DE112016002607B4 - turbocharger - Google Patents

Abstract

A turbocharger (1) comprising: a rotating shaft (12) rotatably supported in a housing (2); an impeller (8) fixed to an end portion of said rotating shaft (12), a bearing (20; 20A ) press-fitted onto the rotary shaft (12) and rotatably supporting the rotary shaft (12) on the housing (2), the bearing (20; 20A) being a grease ball bearing; and a flange member (30; 30A) attached to the rotary shaft (12) and adjacent to the bearing (20; 20A) in an axial direction of the rotary shaft (12), the bearing (20; 20A) being on the rear surface side of the impeller (8) and interposed between the impeller (8) and the flange member (30; 30A), the flange member (30; 30A) having a boss portion (31) through which the rotary shaft (12) penetrates and which is adjacent to the bearing (20; 20A), and has a flange-like portion (32) connected to the boss portion (31) and extending in a radial direction of the rotary shaft (12).

Description

technical field

This disclosure relates to a turbocharger or rotating machine in which a rotating shaft is supported by a bearing.

State of the art

As such a technology, as in JP 2012-102700 A is known, an electric turbocharger is known in which a compressor wheel is attached to a rotating shaft, and a motor rotor fixed to the rotating shaft is rotated by a motor. In the electric turbocharger, a ring portion surrounding the rotating shaft and a damper and a rolling bearing provided inside the ring portion are provided. The rolling bearing is attached to an end portion of the rotating shaft. The rolling bearing is a grease-filled bearing that is filled with a grease.

Similar turbochargers are from the JP 2004-150372 A and the DE 11 2010 001 692 T5 famous.

Summary of the Invention

Technical problem

There may be cases where the bearing is attached to the rotating shaft by an interference fit. When the bearing is press-fitted to the rotating shaft, it is difficult to detach the bearing from the rotating shaft at a time of replacing the rotating shaft. For example, even if an external force is directly applied to the bearing fixed to the rotating shaft, the bearing cannot be easily detached. An object of this disclosure is to provide a lathe or rotating machine capable of easily detaching a bearing from a rotating shaft.

the solution of the problem

The object of the present invention is achieved by a turbocharger according to claim 1 and claim 5. Advantageous developments are the subject matter of the dependent claims. A turbocharger includes: a rotating shaft rotatably supported in a housing; a bearing press-fitted to the rotating shaft and rotatably supporting the rotating shaft to the housing; and a flange member attached to the rotating shaft and adjacent to the bearing on an axis in a direction of the rotating shaft in which the flange member has a boss portion through which the rotating shaft penetrates and which is adjacent to the bearing and has a flange-like portion connected to the boss portion and extending in a radial direction of the rotating shaft.

Advantageous Effects of the Invention

According to the aspect of this disclosure, the bearing can be easily detached from the rotating shaft.

character list

• 1 12 is a sectional view of a lathe according to a first embodiment of this disclosure.
• 2 Fig. 14 is an enlarged sectional view of part A in Fig 1 .
• 3(a) is a sectional view showing a flange member in 2 represents and 3(b) is a sectional view showing a flange member in 5 represents.
• 4(a) and 4(b) 12 are sectional views showing a process of detaching a bearing.
• 5 13 is an enlarged sectional view showing a bearing portion of a lathe according to a second embodiment of this disclosure, and FIG 2 is equivalent to.
• 6 14 is an enlarged sectional view showing a bearing portion of a lathe according to a comparative example.

Description of Embodiments

According to an aspect of this disclosure, a rotary machine includes: a rotating shaft rotatably supported in a housing; a bearing press-fitted to the rotating shaft and rotatably supporting the rotating shaft to the housing; and a flange member attached to the rotary shaft and adjacent to the bearing in an axis in a direction of the rotary shaft in which the flange portion includes a boss portion through which the rotary shaft penetrates and which is adjacent to the bearing, and a flange-like portion connected to the boss portion and extending in a radial direction of the rotating shaft.

In the rotary machine, the flange portion attached to the rotary shaft is adjacent to the bearing in the axial direction. The boss portion of the flange portion is adjacent to the bearing, and the flange-like portion extends in the radial direction. Therefore, by applying an external force in the axial direction to the flange-like portion, the boss portion can be pressed against the bearing, and accordingly the bearing press-fitted on the rotating shaft can be easily detached.

