water cooling jacket. When the inlet flange 30 is connected to an exhaust manifold or the like of the vehicle engine, the central opening 31 is connected to the downstream side of the exhaust manifold, and the cooling water inlet 32 and the cooling water outlet 33 are used to cool the vehicle engine. It will be connected to the system (including the radiator).

  As shown in FIG. 3, the outlet flange 40 is disposed at the position of the outlet port 14 of the scroll main body portion, and is fixed in an externally fitted state to the peripheral wall portion defining the outlet port 14. The outlet flange 40 is a flange part for connecting the exhaust system (catalytic converter, muffler, etc.) of the vehicle further downstream of the exhaust manifold and the turbine housing with the water cooling jacket. By connecting the outlet flange 40 to the exhaust system of the vehicle, the outlet port 14 is connected to the exhaust system of the vehicle.

  In the present invention, the scroll body 10 is configured as a casting made of an iron-based material. Examples of the iron-based material include cast iron (eg, spheroidal graphite cast iron and gray cast iron) and cast steel. Any of these iron-based materials is a metal having a lower thermal conductivity than aluminum or an aluminum alloy. And when this scroll main-body part 10 is cast, the flow-path partition part 16 and the several convex part or uneven | corrugated | grooved part 17 for heat dissipation are formed simultaneously in the outer wall surface 15 of a scroll main-body part (FIG. 3, FIG. 5-7).

  As shown in FIGS. 3, 5, and 6, on the left and right outer wall surfaces 15 of the scroll main body portion, a single channel partition portion (channel partition protrusion) 16 is provided. Each of the flow path partition sections 16 extends along the exhaust gas flow path 12 starting from the vicinity of the inlet port of the scroll body section 10 (indicated by reference numeral “16a” in FIGS. 5 and 6) (see FIG. 5). The scroll main body 10 extends to the end point (indicated by reference numeral “16b” in FIG. 5) at the lowest position of the main body when the side surface of the scroll main body 10 is about half a round. Each of the pair of left and right flow path partition sections 16 divides the inside of the water cooling jacket 23 into a lower area (inner area) and an upper area (outer area) of the flow path partition section.

  That is, the lower region (inner region) of the flow path partition 16 communicates with the cooling water inlet 32 of the inlet flange and guides the cooling water from the cooling water inlet 32 along the flow path partition 16. An inflow side cooling water flow path 24 is provided. In contrast, the upper region (outer region) of the flow path partitioning portion 16 communicates with the cooling water outlet 33 of the inlet flange. In the upper region (outer region) of the flow path partitioning portion 16, the cooling water flowing into the water cooling jacket 23 along the inflow side cooling water flow channel 24 reaches the end point 16 b of the flow path partitioning portion. Then, after turning back and turning (U-turn), the outflow side cooling water flow path 25 for guiding the cooling water along the flow path partitioning portion 16 toward the cooling water outlet 33 is provided.

  In addition, in the state where the first and second shells 21 and 22 are attached to the outside of the scroll main body portion 10, the top portion of the flow path partition portion 16 (the top portion in the height direction of the protrusion) is the inner wall surface of the shell. Or the height of the flow path partitioning portion 16 is set so that the gap existing between the top of the flow path partitioning portion 16 and the inner wall surface of the shell is 0.5 mm or less. Thus, if the gap is 0.5 mm or less, even if such a gap exists, the function as the “channel partition” of the channel partition unit 16 is not impaired at all.

  As shown in FIGS. 5 and 6, on the top, bottom, left, and right outer wall surfaces 15 of the scroll main body portion, in addition to the pair of left and right flow path partition portions (flow path partition protrusions) 16, a plurality of heat radiation convex portions. Or the uneven part 17 is provided. The “plural thick broken lines” depicted in FIGS. 5 and 6 schematically and conceptually show the state of arrangement or arrangement of the heat radiating convex portions or the concavo-convex portions 17. It does not represent a specific form of the heat radiating convex portion or the concave and convex portion 17.

  FIGS. 7A to 7D show a configuration example of the heat dissipation convex portion or the concave and convex portion 17 that is preferable or that can be adopted. For example, as shown in FIG. 7A, rib protrusions 17a having a short length are arranged in series along the flow direction of the cooling water (indicated by arrows in the figure), and the rib protrusions arranged in series. A plurality of rows 17a may be arranged substantially in parallel. Further, as shown in FIG. 7B, circular small protrusions 17b as viewed from the front may be regularly arranged (for example, arranged at lattice point positions of a square lattice). Further, as shown in FIG. 7C, the cross-shaped small protrusions 17c as viewed from the front may be regularly arranged (for example, arranged at lattice point positions of a square lattice). Further, as shown in FIG. 7D, a plurality of protrusions extending in the vertical direction and a plurality of protrusions extending in the horizontal direction may be configured as a group of lattice-like protrusions 17d. .

