JP6207474B2 - Turbocharger - Google Patents

Description

  The present invention relates to a supercharger used in an internal combustion engine, and more particularly, to a supercharger including an actuator that adjusts the opening degree of a wastegate valve.

  Conventionally, superchargers are widely used for applications such as automobile engines. In such a supercharger, a turbine housing and a compressor housing are generally assembled together via a center housing. The rotation of the turbine rotor rotated by the exhaust gas of the engine is transmitted to the compressor rotor through the bearing shaft in the center housing. The supply air is compressed by the rotation of the compressor rotor, and supercharging is performed. In order to properly perform supercharging, the rotation of the turbine rotor is adjusted. This adjustment is performed by adjusting the flow rate that bypasses the exhaust gas supplied to the turbine rotor to the wastegate side. In order to adjust the flow rate of exhaust gas to be bypassed in this way, a wastegate valve is provided in the wastegate, and the opening degree of the wastegate valve is adjusted by an actuator.

  As described above, the actuator is generally provided on the compressor housing side in order to adjust the opening degree of the wastegate valve and to avoid heat from the turbine housing that becomes high temperature. The control rod and relay rod extending from the actuator arranged in this manner are connected to the wastegate valve turning arm on the turbine housing side. Then, when the control rod and the relay rod are displaced in the axial direction by the operation of the actuator, the rotating arm is rotated, and the opening degree of the waste gate valve is adjusted.

  By the way, the actuator must be mounted so that unnecessary vibration does not occur. This is because if vibration occurs, this vibration propagates to the control rod, the relay rod, etc., and the opening degree of the wastegate valve cannot be adjusted appropriately and stably. In some cases, the vibration of the actuator may cause resonance, and the control rod may be brittlely broken.

Various proposals have already been made for attaching such an actuator (see, for example, Patent Document 1). The technique described in Patent Document 1 is to form an actuator mounting flange by casting across an inlet pipe and an outlet pipe of a compressor housing. It is said that the support rigidity of the actuator can be increased.
In addition, the disclosure of a technique for attaching an actuator to a stay provided in a compressor housing with a bolt is also recognized in other documents (see, for example, Patent Document 2).

JP 2014-58894 A JP 2013-53179 Gazette

However, it is difficult to suppress the vibration of the actuator in any of the above-described patent documents unless the compressor housing itself has sufficient rigidity. That is, in order to sufficiently suppress the vibration of the actuator, it is necessary to make the compressor housing thick and rigid, which causes a problem that the weight increases and the fuel consumption deteriorates.
In general, when the turbocharger is installed, only the turbine housing portion is directly attached to the block of the engine body having high rigidity. For this reason, an actuator that is inevitably located away from the attachment site acts by amplifying vibrations from the engine body. For this reason, special consideration is required for the suppression of vibration.

  The present invention has been made to eliminate the above-described conventional problems, and an object thereof is to provide a supercharger that can sufficiently suppress vibration of an actuator while being lightweight.

  The inventors of the present invention have repeatedly studied and experimented to find a solution to the above problem, and have completed the present invention.

(1) A turbocharger in which a turbine housing (for example, a turbine housing 10 described later) and a compressor housing (for example, a compressor housing 20 described later) are integrally assembled via a center housing (for example, a center housing 30 described later). (For example, a supercharger 1 described later)
A wastegate (for example, a later-described wastegate 12) and a wastegate valve (for example, a later-described wastegate valve 13) provided in the turbine housing;
An actuator for adjusting the opening of the wastegate valve (for example, an actuator 40 described later),
The actuator is attached to the compressor housing via an attachment member (for example, an attachment member 200 described later),
The supercharger according to claim 1, wherein the attachment member has a center housing side connection portion connected to the compressor housing at a portion of the compressor housing assembled with the center housing.

  In the supercharger of the above (1), the actuator mounting member (the connecting portion on the center housing side) is connected to a portion that is connected to the center housing that is much higher in rigidity than the surrounding structural portion in a normal configuration. The vibration of the actuator is sufficiently suppressed. Further, since it is not necessary to make the compressor housing particularly thick and highly rigid, there is no inconvenience such as an increase in the weight of the supercharger.

  (2) The compressor housing has an inlet housing portion (for example, an inlet housing portion 22 described later) connected to the upstream intake passage, and the attachment member is connected to the inlet housing portion connected to the inlet housing portion. The supercharger as described in said (1) which has a part (For example, the below-mentioned inlet housing side connection part 202).

