CN113146419A

CN113146419A - High-hardness metal pipe machining device and machining process

Info

Publication number: CN113146419A
Application number: CN202110574569.9A
Authority: CN
Inventors: 姜睿泓
Original assignee: Individual
Current assignee: Jiangsu Dihang Industrial Technology Co.,Ltd.
Priority date: 2021-05-26
Filing date: 2021-05-26
Publication date: 2021-07-23
Anticipated expiration: 2041-05-26
Also published as: CN113146419B

Abstract

The invention relates to the field of metal pipe processing, in particular to a high-hardness metal pipe processing device and a processing technology. The utility model provides a high rigidity tubular metal resonator processingequipment, is including rolling over frame and friction pulley, it is provided with two to roll over the frame, and every both ends of rolling over the frame are all rotated and are connected with the friction pulley, and two intervals of rolling over between the frame can be adjusted. The high-hardness metal pipe machining device further comprises a motor III, wherein one folding frame is fixedly connected with the motor III, and an output shaft of the motor III is fixedly connected with one friction wheel. The processing technology of the high-hardness metal pipe processing device comprises the following steps: (A) processing a plurality of grinding grooves on the metal pipe; (B) inserting a plurality of grinding grooves into the reinforcing columns; (C) processing a notch on each reinforcing column; (D) and sleeving the bandage on the outer sides of the plurality of reinforcing columns, and inserting the bandage into the groove.

Description

High-hardness metal pipe machining device and machining process

Technical Field

The invention relates to the field of metal pipe processing, in particular to a high-hardness metal pipe processing device and a processing technology.

Background

Patent number is 201922386484.9 discloses a corrugated metal tube forming device, and this utility model belongs to tubular metal resonator processing field, concretely relates to corrugated metal tube forming device, the on-line screen storage device comprises a base, the thread groove has been seted up at the middle part of base, there is the thread piece through threaded connection in the thread groove, the upper end fixedly connected with positioning seat of thread piece, the upper end welding of base has the support frame, the fixed surface of support frame installs the cylinder, the adapter sleeve is installed through the bolt to the end of the cylinder pole of cylinder, the terminal welding of adapter sleeve has the link, the skin weld of link has the connecting rod, the terminal welding of connecting rod has the semicircle ring, the right-hand member fixed mounting of support frame has control switch, the protecting crust is installed through the bolt to the right-hand member of support frame. This scheme is through the auxiliary member that the design comprises adapter sleeve, link, connecting rod and semicircle ring, and the auxiliary member passes through the cylinder drive, can realize with the quickly separating of tubular metal resonator, need not successive layer installation auxiliary member moreover, has improved work efficiency. However, this patent fails to machine a plurality of grinding grooves in the metal tube.

Disclosure of Invention

The invention provides a device and a process for processing a high-hardness metal pipe, aiming at overcoming the defects of the prior art.

The utility model provides a high rigidity tubular metal resonator processingequipment, is including rolling over frame and friction pulley, it is provided with two to roll over the frame, and every both ends of rolling over the frame are all rotated and are connected with the friction pulley, and two intervals of rolling over between the frame can be adjusted.

The high-hardness metal pipe machining device further comprises a motor III, wherein one folding frame is fixedly connected with the motor III, and an output shaft of the motor III is fixedly connected with one friction wheel.

The high-hardness metal pipe processing device further comprises a vertical rod, wherein one folding frame is fixedly connected to the vertical rod, and the other folding frame is connected to the vertical rod in a sliding mode.

The high-hardness metal pipe machining device further comprises a telescopic rod II, the telescopic rod II is fixedly connected onto the vertical rod, and the movable end of the telescopic rod II is fixedly connected onto a folding frame capable of sliding.

The high-hardness metal pipe machining device further comprises a round blocking edge, and each friction wheel is provided with the round blocking edge.

The high-hardness metal pipe machining device further comprises a bottom strip, a middle seat and a flat rod, wherein the middle seat is fixedly connected to the bottom strip, and the flat rod can slide on the middle seat.

The utility model provides a high rigidity tubular metal resonator processingequipment still includes motor II and lead screw, and the lower part of montant is provided with motor II, fixedly connected with lead screw on motor II's the output shaft, and the lead screw cooperatees through screw thread and well seat.