In some aspects, the bearing is a grease ball bearing, the cylindrical portion surrounding the bearing from an outer peripheral side is held in the housing, and the flange-like portion of the flange member is disposed inside the cylindrical portion. In this case, since the flange-like portion is arranged inside the cylindrical portion, the distance between the flange-like portion and the inner circumference of the cylindrical portion can be set to be small. Therefore, the flow of a fluid such as air that may pass through the ball bearing is effectively prevented. As a result, grease removal is prevented, and an increase in durability and an improvement in fatigue strength are achieved.

In some aspects, the rotating shaft is provided with a rotating body protruding beyond the flange-like portion in the radial direction, and an interval in the axial direction is defined between the flange-like portion and the rotating body. Rotating body provided. If the rotating body protruding outward in the radial direction is provided on the rotating shaft in a case where an external force is to be applied to the flange-like portion, the rotating body may become an obstacle. In the configuration described above, a jig or the like can be arranged in the clearance provided between the flange-like portion and the rotary body, and an external force in the axial direction is easily transmitted via the jig. the tool or the like applied to the camp. Therefore, even in a case where the rotating body protruding outward in the radial direction is provided on the rotating shaft, the bearing can be easily detached from the rotating shaft.

In some aspects, the bearing is a radial ball bearing having an inner race that is press-fitted to the rotary shaft and an outer race that is relatively rotatable relative to the inner race via a plurality of balls, the hub portion protrudes toward the bearing through the flange-like portion and abuts the inner race, and a gap is provided in the axial direction between the flange-like portion and the outer race. In this case, since the boss portion abuts the inner race of the bearing, by applying an external force in the axial direction to the flange-like portion, the inner race press-fitted onto the rotary shaft can be easily moved relative to the rotary shaft. Further, since the gap is provided between the flange-like portion and the outer race of the bearing even in a case where the flange member rotates with the rotation of the rotating shaft, the flange-like portion is prevented from interfering with the outer race.

According to another aspect of this disclosure, the lathe or rotating machine includes: a housing; a rotating shaft accommodated in the housing; a bearing that supports one side in an axial direction of the rotary shaft; and a flange member adjacent to the other side in the axial direction of the bearing, in which the flange member has a boss portion through which the rotary shaft protrudes and which is adjacent to the bearing, and a flange-like portion connected to the boss portion is connected and extends in a radial direction of the rotary shaft.

Hereinafter, an embodiment of this disclosure will be described with reference to the drawings. In the description of the drawings, the same elements are denoted by the same reference numerals, and redundant descriptions are omitted.

An electric turbocharger (rotary machine) 1 according to a first embodiment is described with reference to FIG 1 described. As in 1 1, the electric turbocharger 1 is applied to an internal combustion engine of a vehicle or a ship, for example. The electric turbocharger 1 has a compressor 7 . In the electric turbocharger 1, a compressor impeller 8 is rotated by the interaction between a rotor portion 13 and a stator portion 14 to compress a fluid such as air and generate compressed air.

The electric turbocharger 1 has a rotating shaft 12 rotatably supported in a housing 2 and the compressor impeller 8 fixed to a tip end portion (an end portion) 12a of the rotating shaft 12 . The housing 2 has a motor housing 3 in which the rotor section 13 and the stator section 14 are supported and an end wall 4 closing an opening on the other end side (the right side in the figure) of the motor case 3. As shown in FIG. A compressor housing 6 accommodating the compressor impeller 8 is provided on one end side (the left side in the figure) of the motor housing 3 . The compressor housing 6 has an inlet port 9 , a scroll section 10 and a discharge port 11 .

The compressor impeller 8 is made of, for example, a resin or carbon fiber reinforced plastic (hereinafter referred to as “CFRP”, CFRP: carbon fiber reinforced plastic), and accordingly weight reduction is achieved.

The rotor portion 13 is fixed to the central portion in an axial direction D<b>1 of the rotary shaft 12 and has one or a plurality of permanent magnets (not shown) attached to the rotary shaft 12 . The stator portion 14 is fixed to the inner surface of the motor case 3 to surround the rotor portion 13 and has a coil portion (not shown) with a lead wire 14a wound thereon. When an alternating current is supplied to the coil portion of the stator portion 14 through the lead wire 14a, the rotating shaft 12 and the compressor impeller 8 integrally rotate due to the interaction between the rotor portion 13 and the stator portion 14. When the compressor impeller 8 rotates, the compressor impeller 8 pulls outward Air takes in through the inlet port 9 , compresses the air through the scroll section 10 , and discharges the air from the discharge port 11 . The compressed air discharged from the discharge port 11 is supplied to the internal combustion engine mentioned above.