  In the supercharger of (2), in addition to the effect of the supercharger of (1), the inlet housing portion inevitably thick and rigid because it is a connecting portion to the upstream intake passage. Since the attachment member is connected at the inlet housing side connecting portion, the vibration of the actuator is sufficiently suppressed, and there is no possibility of causing resonance.

  (3) The mounting member includes a scroll portion (for example, a scroll portion 23 described later) in which the connection end of the center housing side connection portion and the connection end of the inlet housing side connection portion are pressurized with the intake air flowing into the compressor housing. The supercharger as set forth in (2) above, wherein each of the corresponding connecting portions on the center housing side and the connecting portion with the inlet housing portion is connected to each other.

  In the supercharger of the above (3), in addition to the function and effect of the supercharger of the above (2), the mounting member is not mainly involved in supporting the actuator by the scroll portion having a relatively low rigidity. In this way, the connecting end of the center housing side connecting portion and the connecting end of the inlet housing side connecting portion reach the corresponding connecting portion on the center housing side and the connecting portion with the inlet housing portion, and are connected to each other. Therefore, the connection at the connection end is strong and highly rigid, and the rigidity associated with the attachment of the attachment member is not reduced.

  (4) The mounting member is a coupling portion (for example, a coupling described below) that couples a flange-shaped actuator holding portion (for example, an actuator holding portion 203 described later) and the center housing side connection portion for holding the actuator. 204), and the angle formed by the extending direction of the outer edge of the coupling portion and the direction perpendicular to the flange surface that couples the actuator of the flange-shaped actuator holding portion is a side surface from the direction along the flange surface. The supercharger according to any one of (1) to (3), which is approximately 45 degrees in view.

  In the supercharger of (4), in addition to the operational effects of any of the superchargers of (1) to (3), the rigidity of the mounting member is further increased, reducing the increase in weight. Suppression of vibration is more thorough.

  ADVANTAGE OF THE INVENTION According to this invention, the supercharger which can fully suppress the vibration of an actuator can be implemented, although it is lightweight.

It is a perspective view which shows the supercharger of this invention. It is a side view which shows the supercharger of this invention. It is a fragmentary broken view which shows the supercharger of this invention. It is a figure for demonstrating the effect | action of the supercharger of this invention. It is a figure for demonstrating the characteristic regarding the member shape in the supercharger of this invention. It is a figure for demonstrating the basis of member shape selection in the supercharger of this invention.

Hereinafter, a supercharger as an embodiment of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a perspective view showing a supercharger according to the present invention, and FIG. 2 is a side view showing the supercharger according to the present invention.
1 and 2, the supercharger 1 according to the present embodiment is configured by integrally assembling a turbine housing 10 and a compressor housing 20 via a center housing 30.
A turbine rotor (not shown) that is rotated by engine exhaust gas introduced from the exhaust inlet pipe 11 is pivotally supported in the turbine housing 10. The rotation of the turbine rotor is transmitted through a bearing shaft (not shown) in the center housing 30 and transmitted to a compressor rotor (not shown) that is supported in the compressor housing 20.

  By the rotation of the compressor rotor, the intake air introduced from the intake inlet pipe 21 of the compressor housing 20 is compressed and sent from the intake outlet pipe 24 to the intake manifold of the engine to be supercharged.

  In order to properly perform supercharging, the rotation of the turbine rotor is adjusted. This adjustment is performed by adjusting the flow rate of the exhaust gas supplied from the exhaust inlet pipe 11 to the turbine rotor. That is, a part of the exhaust gas introduced from the exhaust inlet pipe 11 is bypassed to the wastegate 12 side, and the flow rate of the bypassed gas is adjusted by adjusting the opening degree of the wastegate valve 13.

In order to adjust the opening degree of the waste gate valve 13, an actuator 40 is provided.
The actuator 40 is a driving source for adjusting the opening degree of the wastegate valve 13 in the turbine housing 10, and is provided on the compressor housing 20 side in order to avoid heat from the turbine housing 10 that becomes high temperature during operation. .
In the supercharger 1, as shown in the figure, the actuator 40 is attached to the compressor housing 20 via an attachment member 200 configured integrally with the compressor housing 20.

The attachment member 200 has a center housing side connection portion 201 connected to the compressor housing 20 at a portion where the compressor housing 20 and the turbine housing 10 are assembled via the center housing 30.
The attachment member 200 is connected to the above-mentioned portion by a center housing side connecting portion 201 which is one part of the leg portion, but the inlet housing side connecting portion 202 which is the other portion of the leg portion is connected to the inlet of the compressor housing 20. It is connected to the housing part 22 (FIG. 2).