The utility model provides a high rigidity tubular metal resonator processingequipment still includes round bar, crossbeam, rotating turret, mill and motor I, and two round bar difference fixed connection are both ends about the bottom strip, and the both ends of crossbeam sliding connection are respectively on two round bars, fixedly connected with rotating turret on the crossbeam, are provided with on the rotating turret can the pivoted mill, are fixed with motor I on the rotating turret, and motor I's output shaft links firmly on the mill.

The utility model provides a high rigidity tubular metal resonator processingequipment still includes telescopic link I, has linked firmly telescopic link I on two round bars, and the equal fixed connection of expansion end of two telescopic link I is on the crossbeam.

The processing technology of the high-hardness metal pipe processing device comprises the following steps:

(A) processing a plurality of grinding grooves on the metal pipe;

(B) inserting a plurality of grinding grooves into the reinforcing columns;

(C) processing a notch on each reinforcing column;

(D) and sleeving the bandage on the outer sides of the plurality of reinforcing columns, and inserting the bandage into the groove.

The processing device and the processing technology for the high-hardness metal pipe have the beneficial effects that:

according to the invention, a plurality of grinding grooves can be processed on the metal pipe, and the reinforcing columns are inserted into the plurality of grinding grooves.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic structural view of a high hardness metal pipe processing apparatus;

FIG. 2 is a schematic view showing a part of a high hardness metal pipe processing apparatus;

FIG. 3 is a schematic diagram of a second partial structure of a high hardness metal pipe machining apparatus;

FIG. 4 is a schematic diagram of a part of a high hardness metal pipe machining apparatus;

FIG. 5 is a schematic structural view of a bottom bar and a cross bar;

FIG. 6 is a first schematic structural view of a vertical rod and a folding frame;

FIG. 7 is a second schematic structural view of the vertical bar and the folding frame;

FIG. 8 is a schematic structural diagram of a square slice;

FIG. 9 is a schematic structural view of a metal tube;

fig. 10 is a schematic view of the structure of the strap.

In the figure: a bottom strip 101; a middle seat 102; a round bar 103; a telescopic rod I104;

a cross member 201; a turret 202; abrasive disc 203; a motor I204;

a vertical rod 301; a motor II 302; a screw 303; a flat bar 304;

a folding frame 401; a rounded ledge 402; a friction wheel 403; a telescopic rod II 404; motor III 405;

a square piece 501; a fastening screw I502; a reach arm 503; a slide carriage 504; a chassis 505;

a metal tube 601; a milling groove 602; a reinforcing column 603; a notch 604;

a strap 701; a fastening screw II 702; a fastening seat 703; a hand-threaded rod 704; a top mount 705.

Detailed Description

Referring to fig. 3-4 and fig. 6, an embodiment of the present invention is provided to solve the main technical problem of facilitating to machine a plurality of grinding grooves 602 on a metal pipe 601, and insert a plurality of grinding grooves 602 into a reinforcing column 603, and further,

because every both ends of rolling over a 401 all rotate and be connected with friction pulley 403, and two intervals between rolling over a 401 can be adjusted, and then can adjust two intervals between four friction pulley 403 on rolling over a 401, and then can press from both sides four friction pulley 403 at the tip of tubular metal resonator 601, and then set up tubular metal resonator 601 between four friction pulley 403, it rotates to drive tubular metal resonator 601 when four friction pulley 403 rotate, and then be convenient for process out a plurality of groove 602 that grinds on tubular metal resonator 601, and with a plurality of groove 602 that grinds, insert enhancement post 603 in.

Referring to fig. 6, an embodiment of the present invention is provided to solve a main technical problem that when an output shaft of a motor III405 rotates, one of friction wheels 403 may be driven to rotate, and further,

because one of the folding frames 401 is fixedly connected with the motor III405, when the output shaft of the motor III405 rotates, one of the friction wheels 403 can be driven to rotate, so that the metal pipe 601 is driven to rotate among the four friction wheels 403, the rotating position of the metal pipe 601 is changed, a plurality of grinding grooves 602 are conveniently machined in the metal pipe 601, and the reinforcing columns 603 are inserted into the plurality of grinding grooves 602.

