BE1026943B1 - Built-in device for cutting irregular sections for large pipelines - Google Patents

Abstract

The present invention includes a support frame component, a translation component, a rotation component, and a telescope compensation component. The three telescopic components are distributed in a herringbone shape at the same angle in the triangular position of the herringbone support frame component. The translation component and the rotation component are arranged in the same axis, the translation component and the telescope compensation component are arranged at right angles, and the rotation component drives the telescope compensation component to rotate. The device uses AC servo drive technology as well as laser cutting and welding technology to implement automatic control and adjustment of the cutting path. It is suitable for cutting non-vertical planar curved sections of pipes with different cross-sectional shapes. No centering process is required. It has the advantages of compact structure, easy operation, convenient loading and unloading, high work efficiency, etc. It can greatly reduce the loading and unloading time and setting difficulty.

Description

Description BE2020 / 5016 Built-in device for cutting irregular sections for large pipelines Technical area The invention belongs to the technical field of mechanical production engineering and relates to a built-in device for cutting irregular sections for large pipelines and is used for the contactless cutting of irregular sections or any curved surfaces for the large pipelines.

Background Technology With the development of economy and technology, large diameter pipelines are required for long-distance transportation of oil, natural gas and water. When laying the pipeline, it is essential to cut and weld the pipeline in order to realize the flat butt joint, the right angle butt joint and the oblique butt joint of the pipe.

In the prior art, for the cut-and-butt joint portion of a large-diameter pipeline, the clamp-type external pipe cutter is often used, but only a flat butt joint can be released while the right-angle butt joint can only be made by hand. Manual marking is adopted first, and then manual grinding wheel is used for cutting and welding. In this way, the cut pipe section has large losses and poor precision, which cannot guarantee the quality of the butt joint.

As a non-contact thermal processing method, laser cutting can cut almost all materials and the cutting path is not limited. The two-dimensional section cutting or the three-dimensional section cutting can be realized. Laser cutting offers the advantages of high processing accuracy, high cutting speed, smooth incision, material savings and low processing costs. There is no contact between the mechanical part of the laser cutting head and the workpiece.

There is no cutting resistance and no special clamping during the work process, which is economical and time-saving.

For a long time, the DC motor speed control system has always dominated the high performance requirements of the high speed control, but there are some inherent disadvantages of the DC motor, such as the brush and commutator, which wear out easily and require frequent maintenance.

If the commutator changes direction, sparks are generated, the maximum speed of the motor and the application environment was limited.

In addition, the structure of the DC motor is complicated, it is difficult to manufacture, the consumption of steel materials used is high, and the manufacturing cost is high.

With the same volume, the output power of the AC motor can be increased by 10% - 70% compared to the DC motor.

In addition, the capacity of the AC motor can be larger than that of the DC motor to achieve higher voltage and speed.

Modern CNC machine tools tend to use an AC servo drive, which shows the trend that the AC servo drive has replaced the DC servo drive.

In order to solve the problem of cutting an irregular inclined section or a special intersecting curved surface on any part of the pipeline during the process of a right angle butt joint or an oblique butt joint of the large pipe, a built-in device for cutting irregular portions for the large pipe is used developed, which adopts AC servo drive technology and laser cutting and welding technology to realize the automatic control and setting of the cutting track.

Content of the invention The technical solution for the built-in device for cutting irregular sections for the large pipelines is as follows: It includes the support frame component, translation component,

Rotation component and telescope compensation component. The support frame component includes three telescopic components with the same structure that moves in a straight line! can be. The three telescope components are distributed in a herringbone shape at the same angle in the triangular position of the herringbone support frame component. The three telescope components are firmly connected to one another by the support base 6. The translational component is coaxially connected to the rotational component. The rotational component is firmly connected to the end of the horizontal screw 4 in the translation component. The axis of the rotational component is perpendicular to the axis of the telescope compensation component. The compensation motor stator 24 of the telescope compensation component is firmly connected to the rotary motor rotor 16. The support frame component consists of a support base 6, a motor base 7, a support motor stator 8, a support motor rotor 9, a screw sleeve 10, a flat guide wedge 11, a support screw rod 12 and a locking roller 13.

