KR101187582B1 - Auger device equiped with excavating rod and casing rod having same turning direction and different speed - Google Patents

Abstract

The present invention relates to an auger excavation device configured to rotate the excavating rod and the casing rod in the same rotational direction and different rotational speeds, including a motor, a planetary gear reducer for reducing the rotational power of the motor, and the planetary gear. A gear box formed at the lower portion of the reducer, a first drive gear that is fixed to the reduction output shaft of the planetary gear reducer projecting into the gear box, and a larger than the first drive gear to reduce the rotational speed of the first drive gear. A first interlocking gear formed to have a diameter and fitted to the first driving gear, and installed in a state of being fitted in the center of the first interlocking gear, and rotating in a reduced speed than the first driving gear; An auger excavation apparatus having an excavation rod shaft that is rotatably installed, wherein the auger is in contact with an extension shaft of the reduction output shaft. A second drive gear rotatably installed in the gearbox and having a larger diameter than the first drive gear; The drilling rod shaft is rotatably penetrated into the center hole formed with an inner diameter larger than the outer diameter of the drilling rod shaft, and the second interlocking gear portion formed to engage the second driving gear is inserted into the gear box. The rod connecting portion to which the casing rod is connected is a casing rod shaft which is rotatably supported by the gear box so as to protrude out of the gear box;

Description

Auger device equiped with excavating rod and casing rod having same turning direction and different speed}

The present invention relates to an auger excavation device configured to rotate the excavating rod and the casing rod in the same rotational direction and different rotational speed, and more specifically, the stirring blade for stirring the excavating rod and the excavated soil. Alternatively, a means for rotating the casing rod with screw blades for discharging the excavated soil at the same time but rotating the rotation speed differently, and with the auger rod for drilling the ground and the stirring blade or screw blade The casing rod equipped with the rotating rod rotates in the same direction, but the casing rod rotates faster than the excavating rod, so that the stirring blade of the casing rod can be stirred while breaking the sediment mass excavated by the auger head of the drilling rod. Or to quickly discharge the soil excavated by the auger head of the excavating rod. It relates to auger drilling apparatus to allow.

In general, auger rigs are used to improve soft ground.

In the prior art, when the soft ground layer is to be improved by using an auger excavation device, the excavation rod is simultaneously excavated with an auger head mounted at the bottom of the excavation rod mounted in a multi-phase connection to the auger drive unit of the auger excavation device. There are a plurality of stirring blades attached at regular intervals to protrude in all directions on the outer periphery of the excavating rod while discharging chemicals such as cement paste or fasteners supplied through the high pressure air and the like to the excavated soil layer through the bottom of the auger head. The soft ground is improved by a method of mixing and stirring the excavated soil and the cement paste, chemicals and the like to distribute the cement paste and the chemical evenly in the soil layer excavated and stirred by the excavation rod.

However, the prior art as described above is because the excavation rod connected to the multi-stage and the auger head mounted on the lower end thereof rotates at the same rotational speed in the same direction, so that the soil piles excavated by the auger head cannot be broken. It is pointed out as a problem that the soft ground cannot be improved by the strength as designed.

For example, in the case of soft ground such as mud, the soil layer excavated by the screw excavation wing of the auger head mounted on the bottom of the excavating rod is like a lump of soil that is changed by moisturizing when plowing the field with a plow. Soil lumps excavated in the form of agglomeration are rotated at the same rotational speed as the screw excavation blade of the auger head, and a plurality of stirring wings protruding on the outer circumference of the excavating rod are also augered. Since the plurality of stirring blades only rotate the soil excavation excavated by the screw excavation blade in the rotational direction because the state rotates at the same rotational speed in the same direction as the screw excavation blade of the head. You can't break at high speed.

Therefore, using the auger excavation device of the prior art, the cement paste or chemicals supplied through the excavation rod during the soft ground improvement construction is not evenly mixed and agitated with the sediment mass excavated by the screw excavation wing of the auger head. There is a big problem that the defects that cause poor construction in the soft ground improvement works.