Referring to fig. 6, an embodiment of the present invention is provided to solve the main technical problem that the space between four friction wheels 403 on two folding frames 401 can be adjusted, and further,

because one of the folding frames 401 is fixedly connected to the vertical rod 301, and the other folding frame 401 is slidably connected to the vertical rod 301, when the movable folding frame 401 slides on the vertical rod 301, the distance between the four friction wheels 403 on the two folding frames 401 can be adjusted, so that the four friction wheels 403 can be clamped at the end of the metal pipe 601, and the metal pipe 601 is arranged between the four friction wheels 403.

Referring to fig. 6, an embodiment of the present invention is provided to solve the main technical problem that the telescopic rod II404 drives the movable folding frame 401 to move when extending and retracting, and further,

because fixedly connected with telescopic link II404 on montant 301, telescopic link II 404's expansion end is fixed connection and can gliding book on putting up 401, and then telescopic link II404 drives this folding frame 401 that can remove when flexible, and then can adjust two when this folding frame 401 that can remove slides on montant 301 and roll up the interval between four friction pulley 403 on the frame 401, and then can press from both sides four friction pulley 403 at the tip of tubular metal resonator 601, and then set up tubular metal resonator 601 between four friction pulley 403.

Referring to fig. 3 and fig. 6, an embodiment of the present invention is provided, which solves the main technical problem that the circular blocking edge 402 can block the end of the metal tube 601, so that the four friction wheels 403 can be better clamped on the metal tube 601, and further,

since each friction wheel 403 is provided with the round blocking edge 402, the round blocking edge 402 can block the end of the metal pipe 601, so that the four friction wheels 403 can be better clamped on the metal pipe 601.

Referring to fig. 3 and fig. 6, an embodiment of the present invention is provided to solve the main technical problem that when the flat bar 304 slides back and forth on the middle seat 102, the flat bar 301 and the four friction wheels 403 can be driven to move back and forth, so as to drive the metal tube 601 between the four friction wheels 403 to slide back and forth, and further,

because the bottom strip 101 is fixedly connected with the middle seat 102, the flat rod 304 is slidably connected to the middle seat 102, and further, when the flat rod 304 slides back and forth on the middle seat 102, the vertical rod 301 and the four friction wheels 403 can be driven to move back and forth, so that the metal tubes 601 between the four friction wheels 403 are driven to slide back and forth.

Referring to fig. 1-7, an embodiment of the present invention is provided to solve the main technical problem that when the motor II302 drives the screw rod 303 to rotate, the motor II can drive the flat bar 304 to slide back and forth on the middle seat 102, and further,

because the lower part of the vertical rod 301 is fixedly connected with the motor II302, the screw rod 303 on the motor II302 is matched with the middle seat 102 through threads, and then the motor II302 drives the screw rod 303 to rotate, so that the flat rod 304 can be driven to slide back and forth on the middle seat 102, and further the metal pipe 601 among the four friction wheels 403 can be driven to slide back and forth.

Referring to fig. 1-10, an embodiment of the present invention is provided, which solves a main technical problem that a plurality of grinding grooves 602 can be machined on a metal pipe 601 by rotating the metal pipe 601 to change a position of the metal pipe 601, and further,

because equal fixedly connected with round bar 103 in both ends about the sill bar 101, the both ends difference sliding connection of crossbeam 201 is on two round bars 103, the rotating turret 202 has been linked firmly on crossbeam 201, it has mill 203 to rotate on the rotating turret 202, be provided with motor I204 on the rotating turret 202, the output shaft of motor I204 links firmly on mill 203, and then crossbeam 201 can be vertical slip on two round bars 103, and then drive rotating turret 202 and mill 203 and reciprocate, and then drive mill 203 and move tangential tubular metal resonator 601 downwards, can process out mill groove 602 on tubular metal resonator 601 when tubular metal resonator 601 moves back-and-forth relative mill 203, it can process out a plurality of mill grooves 602 on tubular metal resonator 601 to rotate tubular metal resonator 601 and change tubular metal resonator 601's position after.