  The inlet housing portion 22 is a portion where the compressor housing 20 is connected to the intake passage on the upstream side, and is formed thick to ensure the connection strength.

  As can be easily understood from the drawings, the mounting member 200 includes a center housing side connecting portion 201 that is one portion of a leg portion that extends in a bifurcated manner and an inlet housing side connecting portion 202 that is the other portion. The compressor housing 20 is disposed so as to straddle the scroll portion 23.

  In other words, the attachment member 200 has a connecting end of the center housing side connecting portion 201 and a connecting end of the inlet housing side connecting portion 202 beyond the scroll portion 23, and a connecting portion with each corresponding connecting portion on the center housing side and inlet housing portion. Each connected.

  The scroll portion 23 is a portion where the intake air flowing into the compressor housing 20 is pressurized, forms the outer shell of the compressor housing 20, and is a relatively thin portion (for example, about 4 mm thick).

  The attachment member 200 is connected to the thick and strong portion by the center housing side connection portion 201 and the inlet housing side connection portion 202, while the scroll portion 23 does not seem to be mainly involved in supporting the actuator 40. It is arranged.

  In the mounting member 200 as described above, a flange-like actuator holding portion 203 is formed at a portion extending to the opposite side of the center housing side connecting portion 201 and the inlet housing side connecting portion 202. The actuator 40 is attached to the actuator holding portion 203 by bolting.

  In this supercharger 1, the actuator 40 is an electric actuator, and a control rod 41 protrudes forward and backward on the tip side of the cylindrical body. The control rod 41 is configured such that a ball screw is displaced in the axial direction by a motor in the actuator 40, and this ball screw advances and retracts the control rod 41.

  The control rod 41 of the actuator 40 is connected to one end side of the relay rod 43 through a joint 42. The other end side of the relay rod 43 is connected to one end side of the rotating arm 15 that adjusts the opening degree of the wastegate valve 13 in the turbine housing 10.

  FIG. 3 is a partially cutaway view showing the supercharger 1 of the present invention, and in particular, the feature of the shape of the mounting member 200 is clear. In FIG. 3, the same parts as those in FIGS. 1 and 2 described above are denoted by the same reference numerals, and description thereof will be omitted.

  As described above, the attachment member 200 extends from the flange-shaped actuator holding portion 203 so that the center housing side connection portion 201 and the inlet housing side connection portion 202 are divided into two portions.

As is clearer with reference to FIG. 3, in the attachment member 200, a portion where the actuator holding portion 203 and the center housing side connection portion 201 are coupled forms a coupling portion 204. The outer edge of the coupling portion 204 extends from the actuator holding portion 203 toward the outside of the center housing side connection portion 201 in a side view, and the extending direction is a shape in a side view of the mounting member 200. Therefore, there is a correlation with the rigidity of the mounting member 200.
As a result, in the mounting member 200, the actuator holding portion 203 is supported by a portion having a wider width and higher rigidity than the conventional one. This point will be described in detail later with reference to FIG.
As a result of various studies on the above-described tilt angle, the inventors have found an optimum angle. This will be described in detail later with reference to the drawings.

FIG. 4 is a diagram for explaining the operation of the supercharger 1 described with reference to FIGS. 1 to 3 in comparison with the prior art.
FIG. 4A is a diagram showing the frequency characteristics of acceleration acting on the actuator when the actuator of the supercharger is attached to the compressor housing as in the prior art. That is, the characteristic of FIG. 4 (A) is that the mounting member for mounting the actuator is not connected to the center housing and the inlet housing portion as in the above-described present invention. When connected to a housing. In this case, as described with reference to FIG. 3, the attachment member is not formed to be wider at the portion connected to the flange-like actuator holding portion, but has a relatively narrow shape.

  FIG. 4B is a diagram showing the frequency characteristics of acceleration acting on the actuator when the actuator according to the present invention described above is attached. That is, the characteristic of FIG. 4B is that the center housing side connecting portion 201 and the inlet housing side connecting portion 202 which are the legs of the mounting member are divided into the center housing 30 and the inlet housing portion 22 which are remarkably high in rigidity. When connected. Furthermore, in this case, as described with reference to FIG. 3, the mounting member 200 has a shape in which the actuator holding portion 203 is supported by a portion having a wider width and higher rigidity than the conventional one.

4A and 4B, the vertical axis represents the acceleration [G] acting on the actuator, and the horizontal axis represents the vibration frequency [Hz] applied to the actuator.
As is clear from FIG. 4 (A) and FIG. 4 (B), when the load is low, that is, when the rotation of the engine to which the turbocharger is attached is low, and when the engine is fully opened, In any case where the rotation of the engine is the maximum rotation, the acceleration acting on the actuator is effectively suppressed in the region where the vibration frequency is 900 [Hz] to 2000 [Hz].