The present invention has been proposed in order to solve the problems described in the prior art as described above, the two gear shafts are mounted on the same axis in the gearbox mounted on the lower portion of the planetary gear reducer of the auger excavator, the two It is a means for rotating two rotating shafts in the same direction and at different rotational speeds, and it is possible to stir while breaking the soil mass excavated by the screw drilling blades of the auger head during the soft ground improvement work. Chemicals such as water, pneumatic, cement paste, and fastener supplied through the supply passage formed at the center are mixed and agitated evenly on the soil layer excavated by the screw excavation blade of the auger head. It is aimed at improving the quality of the steel, and also piles and steel beams on the ground. In order to drill the excavation hole in the ground to insert the same structure, it is possible to discharge the excavated soil from the auger head to the ground quickly so that the construction work of inserting structures such as piles and steel beams on the ground can be carried out more efficiently. It was invented for the purpose.

The present invention as a means for achieving the above object,

A first drive gear condensed to the motor, a planetary gear reducer for reducing the rotational power of the motor, a gearbox formed under the planetary gear reducer, and a reduction output shaft of the planetary gear reducer projecting into the gearbox; And a first interlocking gear formed to have a larger diameter than the first driving gear and fitted to the first driving gear so as to reduce the rotational speed of the first driving gear, and fitted into the center of the first interlocking gear. In the auger excavation apparatus having an excavating rod shaft which is installed in the gearbox so as to rotate at a reduced rotational speed than the first drive gear,

A second drive gear rotatably installed in the gear box in a state in which it is in contact with the extension shaft of the deceleration output shaft, the second drive gear having a larger diameter than the first drive gear;

The drilling rod shaft is rotatably penetrated into the center hole formed with an inner diameter larger than the outer diameter of the drilling rod shaft, and the second interlocking gear portion formed to engage the second driving gear is inserted into the gear box. The rod connecting portion to which the casing rod is connected is provided with a casing rod shaft rotatably supported by the gear box to protrude out of the gear box;

Characterized in that further comprises a.

In addition, the drilling rod shaft is rotatably supported by a first support bearing mounted on the upper side of the gearbox and a second support bearing mounted on the upper end of the casing rod shaft to hold the intermediate portion of the drilling rod shaft. The casing rod shaft is rotatably supported by a third support bearing mounted on the lower side of the gearbox and a fourth support bearing for holding an intermediate portion of the drilling rod shaft.

In addition, the second interlocking gear portion of the casing rod shaft is formed to have a smaller diameter than the second drive gear is characterized in that the casing rod shaft is configured to rotate at an increased rotation speed compared to the rotation speed of the second drive gear.

In addition, the casing rod connected to the rod connecting portion of the casing rod shaft in one or more stages is wrapped in the excavation rod outer circumference while being spaced apart from the outer diameter of the excavating rod that is connected to the water joint of the drilling rod shaft in one or more stages. Is installed in a state, the outer periphery of the casing rod screw blades for discharging a plurality of stirring blades or excavated soil to the ground to break the excavated soil by the screw drilling wings of the auger head mounted on the bottom of the drilling rod It is characterized by selectively forming any one of.

Further, a spiral shape is formed in the lower end of the casing rod in a direction opposite to the screw blades formed on the outer periphery of the casing rod to prevent soil from penetrating into the gap formed between the outer diameter of the excavating rod and the inner diameter of the casing rod. It is characterized in that the spiral wing for soil penetration penetrating.

According to the present invention, during the soft ground improvement construction, a plurality of agitating blades protruding on the outer circumference of the casing rod rotate faster than the excavating rod, and excrete soil masses excavated in agglomerate form from the soil excavated by the screw excavation blade of the auger head. As it is crushed and crushed, it is possible to evenly mix and stir the pneumatic and chemicals in the excavated soil layer, including cement paste, which is discharged from the bottom of the auger head, and injected into the excavated soil layer. In addition, during the insertion of structures to embed piles or steel beams into the ground, the screw blades formed on the outer periphery of the casing rod rotate faster than the excavation rod, increasing the soil excavated from the auger head quickly. Moved and discharged to the ground, so insert the old treasure It provides an effect to shorten the air.

1 is an assembled state cross-sectional view of the auger excavation apparatus for explaining the present invention,
Figure 2 is a cross-sectional view of the use state of the excavation rod and the casing rod of the embodiment connected to the auger excavation device of the present invention,
3 is a cross-sectional view taken along the line AA of FIG.
Figure 4 is an assembled cross-sectional view of the excavation rod and the casing rod of another embodiment connected to the auger excavation device of the present invention.

