KR101729232B1 - Automotive turbocharger with ratiotional inertia reduced rotor shaft - Google Patents

Abstract

The present invention relates to a turbocharger for rotary inertial reduction automobiles. The present invention relates to a turbine wheel having a center housing (100) having a mounting hole formed therein, a turbine wheel (200) rotating and discharging exhaust gas, a compressor wheel (300) rotating and sucking and compressing the outside air, And a shaft 400 connected to the compressor wheel and rotatably installed in the mounting hole, the shaft 400 having a shaft hollow portion 450 formed along an axial direction thereof. According to the present invention, the rotational moment of inertia is reduced, the rotational force of the turbocharger is increased, the oil can be moved toward the hollow portion, and the lubricating ability of the internal engine can be further improved.

Description

{AUTOMOTIVE TURBOCHARGER WITH RATIOTIONAL INERTIA REDUCED ROTOR SHAFT}

The present invention relates to a technology for reducing turbulent moment of inertia by providing a turbine wheel hollow portion and a shaft hollow portion of a turbocharger.

Description of the Related Art [0002] There is a technology related to a turbocharger with respect to an internal combustion engine mounted on an automobile or the like. The turbocharger is a device that recycles the exhaust gas that is discarded after combustion in general as a driving power. It supplies high-density compressed air in the cylinder to improve engine performance (output, torque) (downsizing).

The turbocharger comprises a turbine wheel, a turbine housing, a compressor wheel, a compressor housing and a center housing, and the turbine wheel and the compressor wheel are connected to the exhaust path Through a center housing provided at an intermediate point of the center housing, and is coaxially connected through a shaft rotatably installed in the center housing.

In the turbocharger, the exhaust gas discharged from the internal combustion engine flows into the turbine housing into which the exhaust gas flows, and the exhaust gas flows along a scroll passage in the form of a vortex. It then flows from the scroll path to the nozzle path and impinges on the turbine wheel to rotate the turbine wheel.

 When the turbine wheel rotates in this way, the torque of the turbine wheel is transmitted to the compressor wheel through the turbine shaft, and the compressor wheel rotates synchronously with the turbine wheel. At this time, the intake air near the intake air inlet is sucked into the compressor housing by the suction force generated by the rotation of the compressor wheel, and is sent to the suction air outlet through the sent-out passage and the scroll path.

 The suction air compressed in the compressor housing is forcibly supplied to the combustion chamber, and the charging efficiency of the intake air is improved. In this process, the amount of injected fuel increases according to the amount of intake air, thereby obtaining a greater combustion power and explosive power, thereby improving the engine output.

  When the turbocharger is used, when the engine is operated at a low rotation, the turbo lag is generated until there is a certain rotational force because there is no rotational force. This is called a turbo lag. Various methods for reducing the turbo rack have been attempted. One of them is to reduce the rotational moment of inertia to increase the rotational force.

Further, the viscosity of the oil increases during cold start, which causes a delay in supplying oil and a problem in that the shaft component is disassembled. The present invention is intended to solve such a problem by reducing the rotational moment of inertia and efficiently lubricating the bearings and the shaft in the center housing.

Further, conventionally, there is no separate lubrication system of the sealing member, wear of the sealing member occurs, exhaust gas on the turbine side flows into the center housing and is fixed, oil in the center housing flows out to the turbine side, and oil is deposited on the turbine side end A phenomenon has occurred. The present invention is intended to solve such a problem.

Korean Patent Publication No. 10-2005-0004279

      SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a turbocharger capable of reducing the rotational moment of inertia and improving the lubrication ability of internal organs.

The solution to the problem of the present invention is not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided a portable terminal comprising: a center housing having a mounting hole therein; A turbine wheel for rotating and exhausting the exhaust gas; A compressor wheel rotating and sucking and compressing outside air; And a shaft having one side connected to the turbine wheel and the other side connected to the compressor wheel and rotatably installed in the mounting hole and having a shaft hollow portion formed therein, The hollow portion of the wheel is formed, the hollow portion of the turbine wheel is connected to the hollow portion of the shaft, and the radius around the rotating shaft gradually decreases toward the end of the turbine wheel.

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 The center housing further includes an oil supply path through which oil can be introduced from the outside, and the shaft is provided with a first oil supply passage for supplying the oil introduced from the oil supply passage to the shaft hollow portion, A shaft oil ball can be formed.

 The bearing is mounted on the shaft, and the bearing includes an inner surface of the bearing formed with a through hole into which the shaft is inserted, and an outer surface of the bearing surrounding the inner surface of the bearing, So that the oil supply passage, the bearing oil hole, and the first shaft oil hole can communicate with each other.