The support motor stator 8 is firmly connected to the support base 6. The screw sleeve 10 is firmly installed in the center of the support motor rotor 9. The screw sleeve 10 is screwed onto the support screw rod 12. A flat guide wedge 11 is arranged on the support screw rod 12. The end of the support screw rod 12 is provided with a locking roller 13. The support screw rod 12, the screw sleeve 10, the support motor rotor 9 and the support motor stator 8 are installed coaxially. The support base 6 and the motor base 7 have an inner cavity in the axial direction of the support screw rod 12, via which the support screw rod 12 can enter the support base 6. In the inner hole of the support motor end cover 32, there is provided a keyway for through hole that mates with the guide pin 11.

The translation component consists of a flange plate 2, a horizontal guide rod 5, a translation motor rotor 3, a Translattonsmotorstator 29, a translationmotorieitblech 31, a horizontal screw 4 and a horizontal screw sleeve 14. The flange plate 2 is firmly connected to the end of the horizontal screw 4 and on the horizontal guide rod 5 screwed on. The horizontal guide rod 5 is fixed vertically on the side of the support base 6. The horizontal screw sleeve 14 is screwed to the horizontal screw 4. The horizontal screw sleeve 14 is fixedly arranged in the center of the translation motor rotor 3. The translation motor stator 29 is fixed to the translation motor baffle

31 connected.

The horizontal screw 4, the horizontal screw sleeve 14, the translation motor rotor 3, and the translation motor stator 29 are installed coaxially in the center of the support base 6.

The rotary component consists of a guide plate 30, a rotary motor stator 15 and a rotary motor rotor 16. The rotary motor stator 15 is firmly connected to the right end of the horizontal screw 4.

The rotary motor baffle 30 is connected to the horizontal screw 4 through the bearing.

The rotary motor rotor 16 is firmly connected to the rotary motor guide plate 30.

The telescope compensation component consists of compensation motor stator 24, compensation motor rotor 23, right-hand thread screw rod 22, right-hand thread nut 21, right-hand thread sleeve 20, infrared distance sensor 19, laser cutting head 18, left-thread screw rod 25, left-thread nut 26, left-thread sleeve 27 and counterweight 28 .

The compensating motor rotor 23 is connected coaxially to the compensating motor stator 24 and via a bearing to the motor housing.

The right-thread screw rod 22 and the left-thread screw rod 25 are coaxially connected at both ends of the balance motor rotor 23, respectively.

The right-hand thread nut 21 is screwed onto the right-hand thread screw rod 22.

At the same time, the right-hand thread nut 21 is screwed onto the vertical guide rod 17.

The vertical guide rod 17 is firmly connected to the motor housing and runs parallel to the axis of the motor rotor 23. The left-hand thread nut 26 is screwed onto the left-hand thread screw rod 25.

At the same time, the left-hand thread nut 26 is screwed onto the guide rod 17.

The right-hand thread nut 21 is firmly connected to the right-hand thread sleeve 20.

The left-hand thread nut 26 is firmly connected to the left-hand thread sleeve 27.

The right-hand thread sleeve 20 is used to assemble the laser cutting head 19 and the infrared distance sensor 18, while the left-hand thread sleeve 27 is used to assemble the balance weight 28.

The compensation motor is an AC servo motor.

The invention has the following advantageous effect: A built-in device for cutting irregular sections for the large pipelines adopts the manner of direct connection and direct drive of the servo motor and the nut mechanism to realize the support of the frame.

The direct connection and direct drive of the double-headed screw and the servo motor mean that the laser mounting foot and the counterweight are automatically fed and adjusted.

A linear feed in two orthogonal directions is used and a rotational movement is added between two linear feed directions 5 to realize any spatial movement of the laser cutting head submount.

The device has the advantages of compact structure, convenient operation and high work efficiency.

It can cut any non-vertical planar curved portion that is needed, thereby greatly improving the operating efficiency and the cutting efficiency of the pipeline cutter.

Description of the Figures Fig. 1 shows the overall structure of the built-in device for cutting irregular sections for the coarse pipelines.

Fig. 2 shows the working section of the built-in device for cutting irregular sections for the large pipelines in the pipeline.

Specific Embodiment The invention is described in detail below in combination with the accompanying figures: As shown in Fig. 1, a built-in device for cutting irregular sections for the large pipelines comprises a support frame component, a translation component, a rotation component and a telescopic compensation component.

The support frame component comprises three telescopic components with the same structure that can be moved in a straight line.

The three telescope components are distributed in a herringbone shape at the same angle in the triangular position of the herringbone support frame component.

The three telescope components are firmly connected to one another by the support base 6.

The translational component is coaxially connected to the rotational component.

