CN212762023U - Positioning mechanism for penetrating inner fin machine and penetrating inner fin machine with positioning mechanism - Google Patents

Abstract

The utility model discloses a positioning mechanism for an inner fin penetrating machine and the inner fin penetrating machine provided with the positioning mechanism, wherein the positioning mechanism comprises a support bracket; the positioning block is provided with a positioning hole for the inner fin to pass through and a positioning groove for accommodating one end of the intercooler pipe, the positioning groove is communicated with the positioning hole, and one side of the positioning groove is provided with a first opening communicated with the outside; the first horizontal driving unit is used for driving the intercooler pipe to move along the extending direction of the positioning hole so as to enable the intercooler pipe to be inserted into the positioning groove; and a first vertical driving unit for driving the intercooler pipe to move in a vertical direction. Before the inner fins are assembled, the intercooler pipe is driven to be inserted into the positioning groove through the first horizontal driving unit, then the intercooler pipe is driven to move in the vertical direction through the first vertical driving unit, so that the intercooler pipe is clamped in the positioning groove, and the problem that the inner fins are broken or poor in assembling quality due to shaking of the intercooler pipe when the inner fins are assembled is solved.

Description

Positioning mechanism for penetrating inner fin machine and penetrating inner fin machine with positioning mechanism

Technical Field

The utility model relates to a positioning mechanism for wearing interior fin machine, concretely relates to a wearing interior fin machine that is used for wearing interior fin machine's positioning mechanism and is equipped with this positioning mechanism.

Background

The intercooler is mainly installed on the automobile provided with the supercharger and used for reducing the temperature of the supercharged high-temperature air so as to reduce the heat load of the engine and improve the air inflow, and further the power of the engine is increased. In order to improve the heat dissipation efficiency of the intercooler, inner fins are generally installed in the intercooler pipe of the intercooler.

However, because the inner fins are thin, when the inner fins are not aligned with the accommodating cavities of the intercooler pipes, the inner fins are easily damaged, so that the installation efficiency is low, the assembly quality is poor, the rejection rate is high, and the cost is high.

SUMMERY OF THE UTILITY MODEL

When assembling in order to solve general interior fin and intercooler pipe, easily lead to interior fin to roll over and decrease for the installation effectiveness is low, and assembly quality is poor, and the rejection rate is high, problem such as with high costs, according to the utility model discloses an aspect provides a positioning mechanism for wearing interior fin machine.

The positioning mechanism for the inner fin penetrating machine comprises a supporting bracket for supporting a intercooler pipe; the positioning block, the first horizontal driving unit and the first vertical driving unit are all arranged on the supporting bracket; the positioning block is provided with a positioning hole for the inner fin to pass through and a positioning groove for accommodating one end of the intercooler pipe, the positioning groove is communicated with the positioning hole, and one side of the positioning groove is provided with a first opening communicated with the outside; the first horizontal driving unit is used for driving the intercooler pipe to move along the extending direction of the positioning hole so as to be inserted into the positioning groove; the first vertical driving unit is used for driving the intercooler pipe to move along the vertical direction.

Therefore, before the inner fins are assembled, the intercooler pipe is driven to move along the extending direction of the positioning hole through the first horizontal driving unit, so that the intercooler pipe is inserted into the positioning groove, and then the intercooler pipe is driven to move along the vertical direction through the first vertical driving unit, so that the intercooler pipe is clamped in the positioning groove, and the problem that the inner fins are damaged or poor in assembling quality due to shaking of the intercooler pipe when the inner fins are assembled is solved.

In some embodiments, the positioning mechanism for the inner fin penetrating machine further comprises a second vertical driving unit arranged on the supporting bracket and a stop block arranged on the second vertical driving unit; the stop block is arranged on one side of the positioning hole facing the first opening; the second vertical driving unit is arranged to drive the stopper to reciprocate between the lower side and the upper side of the bearing surface of the bearing bracket.

Therefore, before the inner fin is assembled, the stop block can be driven by the second vertical driving unit to ascend to the upper part of the bearing surface so as to prevent the intercooler pipe from moving out of the positioning groove from the first opening when the inner fin is assembled; after the assembly of the inner fins is completed, the stop block can be driven by the second vertical driving unit to descend below the bearing surface, so that the assembled intercooler pipe can move out of the positioning groove from the first opening to carry out the assembly of the next intercooler pipe.