  In addition, the height of the heat radiating convex portion or the concavo-convex portion 17 (17a to 17d) is about half of the average distance between the outer wall surface of the scroll body 10 and the inner wall surfaces of the shells 21 and 22, for example, 1.2 to It is preferably about 2.5 mm.

  When the turbine housing of the present embodiment is connected to the vehicle engine via the inlet flange 30, the cooling water (that is, engine coolant) from the radiator that is the main component of the cooling system of the vehicle engine is supplied to the cooling water inlet 32. It becomes possible to introduce into the water cooling jacket 23 via The cooling water introduced from the cooling water introduction port 32 flows into the back of the water cooling jacket 23 along the inflow side cooling water flow path 24 occupying the lower area (inner area) of the flow path partitioning section 16, and then flows. It flows backward toward the inlet flange 30 along the outflow side cooling water flow path 25 occupying the upper region (outer region) of the road partition 16. Then, the cooling water flows out of the water cooling jacket 23 from the cooling water outlet 33 and is returned to the cooling system of the vehicle engine.

  In the present embodiment, the scroll main body 10 that forms the exhaust turbine housing chamber 11 and the exhaust gas passage 12 is made of a cast iron-based material whose thermal conductivity is lower than that of aluminum. For this reason, the situation where the heat of the exhaust gas flowing through the scroll main body 10 is transmitted more than necessary to the cooling water flowing through the water cooling jacket 23 can be prevented, and the exhaust gas can be prevented from being excessively cooled. As a result, it is possible to prevent a decrease in supercharging efficiency due to excessive reduction in heat or kinetic energy of the exhaust gas. Further, since the cooling water returned to the engine cooling system after exiting the water cooling jacket 23 of the turbine housing is not excessively heated, the heat exchange load of the radiator is not particularly increased, and as a result, the radiator capacity is increased. There is no need to increase the equipment cost of the cooling system.

  In the turbine housing of the present embodiment, the outer wall surface 15 of the scroll body 10 is provided with a plurality of heat radiating projections or depressions 17 (17a to 17d) in addition to the flow path partitioning portion 16. The plurality of heat radiating projections or projections 17 increase the contact area between the cooling water flowing through the water cooling jacket 23 and the outer wall surface 15 of the scroll body to enable efficient heat transfer. For this reason, cooling (high temperature prevention) of the scroll-made scroll main body 10 can be achieved with a smaller amount of cooling water than in the past. In addition, the fact that the scroll main body 10 is an iron-based material (for example, cast iron) having higher heat resistance than aluminum also contributes to the reduction of the required amount of cooling water. In addition, the fact that the required amount of cooling water is small contributes to keeping the equipment cost of the cooling system low.

  In this embodiment, the shells 21 and 22 that define and form the water-cooling jacket 23 are made of sheet metal or resin instead of casting, thereby reducing the weight of the turbine housing with the water-cooling jacket.

[Example of change]
In the above embodiment, the shell for forming the water cooling jacket 23 is constituted by two parts (21, 22). However, the water cooling jacket 23 may be formed by a single shell part.

DESCRIPTION OF SYMBOLS 10 Scroll main-body part 11 Exhaust turbine accommodating chamber 12 Exhaust gas flow path 15 Outer wall surface 16 of a scroll main-body part Flow path partition part (flow-path partition protrusion)
17 (17a to d) Heat radiating convex or concave portion 21 First shell 22 Second shell 23 Water cooling jacket 24, 25 Cooling water flow path

Claims (2)

A scroll main body for defining an exhaust turbine housing chamber and an exhaust gas flow path surrounding the chamber, and
A turbine housing provided on the outside of the scroll main body portion and including a shell that forms a water-cooled jacket between the outer wall surface of the scroll main body portion,
The scroll body is configured as a casting made of an iron-based material,
On the outer wall surface of the scroll body, a flow path partitioning portion (16) for dividing the inside of the water cooling jacket into two cooling water flow channels (24, 25 ) is provided, and a plurality of heat radiating protrusions or unevennesses are provided. Part is provided ,
The flow path partitioning portion (16) has a starting point (16a) in the vicinity of the inlet port of the scroll main body portion, extends from the starting point along the exhaust gas flow path, and is about half the circumference of the side surface of the scroll main body portion. Extends to the end point (16b) at the position of
The flow path partition (16) having the start point (16a) and the end point (16b)
An inflow-side cooling water flow path (24) for guiding cooling water from the cooling water introduction port along the flow path partition portion (16) to the end point (16b);
The cooling water that has flowed into the depth of the water cooling jacket along the inflow side cooling water flow path (24) and turned over when reaching the end point (16b) is directed toward the cooling water outlet and the flow path partitioning section (16 And an outflow side cooling water flow path (25) guided along
A turbine housing characterized by that.   The turbine housing according to claim 1, wherein the shell is made of sheet metal or resin.

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