The electric turbocharger 1 has two ball bearings (bearings) 20 press-fitted to the rotating shaft 12 and rotatably supporting the rotating shaft 12 to the housing 2 . The ball bearings 20 are provided near the tip end portion 12a and a base end portion 12b of the rotary shaft 12, respectively, and support the rotary shaft 12 on both sides. The ball bearing 20 is, for example, a grease radial ball bearing. More specifically, the ball bearing 20 may be a deep groove ball bearing or an angular contact ball bearing. As in 2 As shown, the ball bearing 20 has an inner race 20a press-fitted to the rotary shaft 12 and an outer race 20b rotatable relative to the inner race 20a via a plurality of balls 20c.

A ball bearing 20 is attached to the back surface side (the right side in the figure) of the compressor impeller 8 . A cylindrical bushing (cylindrical portion) 21 is attached to the outer peripheral side of a ball bearing 20 . As in 1 1, the ball bearing 20 and the bushing 21 are fixed to the rotating shaft 12 by a shaft end nut 16 provided at the tip end portion 12a of the rotating shaft 12. As shown in FIG. The cylindrical bushing 21 is arranged on the outer peripheral side of a ball bearing 20 . The bearing sleeve 21 is press-fitted into a bearing surrounding portion 23 formed on one end side in the axial direction D<b>1 of the motor housing 3 .

The other ball bearing 20 is mounted between the rotating shaft 12 and the end wall 4 . A cylindrical bushing (cylindrical portion) 22 is attached to the outer peripheral side of the other ball bearing 20 . The bearing sleeve 22 is press-fitted to a cylindrical portion (inner peripheral surface) formed to protrude inward from the center of the end wall 4 in the motor housing 3 . An annular spring receiver 26 is provided between the other ball bearing 20 and the end wall 4 . The spring receiver 26 is biased to one side in the axial direction D<b>1 by a spring 27 disposed in the cylindrical portion at the center of the end wall 4 .

The motor housing 3 is made of aluminum, for example. On the other hand, the inner race 20a and the outer race 20b of the ball bearing 20 are made of iron. Therefore, the bushings 21 and 22 which are made of iron such as carbon steel and mild steel and have the same degree of hardness as the ball bearings 20 are provided between the ball bearings 20 and the motor housing 3 . The bushings 21 and 22 surround the ball bearings 20 from the outer peripheral side. Accordingly, the motor housing 3, which is made of a relatively soft material, is protected from abrasion.

The rotary shaft 12 and the compressor impeller 8, the rotor portion 13, the ball bearings 20 and the spring receiver 26 fixed to the rotary shaft 12 integrally form a rotary portion in the casing 2 and become one side biased in the axial direction D1. An annular portion 23a, which is a part of the bearing surrounding portion 23, faces one end side of the ball bearing 20 such that the rotating portion is positioned in the axial direction D1.

Next, the bearing structure of the electric turbocharger 1 is explained in detail with reference to FIG 2 and 3(a) described. As in 2 1, the rotor portion 13 is a rotating body rotating in the radial direction D2 from the rotary shaft 12 protrudes outwards. The outside diameter of the rotor section 13 is, for example, larger than the outside diameter of the outer running surface 20b of the ball bearing 20. The outside diameter of the rotor section 13 is, for example, larger than the inside diameter of the bearing sleeve 21 and smaller than the outside diameter of the bearing sleeve 21. The outside diameter of the rotor section 13 can be larger than the outer diameter of the bearing sleeve 21. An annular stepped portion 12c slightly larger in diameter than the rotary shaft 12 is formed at a position of the rotary shaft 12 corresponding to an end face in the axial direction D1 of the rotor portion 13. That is, the stepped portion 12c of the rotating shaft 12 is located inside an end surface in the axial direction D<b>1 of the rotor portion 13 .