In some embodiments, the positioning mechanism for the inner fin penetrating machine further comprises a first limiting block arranged on the support bracket and a second limiting block arranged on the support bracket or the positioning block; the first limiting block is arranged on one side of the positioning hole, which is far away from the first opening, the second limiting block is arranged on one side of the positioning hole, which is far towards the first opening, the second limiting block is arranged above the bearing surface, and the distance between the bottom surface of the second limiting block and the bearing surface is larger than the thickness of the intercooler pipe and is smaller than twice of the thickness of the intercooler pipe.

Therefore, the intercooler pipe which is worn and assembled can be stacked between the first limiting block and the second limiting block, the intercooler pipe at the bottommost layer is assembled each time, the assembled intercooler pipe can be pushed out from a gap between the second limiting block and the bearing surface of the bearing bracket to a position between the first limiting block and the second limiting block, and the second limiting block can prevent the intercooler pipe above the intercooler pipe at the bottommost layer from being pushed out from a position between the first limiting block and the second limiting block; and the first limiting block and the second limiting block can ensure that the intercooler pipe is neatly arranged, so that the first horizontal driving unit and the first vertical driving unit can clamp the intercooler pipe at a fixed position, the inner fins can be conveniently retracted into the accommodating cavity of the intercooler pipe through the driving mechanism, and the automation of the assembly of the inner fins is realized.

In some embodiments, there are two sets of first and second stop blocks distributed on both sides of the intercooler pipe. Thereby further guarantee the orderly emission of intercooler pipe between first stopper and the second stopper.

In some embodiments, the second limiting block is disposed on the supporting bracket or the positioning block through a horizontal position adjusting mechanism having a locking function, and the horizontal position adjusting mechanism is configured to drive the second limiting block to move toward or away from the first limiting block in a horizontal plane along a direction perpendicular to an extension direction of the intercooler pipe in an unlocked state. So that the distance between the second limiting block and the first limiting block can be adjusted through the horizontal position adjusting mechanism to adapt to intercooler pipes with different widths.

In some embodiments, the positioning groove is provided such that the positioning hole communicates with the accommodating cavity of the intercooler pipe when the intercooler pipe is inserted therein, and the positioning hole is located inside the accommodating cavity. So that the inner fins can be inserted into the accommodating cavities of the intercooler pipes after passing through the positioning holes and the positioning grooves.

When assembling in order to solve general interior fin and intercooler pipe, easily lead to interior fin to roll over and decrease for the installation effectiveness is low, and assembly quality is poor, and the rejection rate is high, problem such as with high costs, according to the utility model discloses an aspect provides the interior fin machine of wearing that is equipped with the positioning mechanism who is used for wearing interior fin machine.

The internal fin penetrating machine provided with the positioning mechanism for the internal fin penetrating machine comprises the positioning mechanism for the internal fin penetrating machine; at least one of a second horizontal driving unit for driving the inner fin to be inserted into the intercooler pipe in the direction in which the intercooler pipe extends, and a third horizontal driving unit for driving the intercooler pipe to move toward the side where the first opening is located; the second horizontal driving unit is arranged on the supporting bracket and is positioned on one side of the positioning block, which is far away from the first vertical driving unit; the third horizontal driving unit is arranged on the supporting bracket and is positioned on one side of the positioning hole, which is deviated from the first opening.

Thus, the inner fins can be installed in the accommodating cavities of the intercooler pipes clamped by the first horizontal driving unit and the first vertical driving unit through the second horizontal driving unit, and the assembly automation of the inner fins is realized; after the assembly of the inner fins is completed, the intercooler pipe at the bottommost layer can be pushed out of the positioning groove from the first opening, the second limiting block and the bracket through the third horizontal driving unit, so that the next intercooler pipe can be assembled; and due to the blocking effect of the second limiting block, the intercooler pipe at the bottommost layer can be prevented from being pushed out of the positioning groove, and the smooth assembly of the intercooler pipe is ensured.