FIG. 5 is a view for explaining the characteristics of the mounting member in the supercharger according to the present invention in comparison with the prior art. That is, it is a figure for demonstrating selection of the shape of the attachment member of the actuator of a supercharger.
FIG. 5A is a diagram showing the shape of an actuator mounting member in a conventional supercharger. In FIG. 5A, a leg portion extends downward from the flange-like actuator holding portion 203a of the mounting member 200a in the drawing. The leg portion includes a first leg portion 201a on the center housing side extending so as to straddle the compressor housing 20a and a second leg portion 202a on the inlet housing side.

In the conventional example of FIG. 5A, the connection from the actuator holding portion 203a to the first leg portion 201a to the coupling portion 204a extending at an inclination angle θ1 is relatively gentle. Here, the inclination angle θ1 is an angle formed between the extending direction of the outer edge of the coupling portion 204a and the direction perpendicular to the flange surface that couples the actuator of the flange-shaped actuator holding portion 203a (in a side view from the direction along the flange surface). Angle in the case of this example, which is approximately 60 degrees.
As a result, the mounting member 200a has a relatively gentle extension from the actuator holding portion 203a to the leg portion, and the overall width is narrowed. Therefore, the rigidity of the mounting member 200a is smaller than that of the present invention described below. Inferior.

  FIG. 5 (B) is a diagram showing the shape of an actuator mounting member 200 in the supercharger of the present invention. In FIG. 5B, the leg portion extends downward from the flange-shaped actuator holding portion 203 of the mounting member 200 in the drawing. As described above, the leg portion includes the center housing side connection portion 201 and the inlet housing side connection portion 202 that extend so as to straddle the compressor housing 20.

In the attachment member 200 in FIG. 5B, the connection from the actuator holding portion 203 to the center housing side connecting portion 201 to the coupling portion 204 extending at an inclination angle θ2 is relatively steep. Here, the inclination angle θ2 is an angle between the extending direction of the outer edge and the direction perpendicular to the flange surface to which the actuator of the flange-shaped actuator holding portion 203 is coupled (as viewed in a side view from the direction along the flange surface). Angle), which is approximately 45 degrees in this example.
In other words, focusing on the shape of the mounting member 200, the mounting member 200 has a coupling portion 204 that couples the flange-shaped actuator holding portion 203 for holding the actuator 40 and the center housing side connection portion 201. Then, it is summarized that the angle formed by the extending direction of the outer edge of the coupling portion 204 and the direction perpendicular to the flange surface to which the actuator of the flange-shaped actuator holding portion 203 is coupled is approximately 45 degrees.
As a result, the mounting member 200 has a relatively steep spread from the actuator holding portion 203 to the leg portion, and the width is widened as a whole. Therefore, the rigidity thereof is higher than that of the conventional example of FIG. And it will be expensive.

By the way, although the rigidity increases if the attachment member 200 is wide as a whole, the disadvantage that the weight of the member increases as the width becomes wider cannot be ignored.
That is, as the inclination angle θ2 (hereinafter, generally referred to as angle θ) of the coupling portion 204 extending from the actuator holding portion 203 of the mounting member 200 to the center housing side connection portion 201 in FIG. The connection from the holding portion 203 to the coupling portion 204 is relatively steep and wide, but the weight as a member increases as this is done.

  On the other hand, when the inclination angle θ is increased in order to reduce the weight and the connection from the actuator holding portion 203 to the coupling portion 204 becomes relatively gentle, the width is reduced and the rigidity is lowered. For this reason, the inventors have deepened various studies and have come to find the optimum shape of the mounting member 200.

FIG. 6 is a diagram for explaining the grounds for selecting a member shape in the supercharger of the present invention.
In FIG. 6, the vertical axis represents the deformation rate (relative value with respect to the reference value) at the deformation amount evaluation position when a certain stress is applied to the mounting member 200, and the horizontal axis represents the weight increase amount, both in the direction of the arrow To increase. The angle θ described above is used as a parameter. Here, the deformation amount evaluation position is a top portion of the actuator holding portion 203 of the mounting member 200, and is a portion indicated by a symbol M in the drawing.

As shown in the figure, when the angle θ is 60 degrees to 45 degrees, the deformation rate decrease (that is, the rigidity increase) is relatively remarkable as compared with the increase in the weight increase amount.
On the other hand, in the region where the angle θ is less than 45 degrees, the deformation rate decrease (that is, the increase in rigidity) is relatively small as compared with the increase in the weight increase amount, and tends to reach saturation. This means that when the angle θ is less than 45 degrees, the increase in rigidity cannot be expected so much, and disadvantages such as an increase in weight become superior.