Referring to fig. 1-10, an embodiment of the present invention is provided to solve the main technical problem that when two telescopic rods I104 are simultaneously extended and retracted, a cross beam 201 can be driven to vertically slide on two round rods 103, and further,

because two round bars 103 are fixedly connected with telescopic link I104, the active ends of two telescopic links I104 are all fixedly connected at the lower side of crossbeam 201. When the two telescopic rods I104 are simultaneously telescopic, the cross beam 201 can be driven to vertically slide on the two round rods 103.

(A) processing a plurality of grinding grooves 602 on the metal pipe 601;

(B) inserting a plurality of grinding grooves 602 into the reinforcing columns 603;

(C) a notch 604 is machined on each reinforcing column 603;

(D) the strap 701 is sleeved on the outside of the plurality of reinforcing posts 603 and the strap 701 is inserted into the slot 604.

The high-hardness metal pipe machining device further comprises a square plate 501, extension arms 503, sliding seats 504 and a bottom frame 505, the bottom frame 505 is fixedly connected onto the bottom strip 101, the extension arms 503 are fixedly connected onto four sides of the square plate 501, the extension arms 503 located on the lower side are fixedly connected onto the upper portion of the bottom frame 505, and the sliding seats 504 are arranged on the extension arms 503.

Referring to fig. 1-10, an embodiment of the present invention is provided, which solves the main technical problem of facilitating the insertion of the reinforcing columns 603 into a plurality of grinding grooves 602 formed on the metal pipe 601, and further,

the plurality of sliders 504 are used for inserting the reinforcing columns 603, so as to support the reinforcing columns 603, and further facilitate the insertion of the reinforcing columns 603 into the plurality of grinding grooves 602 machined on the metal pipe 601.

The high-hardness metal pipe machining device further comprises a fastening screw I502, the sliding base 504 is connected to the extending arm 503 in a sliding mode, the fastening screw I502 is connected to the sliding base 504 in a threaded mode, and the fastening screw I502 abuts against the extending arm 503.

Referring to fig. 1-10, an embodiment of the present invention is provided, which solves the main technical problem of adapting to insert reinforcing columns 603 on metal pipes 601 of different sizes, and further,

the carriages 504 can be moved over the reach arms 503 to change the position, and thus the position, of the plurality of carriages 504 to accommodate insertion of the reinforcement columns 603 on different sizes of metal tubes 601.

The high-hardness metal pipe processed by the high-hardness metal pipe processing device comprises a metal pipe 601, grinding grooves 602 and reinforcing columns 603, wherein a plurality of grinding grooves 602 are uniformly distributed on the outer side of the metal pipe 601 in an annular manner, and the reinforcing columns 603 are arranged on the plurality of grinding grooves 602.

Referring to fig. 1-10, an embodiment of the present invention is provided, which solves the main technical problem of increasing the hardness of a metal pipe 601, and further,

the grinding groove 602 on the metal tube 601 is used for installing the reinforcing column 603, and the reinforcing column 603 is used for increasing the hardness of the metal tube 601 and preventing the metal tube 601 from deforming.

The high-hardness metal pipe further comprises a notch 604 and a binding band 701, the reinforcing column 603 is provided with a plurality of notches 604, the binding band 701 is bound on the outer sides of the plurality of reinforcing columns 603, and the binding band 701 is inserted into the notch 604 on the reinforcing column 603.

Referring to fig. 1-10, an embodiment of the present invention is provided, which solves the main technical problem of preventing a plurality of reinforcing columns 603 from being separated from a metal pipe 601 after a binding band 701 is bound on the outer side of the plurality of reinforcing columns 603, and further,

the plurality of reinforcing columns 603 are prevented from being separated from the metal pipe 601 after the bands 701 are bound on the outer sides of the plurality of reinforcing columns 603, and the bands 701 are bound on the notches 604 on the reinforcing columns 603, so that the bands 701 are prevented from falling off from the reinforcing columns 603.

The high-hardness metal pipe further comprises a fastening screw II702 and a fastening seat 703, two end parts of the binding band 701 are inserted into the fastening seat 703, the fastening seat 703 is in threaded connection with the two fastening screws II702, and the two fastening screws II702 are respectively propped against two ends of the binding band 701.