Drawings

Fig. 1 is a schematic structural diagram of a positioning mechanism for an inner fin threading machine according to an embodiment of the present invention;

FIG. 2 is a schematic view of the positioning mechanism of the tabbing machine of FIG. 1 from another perspective;

FIG. 3 is a schematic structural view of a positioning mechanism for the inner fin threading machine shown in FIG. 2, taken along the M-M section;

FIG. 4 is a schematic structural view of a using state of a positioning mechanism for the inner fin threading machine shown in FIG. 1;

FIG. 5 is a schematic structural diagram of a positioning mechanism for an inner fin threading machine according to another embodiment of the present invention;

FIG. 6 is a schematic view of the positioning mechanism of the tabbing machine of FIG. 5 from another perspective;

FIG. 7 is a schematic view of the positioning mechanism for the interlining fin machine shown in FIG. 6, taken along the N-N section;

FIG. 8 is a schematic structural view of a using state of a positioning mechanism for the inner fin threading machine shown in FIG. 7;

fig. 9 is a schematic structural view of an internal fin inserting machine provided with a positioning mechanism for inserting an internal fin inserting machine according to an embodiment of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

Fig. 1 to 4 schematically show a positioning mechanism for an internal fin threading machine according to a first embodiment of the present invention.

Referring to fig. 1 and 4, the positioning mechanism for an infill fin machine includes a support bracket 20 for supporting an intercooler pipe 100; and a positioning block 21, a first horizontal driving unit 30 and a first vertical driving unit 40 all provided on the support bracket 20; wherein, the positioning block 21 is integrally formed or machined with a positioning hole 211 for the inner fin to pass through and a positioning groove 212 for accommodating one end of the intercooler pipe 100, the positioning hole 211 and the positioning groove 212 both extend along the first direction, one end of the positioning groove 212 is communicated with the positioning hole 211, the other end is communicated with the outside, one side of the positioning groove 212 is integrally formed or machined with a first opening 2121 communicated with the outside; the first horizontal driving unit 30 is used for driving the intercooler pipe 100 to move along the extending direction of the positioning hole 211 so as to be inserted into the positioning groove 212; the first vertical driving unit 40 serves to drive the intercooler pipe 100 to move in a vertical direction.

Referring to fig. 1, 3 and 4, in some embodiments, the positioning holes 211 and the positioning grooves 212 are provided on the outer side of one end of the intercooler pipe 100 placed on the supporting surface 201, the first horizontal driving unit 30 is provided on the outer side of the other end of the intercooler pipe 100, and the first horizontal driving unit 30 is configured to drive the intercooler pipe 100 to move toward the end where the positioning grooves 212 are located.

Referring to fig. 3, in some embodiments, the first horizontal driving unit 30 includes a first cylinder 31 mounted on the support bracket 20 or the positioning block 21 and a first push block 32 mounted on a piston rod of the first cylinder 31, the piston rod of the first cylinder 31 is disposed in a first direction, the first push block 32 is disposed at a position corresponding to the intercooler pipe 100 placed on the bearing surface 201, and a bottom surface of the first push block 32 is located above a bottom surface of the intercooler pipe 100, and a top surface of the first push block 32 is located above the bottom surface of the intercooler pipe 100, so that the first push block 32 is only in contact with the intercooler pipe 100 directly placed on the bearing surface 201 when the first cylinder 31 drives the first push block 32.

With continued reference to fig. 3, in some embodiments, the first vertical driving unit 40 includes a second cylinder mounted on the supporting bracket 20 or the positioning block 21 and a second pushing block 41 mounted on a piston rod of the second cylinder, the piston rod of the second cylinder is disposed along the vertical direction, the second pushing block 41 is disposed at a position corresponding to the intercooler pipe 100 placed on the supporting surface 201, and the piston rod of the second cylinder is disposed upward, so that the second pushing block 41 is driven by the second cylinder to drive the intercooler pipe 100 placed on the supporting surface 201 to move upward.

Preferably, the first direction is arranged along a horizontal direction. Preferably, the first vertical driving unit 40 is provided to be able to drive the intercooler pipe 100 upward in the vertical direction to abut the top of the intercooler pipe 100 inserted into the positioning groove 212 against the top of the positioning groove 212, thereby clamping the intercooler pipe 100 in the positioning groove 212 by the first vertical driving unit 40. Referring to fig. 1 and 4, the first opening 2121 is provided at the side of the detent groove 212 except the top and bottom, and the width of the first opening 2121 is larger than the thickness of the intercooler pipe 100 so that the intercooler pipe 100 inserted into the detent groove 212 can be moved out of the first opening 2121 out of the detent groove 212.

Therefore, before the inner fins are assembled, the intercooler pipe 100 is placed on the bearing surface 201 of the bearing bracket 20 along the first direction and aligned with the positioning groove 212, and then the first push block 32 is driven by the first cylinder 31 along the extending direction of the positioning hole 211 to drive the intercooler pipe 100 to move, so that the intercooler pipe 100 is inserted into the positioning groove 212; and then the second cylinder drives the second push block 41 to drive the intercooler pipe 100 to move along the vertical direction so as to clamp the intercooler pipe 100 in the positioning groove 212 (refer to fig. 4), thereby avoiding the problem that the intercooler pipe 100 is broken or the assembling quality is poor due to shaking when the intercooler pipe 100 is assembled.