Excavation rod and casing rod according to the present invention will be described in detail with reference to the accompanying drawings a specific embodiment of the auger excavation apparatus for the same rotational direction and rotational operation differently.

Reference numeral 1 denotes an auger excavation device, and the auger excavation device 1 includes a motor 2a and a planetary gear reducer 2b integrally formed thereon, and a gearbox at the lower end of the planetary gear reducer 2b. 3) is mounted.

On one side of the gear box 3, a first drive gear 4a extends from the deceleration output shaft 21 to the deceleration output shaft 21 of the planetary gear reducer 2b protruding therein. The second drive gear 4b is provided in each, and the first drive gear 4a is formed with a diameter smaller than that of the second drive gear 4b.

On the other side of the gear box 3, the drilling rod shaft 5 and the casing rod shaft 6 are rotatably installed, and the drilling rod shaft 5 has an upper end at the top of the gear box 3. The casing rod shaft whose lower end is rotatably supported by the third support bearing 33 mounted at the lower end of the gearbox 3 while being rotatably supported by the mounted first support bearing 31 ( It is installed to protrude to the lower end of the gear box 3 through the center hole 61 formed in the center of 6) is configured to connect the excavating rod (5) at the lower side of the gear box (3).

In addition, the drilling rod shaft 5 is a state in which the intermediate portion is rotatably held by the second support bearing 32 mounted on the upper end of the casing rod shaft 5 inserted into the gearbox 3. The first interlocking gear 51 is condensed on the upper end of the excavating rod shaft 5 between the first supporting bearing 31 and the second supporting bearing 32, and the first interlocking gear ( 51 is engaged with the first drive gear 4a. The first interlocking gear 51 is formed to have a diameter larger than that of the first drive gear 4a and is transmitted from the first drive gear 4a. It is responsible for the function of the reduction gear which decelerates and rotates the drilling rod shaft 5 by decelerating the output. Thus, the drilling rod shaft 5 is rotated slower than the rotational speed of the casing rod shaft (6).

The casing rod shaft 6 is divided into a second interlocking gear portion 62 inserted into the gear box 3 and a rod connecting portion 63 protruding downward of the gear box 3. The casing rod shaft 6 is rotatably supported by the third support bearing 33 mounted inside the lower end of the gearbox 3 in a state of being caught by the lower end of the second interlocking gear part 62.

The second interlocking gear portion 62 of the casing rod shaft 6 is engaged with the second drive gear 4b which is affixed to the extension shaft 22 of the planetary gear reducer 2b. The interlocking gear portion 62 is formed with a smaller diameter than the second drive gear 4b. Accordingly, the second interlocking gear part 62 is responsible for the function of the speed increasing gear which rotates the casing rod shaft 6 by increasing the rotational output transmitted from the second driver 4b. Thus, the casing rod shaft 6 is rotated faster than the rotation speed of the excavating rod shaft (5).

Meanwhile, as described above, the first to third support bearings 31, 32, and 33 supporting the excavation rod shaft 5 and the casing rod shaft 6 rotatably installed in the gear box 3 are heavy. It is composed of a needle bearing that is used to support a lot of load, the drilling rod shaft (5) of being inserted into the center hole 61 to pass through the center hole 61 of the casing rod shaft (6) The lower end is rotatably supported by the fourth support bearing 34 attached to the lower end side of the central hole 61.

 As described above, the drilling rod shaft 5 rotatably installed in the gear box 3 is connected to the drilling rod 7 in one or more stages, and further comprises a casing rod shaft surrounding the drilling rod shaft 5 ( In 6), the casing rod 8 is assembled in one or more stages.

First, the drilling rod 7 connected to the drilling rod shaft 5 will be described.

At the bottom of the drilling rod shaft 5, a water joint 52 having a hexagonal outer surface is formed, and at the top of the drilling rod 7 connected to the drilling rod shaft 5, the water joint 52 is formed. A female joint 71 having a hexagonal inner surface is formed so as to be detachably coupled thereto), and a male joint 72 that can be inserted into the female joint 71 at the upper end of the excavating rod 7 is formed at the lower end of the drilling rod 7. Formed.

In addition, the water joint 72 formed at the bottom of the drilling rod (7) of the auger head (9) is connected to the lower end of the bottom of the drilling rod of the drilling rods assembled to the drilling rod shaft (5) more than one stage Connected to the top.