  Therefore, in one embodiment of the present invention, the coupling portion extending from the flange-shaped actuator holding portion 203 toward the center housing side connecting portion 201 forms an inclination angle, and this inclination angle is determined by the flange-shaped actuator. The mounting member 200 is formed so that the angle θ is approximately 45 degrees with respect to the direction of the normal line set on the virtual plane p assumed in the holding portion 203 as described above.

  As described above, in the supercharger 1 as one embodiment of the present invention described with reference to the drawings, in a normal configuration, it is much more rigid than the surrounding structural portion (for example, the scroll portion 23 of the compressor housing 20). Since the attachment member 200 (the center housing side connecting portion 201) of the actuator 40 is connected to a portion connected to the high center housing 30, the rigidity of the connecting portion is high and vibration of the actuator 40 is sufficiently suppressed. Further, since it is not necessary to make the compressor housing 20 main body particularly thick and highly rigid, there is no inconvenience such as an increase in the weight of the supercharger.

  Further, since the attachment member 200 of the actuator 40 is attached to the compressor housing 20 so as not to be connected to the scroll portion 23 to which the intake air flowing into the compressor housing 20 is pressurized, the wall thickness is generally thin. The scroll part 23 with low rigidity (for example, about 4 mm) does not participate in the support of the actuator, and does not cause a decrease in rigidity related to the attachment of the attachment member 200.

  Further, since the attachment member 200 is inevitably connected to the inlet housing portion 22 having a large thickness and rigidity due to the connection portion to the intake passage on the upstream side, the vibration of the actuator 40 is vibrated. Is sufficiently suppressed, and there is no possibility of causing resonance.

Further, in the attachment member 200 of the actuator 40, the coupling portion extending from the flange-shaped actuator holding portion 203 toward the center housing side connection portion 201 forms an inclination angle, and the inclination angle is 45 as described above. Has been chosen to be degrees.
For this reason, the vibration of the actuator 40 is sufficiently suppressed while reducing the increase in weight.

It should be noted that the present invention is not limited to the above-described embodiment, and modifications, improvements, etc. within a scope that can achieve the object of the present invention are included in the present invention.
For example, the actuator 40 described above is not necessarily limited to an electric actuator. For example, the actuator 40 is operated by introducing a pressurized air supply into a diaphragm chamber and operating it by force balance between the back pressure and the elastic force of the spring. An actuator may be applied.

DESCRIPTION OF SYMBOLS 1 ... Supercharger 10 ... Turbine housing 20 ... Compressor housing 22 ... Inlet housing part 23 ... Scroll part 30 ... Center housing 40 ... Actuator 200 ... Mounting member 201 ... Center housing side connection part 202 ... Inlet housing side connection part 203 ... Actuator Holding unit 204... Coupling unit

Claims (3)

In the turbocharger in which the turbine housing and the compressor housing are integrally assembled via the center housing,
A wastegate and a wastegate valve provided in the turbine housing;
An actuator for adjusting the opening of the wastegate valve,
The actuator is attached to the compressor housing via an attachment member,
The attachment member has a center housing side connection portion connected to the compressor housing at a portion assembled with the center housing in the compressor housing,
The compressor housing has an inlet housing portion connected to an upstream intake passage, and the attachment member further has an inlet housing side connection portion connected to the inlet housing portion. . In the turbocharger in which the turbine housing and the compressor housing are integrally assembled via the center housing,
A wastegate and a wastegate valve provided in the turbine housing;
An actuator for adjusting the opening of the wastegate valve,
The actuator is attached to the compressor housing via an attachment member,
The mounting member has a center housing side connection portion connected to the compressor housing at a portion assembled with the center housing in the compressor housing,
The mounting member includes a coupling portion that couples a flange-shaped actuator holding portion for holding the actuator and the center housing side connection portion, and an extending direction of an outer edge of the coupling portion and the flange-shaped actuator The supercharger characterized in that an angle between the holding portion and a direction orthogonal to the flange surface to which the actuator is coupled is approximately 45 degrees in a side view from the direction along the flange surface. The attachment member includes a connecting end of the center housing side connecting portion and a connecting end of the inlet housing side connecting portion beyond the scroll portion where the intake air flowing into the compressor housing is pressurized. The supercharger according to claim 1, wherein the turbocharger is connected to each other by reaching a connecting portion and a connecting portion with the inlet housing portion.

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