Referring to fig. 3, in some embodiments, to facilitate the insertion of the inner fin, a first guide section 2111 is provided at an end of the positioning hole 211 facing away from the positioning slot 212, and an inner diameter of the first guide section 2111 increases as a distance from the positioning slot 212 increases.

With continued reference to fig. 3, in some embodiments, to facilitate insertion of the intercooler pipe 100, a second guide section 2122 is provided at an end of the positioning slot 212 facing away from the positioning hole 211, the inner diameter of the second guide section 2122 increasing as its distance from the positioning hole 211 increases.

Referring to fig. 1, in some embodiments, the positioning mechanism for an internal fin threading machine further includes a first stopper 61 disposed on the support bracket 20, and a second stopper 62 disposed on the support bracket 20 or the positioning block 21; the first limiting block 61 is arranged on one side of the positioning hole 211 departing from the first opening 2121, the second limiting block 62 is arranged on one side of the positioning hole 211 facing the first opening 2121, the second limiting block 62 is arranged above the bearing surface 201, the thickness of the intercooler pipe 100 is X, and the distance between the bottom surface of the second limiting block 62 and the bearing surface 201 is smaller than 2X.

The intercooler pipe 100 is limited at the position corresponding to the positioning hole 211 through the two limiting blocks, and after the intercooler pipe 100 at the lowest layer is assembled and pushed out of the positioning groove 212 each time, the intercooler pipe 100 with the inner fins to be assembled can be placed between the two limiting blocks from the upper part, so that the automatic feeding of the intercooler pipe 100 is realized.

Referring to fig. 1 and 3, in some embodiments, there are two sets of first and second stop blocks 61, 62, with the two sets of first and second stop blocks 61, 62 distributed on either side of the intercooler pipe 100.

Referring to fig. 1 and 4, in some embodiments, the second stopper 62 is disposed on the support bracket 20 or the positioning block 21 through a horizontal position adjusting mechanism 63 having a locking function, and the horizontal position adjusting mechanism 63 is configured to drive the second stopper 62 to move toward or away from the first stopper 61 in a horizontal plane along a direction perpendicular to an extending direction of the intercooler pipe 100 in an unlocked state.

Referring to fig. 4, in some embodiments, the horizontal position adjusting mechanism 63 includes a first rail 631 and a first slider 632 that are adapted to each other, wherein the first rail 631 is disposed on the support bracket 20 or the positioning block 21 and is disposed in a horizontal plane perpendicular to an extending direction of the intercooler pipe 100, a locking function of the first rail 631 is achieved by a first screw hole 6311 formed in the first rail 631 and a first through groove 6321 integrally formed or formed on the first slider 632, the first through groove 6321 corresponds to the first screw hole 6311, a bolt is connected to the first screw hole 6311 through the first through groove 6321, and locking and unlocking of the locking function are achieved by locking and loosening of the bolt.

Referring to fig. 1-4, in some embodiments, the positioning mechanism for an infill fin machine further includes a third horizontal drive unit 80 disposed on the support bracket 20 and located on a side of the positioning hole 211 facing away from the first opening 2121, the third horizontal drive unit 80 being configured to drive the bottommost intercooler pipe 100 toward the side of the first opening 2121.

Referring to fig. 3 and 4, in some embodiments, the third horizontal driving unit 80 includes a fourth cylinder and a third guide rail 81 provided on the support bracket 20, and a third slider 82 provided on a piston rod of the fourth cylinder, wherein the third guide rail 81 is provided in a vertical first direction in a horizontal plane, the fourth cylinder is provided on a side of the positioning hole 211 facing away from the first opening 2121, the piston rod of the fourth cylinder is provided toward a side where the first opening 2121 is located, the third slider 82 is provided at a position corresponding to the intercooler pipe 100 placed on the support surface 201, and a bottom surface of the third slider 82 is located above a bottom surface of the intercooler pipe 100, and a top surface of the third slider 82 is located above the bottom surface of the intercooler pipe 100, so that when the fourth cylinder drives the third slider 82, the third slider 82 is in contact with only the intercooler pipe 100 placed directly on the support surface 201.