In the electric turbocharger 1 of this embodiment, a spacer (flange member) 30 is interposed between the ball bearing 20 and the stepped portion 12c. The spacer 30 is fixed to the rotary shaft 12 and is adjacent to the ball bearing 20 in the axial direction D1. The spacer 30 is made of iron such as carbon steel or mild steel.

As in 3(a) As shown, the spacer 30 has a cylindrical boss portion 31 which abuts against the inner race 20a of the ball bearing 20 and a flange-like portion 32 which is connected to the boss portion 31 . A through hole 30a through which the rotating shaft 12 passes is provided in the central portion of the boss portion 31. As shown in FIG. The flange-like portion 32 has an annular shape and extends in the radial direction D2.

The boss portion 31 has an annular boss portion first end face 31a on one end side in the axial direction D1 and an annular boss portion second end face 31b on the other end side in the axial direction D1. The flange-like portion 32 has a flange-like portion first end face 32a on one end side in the axial direction D1 and an annular flange-like portion second end face 32b on the other end side in the axial direction D1. The thickness in the axial direction D1 of the boss portion 31, that is, the distance between the first end face 31a of the boss portion and the second end face 31b of the boss portion is set to be larger than the thickness of the flange-like portion 32, that is, the distance between the first end surface 32a of the flange-like portion and the second end surface 32b of the flange-like portion. In other words, the hub section 31 projects toward the ball bearing 20 beyond the flange-like section 32 . Further, the boss portion 31 protrudes toward the stepped portion 12c beyond the flange-like portion 32 . The thickness of the boss portion 31 can be determined by the length (width) in the axial direction D1 of the ball bearing 20, for example. The thickness of the flange-like portion 32 can be determined based on the strength required when the ball bearing 20, which will be described later, is detached.

As in 2 As shown, the hub portion 31 of the spacer 30 abuts against the inner race 20a of the ball bearing 20 . Since the boss portion first end surface 31a protrudes from the flange-like portion first inner surface 32a, a gap is provided between the flange-like portion first end surface 32a and the outer raceway surface 20b of the ball bearing 20 .

The outer diameter of the flange-like portion 32 is smaller than the inner diameter of the bearing sleeve 21. The bearing sleeve 21 projects beyond the ball bearing 20 to the other side in the axial direction D1. The flange-like section 32 is arranged inside the protruding section of the bearing sleeve 21 . A narrow annular gap g is provided between the inner peripheral surface of the bearing sleeve 21 and the outer peripheral surface of the flange-like portion 32 . As described above, since the spacer 30 is disposed inside the bearing sleeve 21 and the gap g is formed as a slight clearance, the passage of air into the ball bearing 20 is suppressed.

The rotor portion 13 described above protrudes outward in the radial direction D2 beyond the flange-like portion 32 . Since the flange-like portion second end face 32 b protrudes from the flange-like portion second end face 32 b , an interval S is provided between the flange-like portion second end face 32 b and the rotor portion 13 .

In the same manner, the spacer 30 is provided between the other ball bearing 20 and the rotor portion 13. As shown in FIG. The configuration of the other ball bearing 20, the bearing sleeve 22 and the spacer 30 is the same as that described above, and accordingly the description thereof is omitted.

Next, a process of extracting the ball bearing 20 from the rotating shaft 12 will be described with reference to FIG 4 described. As in 4(a) shown is a camp release tool 40 or a bearing removal tool 40 is provided. The bearing detaching tool 40 is composed of a cylindrical body 41 formed by joining two separate semi-cylindrical housings and a jig 42 provided at the upper portion of the cylindrical body 41 and by joining is formed by semi-circular plate members. The rotary shaft 12 is inserted through the upper portion of the cylindrical body 41 and the central portion of the jig 42 in a state where the ball bearing 20 and the spacer 30 are press-fitted to the rotary shaft 12 . In the present case, the edge portion of the opening provided in the central portion of the holder 42 is arranged at the interval S mentioned above. Accordingly, the jig 42 can be brought into pressure contact with the flange-like portion 32 of the spacer 30 in the axial direction D1.

When the tip end portion 12a of the rotary shaft 12 is pushed down in the state shown in FIG 4(a) 1, the rotary shaft 12 is pulled out of the ball bearing 20 via the spacer 30 (specifically, due to the pressure contact between the boss portion 31 and the inner race 20a) as shown in FIG 4(b) is shown. Accordingly, the ball bearing 20 is easily detached or removed. The other ball bearing 20 can also be detached or removed in the same procedure as described above.