The upper end of the auger head (9) is formed with a female joint is inserted into the male joint 72 formed at the bottom of the excavating rod (7).

In addition, the auger head 9 is formed with a plurality of drilling bits 91 and screw blades 92, respectively, the drilling bit 91 is projected downward on the lower auger head (9) auger head ( Excavation operation proceeds in the state of scratching the ground during the rotation operation of 9), the screw drilling blade 92 is inclined angle of approximately 40 ~ 50 ° (preferably 45 °) on the top of the auger head (9) It is formed to proceed with the excavation operation in the state of sweeping the ground during the rotation operation of the auger head (9).

Next, the casing rod 8 connected to the casing rod shaft 6 will be described.

The upper flange 81 is detachably connected to the connecting flange 64 provided at the lower end of the rod connecting portion 63 of the casing rod shaft 6 by a bolt or the like at the upper end of the casing rod 8. In addition, a lower flange (not shown) is provided at the lower end of the casing rod 8 to connect to the upper flange 81, but a casing rod connected to the lowermost side of the casing rods 8 is assembled. The lower flange is not provided only at the lower end of (8).

In addition, the casing rod (8) is formed slightly larger than the outer diameter of the excavating rod (7) when the excavation rod (7) when installed in a state surrounding the excavating rod (7) connected to the drilling rod shaft (5) The gap S is formed between (). Therefore, the excavation rod 7 and the casing rod 8 can be rotated individually without contacting each other.

The casing rod 8 is an embodiment in which a plurality of stirring blades 82 are formed as shown in FIG. 2 and applied to soft ground improvement work, and the screw blades 83 are formed in a spiral shape as shown in FIG. 4. There is an embodiment that is applied at the time of the structure insertion construction for inserting piles and the like on the ground.

In addition, a swivel 5a is installed at the upper end of the excavating rod shaft 5 for supplying chemicals such as water, pneumatic or quickener, including cement supplied from the outside.

In the center of the swivel (5a) is formed an injection passage 53 for supplying cement paste (or water, pneumatics, chemicals, etc.), the injection of the swivel (5a) in the center of the excavating rod shaft (5) A connection passage 54 is formed to be connected to the passage 53, and the above connection is also performed to each of the excavation rods 7 which are assembled to the water joint 51 at the lower end of the excavation rod shaft 5 by one or more stages. A supply passage 74 is formed which is connected to the passage 54.

In addition, the auger head 9 connected to the lower arm joint 72 of the excavating rod 7 is provided with a discharge passage 73 connected to the supply passage 74 of the excavating rod 7, the auger The bottom of the head 9 is formed with a discharge hole 94 for discharging the cement pool (or water, pneumatic, chemical, etc.) discharged from the discharge passage 73 toward the excavated soil layer.

On the other hand, one or more stages in the lower end and the casing rod shaft (6) of the excavating rod (7) connected to the lowermost side of the excavating rod (7) that is connected to the excavating rod shaft (5) one or more stages as described above Between the lower end of the casing rod (8) connected to the lowermost side of the casing rod (8) to be assembled to the sedimentary penetration blocking spiral blades 73 to block the soil from penetrating into the gap (S) is formed It is.

The earth-and-penetration blocking spiral blade 73 is welded to the lower end of the excavating rod (7) so as to be adjacent to the inner surface of the casing rod (8) so that a minute gap is formed on the inner surface of the casing rod (8). In addition, the above-mentioned earth-and-soil penetration block spiral 73 is formed in a spiral direction that can push the earth and sand during the rotary operation of the excavating rod (7) between the excavating rod 6 and the casing rod (8) It has a function to prevent the gravel and the like of the size to fit in the gap (S) formed in the penetration into the casing rod (8).

The operation of the auger excavation device 1 configured as described above will be described.

The auger excavation device (1) is the rotational output of the motor (2a) is decelerated primarily through the planetary gear reducer (2b), the output of the planetary gear reducer (2b) is a deceleration protruding into the gear box (3) It is output through the output shaft 21.