In some embodiments, the positioning groove 212 is provided such that the positioning hole 211 communicates with the accommodating cavity 101 of the intercooler pipe 100 when the intercooler pipe 100 is inserted therein, and the positioning hole 211 is located inside the accommodating cavity 101, i.e., the positioning hole 211 is smaller in size than the accommodating cavity 101 of the intercooler pipe 100. The position of the intercooled organ corresponding to the positioning hole 211 is defined by the first stopper 61, the second stopper 62, the first vertical driving unit 40 and the second vertical driving unit 50 to ensure that the inner wall of the accommodating chamber 101 of the intercooled organ inserted into the positioning groove 212 is positioned outside the positioning hole 211.

Fig. 5 to 8 schematically show a positioning mechanism for an inner fin threading machine according to a second embodiment of the present invention.

The first embodiment can be referred to for other structures of the positioning mechanism for the interlining blade machine in the present embodiment. Further, as shown in fig. 5, 7 and 8, the positioning mechanism for an inner fin threading machine in the present embodiment further includes a second vertical driving unit 50 provided on the support bracket 20 and a stopper 51 provided on the second vertical driving unit 50; the stopper 51 is disposed on the side of the positioning hole 211 facing the first opening 2121; the second vertical driving unit 50 is provided to be able to drive the stopper 51 to reciprocate between below and above the bearing surface 201 of the bearing bracket 20.

Referring to fig. 7, in some embodiments, the second vertical driving unit 50 includes a third air cylinder, a piston rod of which is disposed upward, and a stopper 51 disposed on the piston rod of the third air cylinder.

With continued reference to fig. 7, in some embodiments, the intercooler pipe 100 placed on the seating surface 201 may be lifted up to a position corresponding to the positioning hole 211 and the positioning groove 212 by the third air cylinder so that the first horizontal driving unit 30 drives the intercooler pipe 100 to be inserted into the positioning groove 212 to align the receiving cavity 101 of the intercooler pipe 100 with the positioning hole 211.

With continued reference to FIG. 7, in some embodiments, a third pusher block 52 is provided on the piston rod of the third cylinder for lifting the intercooler pipe 100 resting on the seating surface 201.

When the first stopper 61 and the second stopper 62 are provided, the manner in which the intercooler pipe 100 to be assembled is stacked between the first stopper 61 and the second stopper 62 is shown with reference to fig. 8, so as to facilitate automation of assembling the inner fins of the intercooler pipe 100.

Fig. 9 schematically illustrates an infill fin machine provided with a positioning mechanism for the infill fin machine according to an embodiment of the present invention.

Referring to fig. 9, the internal fin threading machine provided with the positioning mechanism for the internal fin threading machine includes the aforementioned positioning mechanism for the internal fin threading machine; further comprises at least one of a second horizontal driving unit 70 for driving the inner fin to be inserted into the intercooler pipe 100 in the direction in which the intercooler pipe 100 extends, and a third horizontal driving unit 80 for driving the intercooler pipe 100 to move toward the side where the first opening 2121 is located; wherein, the second horizontal driving unit 70 is disposed on the supporting bracket 20 and located at a side of the positioning block 21 away from the first vertical driving unit 40; the third horizontal driving unit 80 is disposed on the support bracket 20 and located at a side of the positioning hole 211 away from the first opening 2121.

The structure of the positioning mechanism for an inner fin piercing machine in the present embodiment can refer to the first or second embodiment.

With continued reference to fig. 9, in some embodiments, the second horizontal driving unit 70 includes a fourth pushing block 75, a first screw rod 71 and a first nut 72 that are adapted to each other, a second guiding rail 73 and a second slider 74 that are adapted to each other, and a motor that is disposed on the supporting bracket 20 or the positioning block 21, the second guiding rail 73 and the first screw rod 71 are disposed on the supporting bracket 20 or the positioning block 21 along a first direction, and the first screw rod 71 can be disposed opposite to the supporting bracket 20 or the positioning block 21; the first nut 72 is connected with the second slider 74, and the fourth push block 75 is arranged on the first nut 72 or the second slider 74.

The first screw rod 71 is driven by the motor to rotate, the first nut 72 and the second slider 74 are driven to reciprocate along the extending direction of the first screw rod 71, the second slider 74 and the fourth push block 75, so that the inner fins are pushed into the accommodating cavity 101 of the intercooler pipe 100 through the positioning holes 211 and the positioning grooves 212 by the fourth push block 75, and automation of assembling the inner fins of the intercooler pipe 100 is realized.