In the electric turbocharger 1, the spacer 30 attached to the rotary shaft 12 is adjacent to the ball bearing 20 in the axial direction D1. The boss portion 31 of the spacer 30 is adjacent to the ball bearing 20, and the flange-like portion 32 extends in the radial direction D2. Therefore, by applying an external force in the axial direction D1 to the flange-like portion 32, the boss portion 31 is pressed against the ball bearing 20, and the ball bearing 20 press-fitted on the rotary shaft 12 can be easily detached.

In addition, since the flange-like portion 32 extends in the radial direction D2, the clearance is narrowed and the flow of air that can pass through the ball bearing 20 is prevented. As a secondary effect, the grease contained in the ball bearing 20 is prevented from being removed, and an increase in the life of the ball bearing 20 is achieved. This effect is significant in the ball bearing 20 provided on the back surface side of the compressor impeller 8 .

As in 6 1, in a configuration in which a bushing 50 not protruding beyond the ball bearing 20 is used and the spacer 30 is not provided, the flow F of air tends to occur with the rotation of the compressor impeller 8. Therefore, the grease contained in the ball bearing 20 tends to come off, which is a factor of reducing the fatigue strength of the ball bearing 20 . In the electric turbocharger 1 provided with the spacer 30, the grease contained in the ball bearing 20 is prevented from being removed.

In the electric turbocharger 1, since the flange-like portion 32 is disposed inside the bearing sleeve 21, the gap g between the flange-like portion 32 and the inner periphery of the bearing sleeve 21 is small. Therefore, the air flow that can pass through the ball bearing 20 is prevented. As a result, the grease contained in the ball bearing 20 is further prevented from being removed.

In the electric turbocharger 1, the retainer 42 can be arranged in the interval S provided between the flange-like portion 32 and the rotor portion 13, and an external force in the axial direction can be easily applied to the ball bearing 20 via the retainer 42 be raised. Therefore, even in a case where the rotor portion 13 protruding outward in the radial direction D2 is provided on the rotary shaft 12, the ball bearing 20 can be easily detached from the rotary shaft 12.

In the electric turbocharger 1, since the boss portion 31 abuts against the inner race 20a of the ball bearing 20, the inner race 20a press-fitted to the rotary shaft 12 can be rotated by applying an external force in the axial direction D1 to the flange-like portion 32 be easily moved relative to the rotating shaft. Further, since the gap is provided between the flange-like portion 32 and the outer race 20b of the ball bearing 20 even in a case where the spacer 30 rotates with the rotation of the rotary shaft 12, the flange-like portion 12 is prevented from the outer race 20b to affect.

The electric turbocharger 1 of a second embodiment is described with reference to FIG 5 and 3(b) described. In the electric turbocharger 1, a spacer 30A is used, des whose other end surface is flat in the axial direction D1. This is because in a case where a ball bearing 20A (for example, an angular contact bearing) of a different type from the ball bearing 20 is used, the ball bearing 20A has different dimensions from the ball bearing 20, and the shape of the spacer is changed accordingly. A boss portion 31A and a flange-like portion 32A of the spacer 30 are thinner in the axial direction D1 than the boss portion 31 and the flange-like portion 32 of the spacer 30. From the viewpoint of ensuring strength, the material of the spacer 30A may differ from the material of the spacer 30 be changed from. Furthermore, the spacer 30A may be made of chromium-molybdenum steel. In the thin spacer 30A, the second end surface 32b of the flange-like portion and the second end surface 32b of the flange-like portion are flush with each other and form a flat surface. Even in this case, an interval S is provided between the boss portion 31A and the rotor portion 13 similar to the foregoing.

Even with the structure using the spacer 30A, the same operations and effects as those of the first embodiment described above can be exhibited.

While the embodiments of this disclosure have been described above, the present invention is not limited to the embodiments. For example, the arrangement relationship between the bearing sleeve 21 and the spacer 30 is not limited to the above-described aspect. The spacer 30 does not have to be arranged inside the bearing sleeve 21 and can be arranged outside of the bearing sleeve 21 . The flange-like portion 32 may be arranged adjacent to the bearing sleeve 21 in the axial direction D1.