The decelerated output of the deceleration output shaft 21 is transmitted to the excavation rod shaft 5 and the first interlocking gear 51 meshed with the first drive gear 4a and meshed with the second drive gear 4b. Since the first drive gear 4a and the second drive gear 4b are rotated with different rotational outputs in the same direction because they are transmitted to the casing rod shaft 6 through the second interlocking gear part 62, This is because the first interlocking gear 51 having a larger diameter is meshed with the first drive gear 4a, so that the first interlocking gear 51 has a lowered rotation speed than the first drive gear 4a. The excavation rod shaft 5 is rotated with a strong rotational output while rotating, and the second drive shaft 4b is engaged with the second interlocking gear portion 62 having a smaller diameter. The part 62 is rotated at a rotational speed which is further increased than the second drive gear 4b.

Therefore, the excavating rod shaft 5 installed in the first interlocking gear 51 rotates slowly with a strong output, so that the ground is a rigid rigid layer, as well as a layer of water and stone, a layer formed of a ladle layer. It is very easy to, and the casing rod shaft (6) in which the second interlocking gear portion (62) is formed is rotated faster than the excavating rod shaft (5), so that the excavated lump excavated by the auger head (9) It is to break up or excavate the excavation of the excavated soil layer will be able to proceed quickly.

The rotational ratio of the drilling rod shaft 5 and the casing rod shaft 6 is configured to rotate at a ratio of approximately 1: 2. For example, assuming that the drilling rod shaft 5 is configured to rotate slowly at 10 rpm, the casing rod shaft 8 is configured to rotate quickly at 20 rpm.

When the auger excavation device 1 configured to rotate at different rotational outputs while the excavating rod 5 and the casing rod 6 rotate in the same direction as described above is illustrated in FIG. 2. As an example, a casing rod 8 in which a plurality of stirring blades 82 are formed on the outer circumference is used.

In the above embodiment, the excavation rod 7 inserted into the casing rod 8 is rotated slowly with a strong output, so that the excavation operation of the hard strata or the compacted sand layer and the rocky strata is easily performed. The plurality of stirring blades 82 protruding on the outer circumference of the casing rod 8 is connected to the lower end of the drilling rod 7 and rotates faster than the auger head 9 to excavate the ground, and the screw drilling blade of the auger head. Repeating the action of hitting the sediment mass excavated in the lump state by the 92, the soil excavation excavated by the auger head (9) is finely broken, and thus the bottom of the auger head (9) Soft paper by allowing the cement paste (or water, pneumatic, chemicals, etc.) discharged through the discharge hole 94 formed in the agitator to be uniformly mixed with the soil layer excavated by the auger head 9 It will be able to proceed with the improved construction effectively.

In addition, the sedimentary penetration blocking spiral blades 73 formed at the lower end of the drilling rod 7 connected to the lowermost side of the drilling rods 7 connected to the drilling rod shaft 5 in one or more stages are casing rods ( Since the soil is pushed downward in the state adjacent to the inner surface of the opened lower end of 8), the soil is blocked to the inside of the lower end of the casing rod (8), wherein the spiral penetrating blocking blade (73) and Even though soil of very small particles penetrates through the minute gap formed between the inner surfaces of the casing rod 8, the soil of the small particles is formed in the gap S between the outer surface of the excavating rod 7 and the inner surface of the casing rod 8. Excavation rod (7) and the casing rod (8) is smoothly rotated at different rotational output because it is not pinched.

In addition, the above embodiments are applicable to the construction of soft ground improvement construction, as well as other underground continuous wall construction or underground water barrier and various contaminant leachate barrier construction construction, and also the above embodiment As shown in FIG. 3, the excavation rod 5 and the casing rod 6 may be connected and assembled in three axes or one or more auger excavators 1 may be used to excavate and stir the ground. It is possible to construct soft ground improvement work and underground continuous wall construction work.

On the other hand, when inserting a structure such as a pile or steel beam into the ground with the auger excavation device (1), as shown in Figure 4 the casing rod 8 is formed with a screw blade 83 on the outer periphery Used.

In the above embodiment, the excavation rod 7 inserted into the casing rod 8 is rotated slowly with a strong output, so that the excavation work such as a hard strata and a compacted sand layer is easily performed. Since the screw blade 83 formed in a spiral shape on the outer circumference of the casing rod 8 rotates at a faster speed than the auger head 9, the screw blade 83 for rapidly rotating the soil excavated by the auger head 9 described above. As the ascending movement proceeds rapidly, the earth and sand excavated by the auger head 9 can be quickly discharged to the ground, so that the structure insertion work can be efficiently performed.