 In addition, the shaft and the turbine wheel are provided with a connecting portion for connecting the shaft and the turbine wheel, a circumferential groove is formed in the connecting portion, and a sealing member may be mounted along the groove.

       The shaft may further include a second shaft oil hole communicating the groove and the shaft hollow portion to move the oil.

According to the present invention, since the hollow portion of the turbine wheel and the hollow portion of the shaft are provided to reduce the moment of inertia, the turbo rack phenomenon is improved and the efficiency in controlling the operation of the turbocharger can be improved.

In addition, since the oil can move toward the hollow portion of the shaft, the lubricating ability is improved, and the wear of the bearing and the shaft is reduced, and the durability of the turbocharger can be improved.

Further, since the oil moves to the hollow portion side of the turbine wheel to cool the turbine wheel, there is an advantage that the material selection of the turbine wheel is widened. Further, since the lubricating of the sealing member on the turbine side is enabled, the life of the sealing member can be prolonged and leakage of oil and exhaust gas can be prevented.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the following description.

1 is a cross-sectional view of a conventional turbocharger.
2, 3 and 4 are cross-sectional views of a turbocharger according to an embodiment of the present invention.
5 is a perspective view showing the structure of a bearing according to the present invention.

Hereinafter, preferred embodiments of the turbocharger according to the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to designate the same or similar components throughout the drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

1 is a cross-sectional view of a conventional turbocharger.

The conventional turbocharger includes a center housing 100 having a mounting hole formed therein, a turbine wheel 200 rotating and discharging exhaust gas, a compressor wheel 300 rotating and sucking and compressing external air, And a shaft 400 connected to the compressor wheel and rotatably installed in the mounting hole.

In the case of the conventional turbo charger, when the engine is operated at a low rotation speed, a delay occurs until a certain rotational force is generated because the rotational force of the turbo is almost zero. This is called a turbo lag. Several approaches have been attempted to reduce turbo racks.

The present invention is directed to increase the rotational force by reducing the moment of inertia of rotation as one of them, and FIGS. 2 to 5 are views showing the present invention.

2, the present invention includes a shaft 400 having a shaft hollow 450 formed therein, in addition to a center housing 100, a turbine wheel 200, and a compressor wheel 300, which are basic components of the related art. ).

The inner shaft hollow portion 450 is formed parallel to the axial direction, and the mass of the shaft is reduced to reduce the rotational moment of inertia of the turbocharger.

In addition, a wheel hollow portion 250 is formed in the interior of the turbine wheel 200 along the axial direction. The radius of the turbine wheel hollow portion 250 gradually decreases toward the end of the wheel, and the weight of the wheel is effectively reduced. At this time, when the wheel hollow portion 250 is connected to the shaft hollow portion 450, the rotational inertia moment of the turbocharger is further reduced, thereby contributing to the improvement of the turbo rack.

3, the turbocharger further includes an oil supply path 110 through which oil can be introduced from the outside into the center housing 100. The shaft 400 is connected to the oil supply path 110, A first shaft oil hole 410 may be formed on the outer circumferential surface to supply oil to the shaft hollow portion 450. Also, a plurality of first shaft oil holes 410 and oil supply passages 110 may be formed.

The oil introduced through the oil supply passage 110 is moved to the shaft hollow portion 450 and the turbine wheel hollow portion 250 through the connected first shaft oil hole 410. The transferred oil has the effect of being stored inside the shaft and the wheel, improving the lubrication ability, and reducing the wear of the shaft, thereby improving the durability. Further, the oil introduced through the first shaft oil hole 410 moves to the turbine wheel hollow portion 250, thereby cooling the turbine wheel side.

The material selection on the side of the turbine wheel 200 is limited since the side of the turbine wheel 200 is directly exposed to the high-temperature exhaust gas (1000 DEG C or more in the case of a gasoline engine). As a conventional material, nickel alloy (Ni-Alloys) is used and titanium alloy (Ti-Al) is used. However, this is disadvantageous in that it is expensive and has a complicated main composition. Accordingly, by providing a cooling system in the turbine wheel 200 itself, it is possible to apply a material that is lighter than existing materials (Ni-Alloys, Ti-Al, etc.) .

Referring to FIGS. 3 and 5, a bearing 500 is mounted on the shaft 400. The mounted bearing 500 includes a bearing inner side surface 510 having a through hole into which a shaft is inserted and a bearing outer side surface 520 surrounding the bearing inner side. The bearing inner side surface 510 and the bearing outer side surface A bearing oil hole 530 penetrating through the bearing hole 530 is formed. In addition, a plurality of bearing oil holes 530 may be formed.