Referring to fig. 1-10, an embodiment of the present invention is provided, which solves the main technical problem of binding a strap 701 to metal pipes 601 with different sizes, and further,

the strap 701 can slide on the fastening seat 703, and the length of the strap 701 is adjusted, so that the strap 701 is tied on the metal pipes 601 with different sizes, and the fastening screw II702 is used for fixing the strap 701 and the fastening seat 703.

The high-hardness metal pipe further comprises a hand-screwed screw 704 and a top seat 705, the two end parts of the binding band 701 are fixedly connected with the top seat 705, the top seat 705 is in threaded connection with the hand-screwed screw 704, and the lower part of the hand-screwed screw 704 is propped against the fastening seat 703.

Referring to fig. 1-10, an embodiment of the present invention is provided, which solves the main technical problem of tightly binding the binding band 701 on the outer side of the metal pipe 601, and further,

rotating the hand screw 704 relative to the top seat 705 can press the fastening seat 703 downwards, so that the binding band 701 is tightly bound on the outer side of the metal pipe 601.

Claims

1. The utility model provides a high rigidity tubular metal resonator processingequipment, includes roll over frame (401) and friction pulley (403), its characterized in that: roll over frame (401) and be provided with two, the both ends of every folding frame (401) are all rotated and are connected with friction pulley (403), and the interval between two folding frames (401) can be adjusted.

2. The high-hardness metal pipe processing device according to claim 1, wherein: the folding mechanism further comprises a motor III (405), wherein one folding frame (401) is fixedly connected with the motor III (405), and an output shaft of the motor III (405) is fixedly connected with one friction wheel (403).

3. The high-hardness metal pipe processing device according to claim 2, wherein: the folding type folding bicycle is characterized by further comprising vertical rods (301), wherein one folding frame (401) is fixedly connected to the vertical rods (301), and the other folding frame (401) is connected to the vertical rods (301) in a sliding mode.

4. A high-hardness metal pipe processing apparatus according to claim 3, wherein: the folding frame is characterized by further comprising a telescopic rod II (404), the telescopic rod II (404) is fixedly connected to the vertical rod (301), and the movable end of the telescopic rod II (404) is fixedly connected to the folding frame (401) capable of sliding.

5. The high-hardness metal pipe processing device according to claim 4, wherein: the friction wheel is characterized by further comprising circular blocking edges (402), and each friction wheel (403) is provided with the circular blocking edge (402).

6. The high-hardness metal pipe processing device according to claim 5, wherein: the novel electric heating cooker also comprises a bottom strip (101), a middle seat (102) and a flat rod (304), wherein the middle seat (102) is fixedly connected to the bottom strip (101), and the flat rod (304) is connected to the middle seat (102) in a sliding mode.

7. The high-hardness metal pipe processing device according to claim 6, wherein: the electric bicycle is characterized by further comprising a motor II (302) and a screw rod (303), the lower portion of the vertical rod (301) is fixedly connected with the motor II (302), an output shaft of the motor II (302) is fixedly connected with the screw rod (303), and the screw rod (303) is matched with the middle seat (102) through threads.

8. The high-hardness metal pipe processing device according to claim 7, wherein: still include round bar (103), crossbeam (201), rotating turret (202), mill (203) and motor I (204), both ends have all linked firmly round bar (103) about sill bar (101), and sliding connection is on two round bar (103) respectively at the both ends of crossbeam (201), has linked firmly rotating turret (202) on crossbeam (201), and it is connected with mill (203) to rotate on rotating turret (202), is provided with motor I (204) on rotating turret (202), and the output shaft of motor I (204) links firmly on mill (203).

9. The high-hardness metal pipe processing device according to claim 8, wherein: the telescopic rod I (104) is fixedly connected to the two round rods (103), and the movable ends of the two telescopic rods I (104) are fixedly connected to the lower side of the cross beam (201).

10. The processing technology of the high-hardness metal pipe processing device according to claim 9 comprises the following steps:

(A) processing a plurality of grinding grooves (602) on a metal pipe (601);

(B) inserting a plurality of grinding grooves (602) into a reinforcing column (603);

(C) machining a notch (604) on each reinforcing column (603);

(D) and sleeving the bandage (701) on the outer sides of the plurality of reinforcing columns (603), and inserting the bandage (701) into the notch (604).