The bearing sleeve 21 need not be provided, and the housing may have a portion having the same shape as the bearing sleeve. That is, as long as the difference in a material between the housing and the bearing is resolved, the housing and the bearing (the outer race of the bearing) can be brought into contact with each other without interposing a bushing therebetween.

The bearing is not limited to the grease ball bearing. For example, a ball bearing employing another type of lubrication (oil lubrication or the like) can also be used. The bearing is not limited to the radial bearing and may also be a thrust bearing.

The structure of the present invention can be applied to any rotary machine in which a bearing is press-fitted onto a rotating shaft. For example, the present invention can be applied to a type of electric turbocharger in which rotation is assisted by a motor provided with a turbine, or can be applied to a general turbocharger other than the electric turbocharger. Further, the present invention is not limited to a rotary machine provided with a compressor, and can also be applied to a generator that generates electric power using a turbine.

Commercial Applicability

According to some aspects of this disclosure, a bearing can be easily removed from a rotating shaft.

Reference List

1

electric turbocharger (lathe or rotating machine)

2

housing

7

compressor

8th

Compressor impeller (impeller)

12

rotating shaft or rotating shaft

13

rotor section (rotating body or rotating body)

14

stator section

20

ball bearing (bearing)

20A

ball bearing (bearing)

20a

inner tread

20b

outer tread

20c

bullet

21

bearing sleeve (cylindrical section)

22

bearing sleeve (cylindrical section)

23

camp surrounding section

23a

annular section

30

spacer (flange component)

30A

spacer (flange component)

31

hub section

31A

hub section

32

flange-like section

32A

flange-like section

D1

axial direction

D2

radial direction

S

interval or distance

Claims (5)

Turbocharger (1) comprising: a rotating shaft (12) rotatably supported in a housing (2); an impeller (8) fixed to an end portion of the rotating shaft (12), a bearing (20; 20A) press-fitted onto the rotary shaft (12) and rotatably supporting the rotary shaft (12) on the housing (2), the bearing (20; 20A) being a grease ball bearing; and a flange member (30; 30A) attached to the rotary shaft (12) and adjacent to the bearing (20; 20A) in an axial direction of the rotary shaft (12), wherein the bearing (20; 20A) is attached to the rear surface side of the impeller (8) and is interposed between the impeller (8) and the flange member (30; 30A), said flange member (30; 30A) having a boss portion (31) through which said rotary shaft (12) penetrates and which is adjacent to said bearing (20; 20A), and a flange-like portion (32) integral with said boss portion ( 31) and extending in a radial direction of the rotating shaft (12). Turbocharger (1) after claim 1 wherein a cylindrical bearing sleeve (21) is attached to the outer peripheral side of the bearing (20; 20A), and the flange-like portion (32) of the flange member is arranged inside the cylindrical bearing sleeve (21). Turbocharger (1) after claim 1 or 2 wherein the rotary shaft (12) is provided with a rotary body (13) protruding outward beyond the flange-like portion (32) in the radial direction, and a clearance in the axial direction between the flange-like portion (32) and the rotary body ( 13) is provided. Turbocharger (1) according to one of Claims 1 until 3 , wherein the bearing (20; 20A) is a radial ball bearing having an inner race (20a) fitted on the rotary shaft (12) and an outer race (20b) which is relatively to the inner race (20a) over a plurality of balls (20c) is rotatable, the boss portion (31) projects beyond the flange-like portion (32) toward the bearing (20; 20A) and abuts on the inner race (20a), and a gap (g) in the axial direction is provided between the flange-like portion (32) and the outer race (20b). Turbocharger (1) comprising: a housing (2); a rotating shaft (12) housed in the housing (2); an impeller (8) fixed to one end of the rotating shaft (12), a bearing (20; 20A) supporting an axial side of said rotary shaft (12), said bearing (20; 20A) being a grease ball bearing; and a flange member (30; 30A) which is adjacent to the side in the axial direction of the bearing (20; 20A), wherein the bearing (20; 20A) is attached to the rear surface side of the impeller (8) and is interposed between the impeller (8) and the flange member (30; 30A), said flange member (30; 30A) having a boss portion (31) through which said rotary shaft (12) penetrates and which is adjacent to said bearing (20; 20A), and a flange-like portion (32) integral with said boss portion ( 31) and extending in a radial direction of the rotary shaft (12).

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