The oil supply path 110 is connected to the bearing oil hole 530 and the first shaft oil hole 410 so that the oil introduced into the oil supply path 110 flows along the bearing oil hole 530, The oil moves to the oil hole 410 and the oil moves to the shaft hollow portion 450 and the turbine wheel hollow portion 450.

The bearing 500 is mounted on the shaft 400 to smooth the rotation of the shaft and the bearing oil hole 530 formed in the bearing 500 is connected to the oil supply passage 110 and the first shaft oil hole 410 So as to smooth the movement of the oil. This contributes to the cooling of the turbine wheel 200 side and the expansion of the material selection of the turbine wheel 200.

       4, a connecting portion 600 for connecting the shaft 400 and the turbine wheel 200 is formed in the shaft 400 and the turbine wheel 200, and a circumferential groove 610 is formed in the connecting portion 600. [ And the sealing member 620 is mounted along the groove 610. [ At this time, a plurality of grooves 610 are formed, and a plurality of sealing members 620 may also be mounted. Preferably, a plurality of grooves are formed, and each of the grooves 610 may be provided with a sealing member 620 one by one.

        In addition, the sealing member 620 may be mounted on the groove 610 of the connection part 600 to prevent the leakage of oil and the exhaust gas flowing into the turbine wheel from flowing into the center housing.

 A second shaft oil hole 420 is formed in the shaft 400 so that the groove 610 in which the sealing member 620 is mounted is communicated with the shaft hollow portion 450 to allow the oil to move. At this time, a plurality of second shaft oil holes 420 may be formed.

The second shaft oil hole 420 is in communication with the inside of the groove 610 and the second shaft oil hole 420 is in contact with the outside of the groove 610 when a plurality of sealing members 620 are mounted. It does not communicate.

The oil introduced into the oil supply path 110 moves to the first shaft oil hole 410 and enters the inner shaft hollow portion 450 and the turbine wheel hollow portion 250, Oil is supplied to the sealing member 620 through the groove 610 through the oil hole 420 to lubricate the sealing member. Therefore, the life of the sealing member 620 is prolonged, and the phenomenon of the inflow of the exhaust gas on the turbine side into the center housing 100 due to wear of the sealing member, the outflow of oil in the center housing 100, There is an effect of preventing the phenomenon of deposition.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

100: center housing 110: oil supply path
200: Turbine wheel 250: Turbine wheel hollow part
300: Compressor wheel 400: Shaft
410: first shaft oil ball 420: second shaft oil ball
450: shaft hollow part 500: bearing
510: Inner side of bearing 520: Outer side of bearing
530: Bearing oil ball 600: Connection
610: groove 620: sealing member

Claims (6)

A center housing (100) having a mounting hole formed therein;
A turbine wheel 200 that rotates to introduce and discharge exhaust gas;
A compressor wheel 300 for rotating and sucking and compressing outside air; And
A shaft 400 connected to the turbine wheel 200 at one side and connected to the compressor wheel 300 so as to be rotatable within the mounting hole and having a shaft hollow portion 450 formed therein; Including,
The turbine wheel hollow portion 250 is formed inside the turbine wheel 200 along the axial direction of the shaft 400,
The turbine wheel hollow portion 250
And the radius of the turbine wheel (200) is gradually decreased toward the end of the turbine wheel (200).
delete The method according to claim 1,
The center housing 100
And an oil supply path 110 through which oil can be introduced from the outside,
In the shaft 400,
And a first shaft oil hole (410) is formed on the outer circumferential surface to supply the oil introduced from the oil supply path (110) to the shaft hollow part (450). The method of claim 3,
In the shaft 400,
A bearing 500 is mounted,
The bearing (500)
A bearing inner side surface 510 formed with a through hole into which the shaft 400 is inserted and a bearing outer side surface 520 surrounding the bearing inner side surface 510,
A bearing oil hole 530 penetrating the bearing inner surface 510 and the bearing outer surface 520 is formed,
The oil supply passage 110, the bearing oil hole 530, and the first shaft oil hole 410 are communicated with each other. The method of claim 3,
The shaft (400) and the turbine wheel (200)
A connecting portion 600 connecting the shaft 400 and the turbine wheel 200 is formed and a circumferential groove 610 is formed in the connecting portion 600 and a sealing member 620 is formed along the groove Equipped turbocharger. 6. The method of claim 5,
In the shaft 400,
And a second shaft oil hole (420) capable of communicating the groove (610) with the shaft hollow portion (450) to move the oil.

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