What has been described above are only some embodiments of the invention. For those skilled in the art, without departing from the inventive concept, several modifications and improvements can be made, which are within the scope of the invention.

Claims (10)

1. A positioning mechanism for wearing interior fin machine, its characterized in that includes:

a support bracket for supporting the intercooler pipe;

the positioning block, the first horizontal driving unit and the first vertical driving unit are arranged on the supporting bracket;

the positioning block is provided with a positioning hole for the inner fin to pass through and a positioning groove for accommodating one end of the intercooler pipe, the positioning groove is communicated with the positioning hole, and one side of the positioning groove is provided with a first opening communicated with the outside;

the first horizontal driving unit is arranged to drive the intercooler pipe to move along the extending direction of the positioning hole so as to be inserted into the positioning groove;

the first vertical driving unit is provided to be able to drive the intercooler pipe to move in a vertical direction.

2. The positioning mechanism for an endofin machine of claim 1, further comprising a second vertical drive unit provided on the support bracket and a stop provided on the second vertical drive unit;

the stop block is arranged on one side, facing the first opening, of the positioning hole;

the second vertical driving unit is arranged to drive the stopper to reciprocate between the lower side and the upper side of the bearing surface of the bearing bracket.

3. The positioning mechanism for an inner fin threading machine as claimed in claim 1, further comprising a first limiting block arranged on the support bracket, and a second limiting block arranged on the support bracket or the positioning block;

the first limiting block is arranged on one side, away from the first opening, of the positioning hole, the second limiting block is arranged on one side, facing the first opening, of the positioning hole, the second limiting block is arranged above the bearing surface, and the distance between the bottom surface of the second limiting block and the bearing surface is larger than the thickness of the intercooler pipe and smaller than twice the thickness of the intercooler pipe.

4. The positioning mechanism for the inner fin threading machine as claimed in claim 2, further comprising a first limiting block arranged on the support bracket, and a second limiting block arranged on the support bracket or the positioning block;

the first limiting block is arranged on one side of the positioning hole, which is far away from the first opening, the second limiting block is arranged on one side of the positioning hole, which is far towards the first opening, the second limiting block is arranged above the bearing surface, and the distance between the bottom surface of the second limiting block and the bearing surface is larger than the thickness of the intercooler pipe and smaller than twice the thickness of the intercooler pipe.

5. The positioning mechanism for threading an internal fin machine as recited in claim 3, wherein there are two sets of the first and second limiting blocks, the two sets of the first and second limiting blocks being distributed on both sides of the intercooler pipe.

6. The positioning mechanism for threading an internal fin machine as recited in claim 4, wherein there are two sets of the first and second limiting blocks, the two sets of the first and second limiting blocks being distributed on both sides of the intercooler pipe.

7. The positioning mechanism for an inner fin threading machine as claimed in any one of claims 3 to 6, wherein the second limiting block is arranged on the support bracket or the positioning block through a horizontal position adjusting mechanism with a locking function, and the horizontal position adjusting mechanism is arranged to drive the second limiting block to move towards or away from the first limiting block along a direction perpendicular to the extension direction of the intercooler pipe in a horizontal plane in an unlocked state.

8. The positioning mechanism for an endofinned machine as set forth in any one of claims 2 to 6 wherein said positioning groove is provided so that said positioning hole communicates with a housing cavity of said intercooler pipe when said intercooler pipe is inserted therein, and said positioning hole is located inside said housing cavity.

9. The positioning mechanism for an endofinned machine as set forth in claim 7, wherein said positioning groove is provided such that said positioning hole communicates with a housing cavity of said intercooler pipe when said intercooler pipe is inserted therein, and said positioning hole is located inside said housing cavity.

10. An internal fin penetrating machine provided with a positioning mechanism for the internal fin penetrating machine, which is characterized by comprising the positioning mechanism for the internal fin penetrating machine as claimed in any one of claims 1 to 6;

the horizontal driving unit is used for driving the inner fins to be inserted into the intercooler pipe along the extending direction of the intercooler pipe, and the horizontal driving unit is used for driving the intercooler pipe to move towards the side of the first opening; wherein the content of the first and second substances,

the second horizontal driving unit is arranged on the supporting bracket and is positioned on one side of the positioning block, which is far away from the first vertical driving unit;

the third horizontal driving unit is arranged on the supporting bracket and is positioned on one side of the positioning hole, which is far away from the first opening.

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