1: Auger Excavator 2a: Motor
2b: Planetary gear reducer 21: Deceleration output shaft
22: extension shaft 3: gearbox
31,32,33,34: first to fourth support bearings
4a, 4b: First and second drive gear 5: Excavation rod shaft
5a: Swivel 51: First interlocking gear
52,72: male joint 6: casing rod shaft
61: center hole 62: second interlocking gear
63: rod connection 64: connection flange
7: excavation rod 71: female joint
73: spiral wings for soil penetration penetration 74: supply passage
8: casing rod 81: upper flange
82: stirring blade 83: screw blade
9: auger head 91: drilling bit
92: screw excavation wing 93,94: discharge passage and discharge hole

Claims (5)

Of the motor 2a, a planetary gear reducer 2b for reducing the rotational power of the motor, a gear box 3 formed below the planetary gear reducer, and a planetary gear reducer protruding inward of the gearbox. A first drive gear (4a) is in contact with the deceleration output shaft 21 and the first drive gear formed in a larger diameter than the first drive gear to reduce the rotational speed of the first drive gear is installed to match the first drive gear 1 is installed in the state interlocked with the interlocking gear 51 and the center of the first interlocking gear, the excavation rotatably installed in the gear box (3) to rotate at a reduced speed than the first drive gear (4a) In the auger excavation apparatus provided with the rod shaft 5,
A second drive gear rotatably installed in the gearbox 3 in a state in which it is in contact with the extension shaft 22 of the reduction output shaft 21 and having a diameter larger than that of the first drive gear 4a; (4b); A second interlocking gear is installed to rotatably penetrate the drilling rod shaft into the central hole 61 formed to an inner diameter larger than the outer diameter of the drilling rod shaft 5, and to be engaged with the second drive gear 4b. The part 62 is inserted into the gearbox and the rod connecting portion 63 to which the casing rod 8 is connected is rotatably supported on the gearbox so as to protrude out of the gearbox 3. Casing rod shaft (6); including, but including
The casing rod shaft 6 and the drilling rod shaft 5 have the same rotational direction, and the casing rod shaft 6 is configured to rotate faster than the drilling rod shaft 5 with respect to the rotational speed.
Inside the lower end of the casing rod (8) of the casing rod (8) to prevent soil from penetrating into the gap (S) formed between the inner diameter of the excavating rod (7) and the inner diameter of the casing rod (8) The excavation rod and the casing rod are rotated in the same direction as the screw rod 83 formed on the outer circumference, and further comprising a spiral blade 73 for soil penetration penetration formed in a spiral direction in the opposite direction. Auger rig configured to operate.
The method of claim 1,
The drilling rod shaft 5 is mounted on the upper end of the first support bearing 31 and the casing rod shaft 6 mounted on the upper end side of the gear box 3 to hold the intermediate portion of the drilling rod shaft It is rotatably supported by the support bearing 32, the casing rod shaft 6 is the middle of the third support bearing 33 and the excavating rod shaft 5 mounted on the lower side of the gear box (3) The auger excavation device configured to rotatably operate the excavation rod and the casing rod in the same rotational direction and different rotational speeds, which are rotatably supported by a fourth support bearing (34) for holding the portion.
The method of claim 1,
The second interlocking gear portion 62 of the casing rod shaft 6 has a diameter smaller than that of the second drive gear 4b so that the casing rod shaft 6 rotates at a speed of the second drive gear 4b. The auger excavation device configured to rotate the excavation rod and the casing rod in the same rotational direction and different rotational speed, characterized in that configured to rotate at an increased rotational speed.
The method of claim 1,
The casing rod 8 connected to the rod connecting portion 63 of the casing rod shaft 6 in one or more stages is excavated connected in one or more stages to the water joint 52 of the drilling rod shaft 5. The outer periphery of the excavating rod (7) is installed while being spaced apart from the outer diameter of the rod (7), the outer periphery of the casing rod (8) auger head mounted on the lower end of the excavating rod (7) 9) by selectively forming any one of the plurality of stirring blades 82 for breaking the excavated soil by the screw excavation wings 92 of the screw or the screw wings 83 for discharging the excavated soil to the ground The auger excavation device configured to rotate the excavation rod and the casing rod to be the same rotational direction and different rotation speed. delete

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