The rotational component is firmly connected to the end of the horizontal screw 4 in the translational component.

The axis of the rotational component is perpendicular to the axis of the telescope compensation component.

The compensating motor stator 24 of the telescopic compensation component is fixed to the

Rotary motor rotor 16 connected. 3E2020 / s016 As shown in Fig. 2, the support frame component consists of a support base 6, a motor base 7, a support motor stator 8, a support motor rotor 9, a screw sleeve 10, a flat guide wedge 11, a support screw rod 12 and a fixed spiral 13. The support motor stator $ is firmly connected to the support base 6.

The screw sleeve 10 is firmly installed in the center of the support motor rotor 9.

The screw sleeve 10 is screwed onto the support screw rod 12.

A flat wedge 11 is arranged on the support screw rod 12.

The end of the support screw rod 12 is provided with a locking roller 13.

The support screw rod 12, the screw sleeve 10, the support motor rotor 9 and the support motor stator 8 are installed coaxially.

The support base 6 and the motor base 7 have an inner cavity in the axial direction of the support screw rod 12, via which the support screw rod 12 can enter the support base 6.

In the inner hole of the support motor end cover 32, a keyway for through-hole that mates with the guide flats 11 is disposed.

Three support motors adopt the same type of AC servo motor.

Working method of the present invention: In the built-in jig for cutting irregular sections for the large-diameter pipelines, insert the device into the Robr pipe, start the three support servomotors of the support frame component, rotate the support screw rod 12 on the inner wall of the pipeline 1, and lock and fix with the locking roller 13, use the locking roller 13 to lock and fix and then start the compensating motor in the telescopic compensating component.

The balance motor rotor 23 drives the right-hand thread screw rod 22 and the left-hand thread screw rod 25 to rotate and adjusts the laser cutting head 18 and balance weight 28 in the correct positions to balance the axial symmetry of the entire device.

During the cutting process, the infrared distance sensor detects the subsequent adaptation of the laser cutting head to the cross-sectional shape of the pipe being cut.

Then start the translation engine of the translation component.

The translation motor rotor 3 drives the horizontal screw sleeve 14 to rotate to give the horizontal screw 4 a side force.

Under the limitation and guidance of the horizontal guide rod 5, it drives the rotation component and the telescopic compensation component in order to realize the shift to the left and right. Start the rotating component of the rotating component, rotate the motor rotor 15, drive the compensating motor, screw rod and laser cutting head 18 to rotate axially, at the same time open the laser cutting head 18, cut the pipeline, and rotate the device for a circle, then a complete irregular section or curved surface can be cut.

Functional principle of the present invention: With the built-in device for cutting irregular sections for the large rough lines, the frame is supported by the direct connection and direct drive of the servo motor and screw nut mechanism. The adjustment of the servo motor makes the support spacing vanabel. The translation motor rotor drives the horizontal screw sleeve to rotate so that the horizontal screw moves horizontally. Adjust the horizontal reciprocating motion of the laser cutting head to realize the cutting of irregular sections or arbitrarily curved cut surfaces. The rotary motor rotor drives the motor to rotate in order to realize the indexable cutting movement of the laser cutting head. The dynamic adjustment between the self-balancing center of rotation and the laser head and the inner wall of the pipeline can be realized by the coaxial fixed connection of the forwards and backwards screw nut pairs and the infrared distance measurement in order to adapt to the different shapes of different shapes of pipeline sections. The direct connection and direct drive of the balance motor and the forward and backward screw nut pairs is used to realize a closed loop control of the setting process to avoid the troublesome setting and positioning of the cutting machine in advance.

Claims (5)

Claims BE2020 / 5016 1. Built-in device for cutting irregular sections for the large pipelines, characterized in that it comprises support frame component, translation component, rotation component and telescope compensation component, the support frame component consists of three linearly movable telescope components with the same structure. The three telescopic components are distributed in a herringbone shape at equal angles in the triangular position of the herringbone support frame component. The three telescope components are firmly connected to one another via a support base (6). The translational component is coaxially connected to the rotational component, and the rotational component is firmly connected to the end of the horizontal screw (4) in the translational component. The axis of the rotation component runs perpendicular to the axis of the telescope compensation component, and the compensation motor stator {24} of the telescope compensation component is firmly connected to the rotary motor rotor (16). 2. Built-in device for cutting irregular sections for the large pipelines according to claim 1, characterized in that the support frame component consists of support base (6), motor base (7) and support motor stator (8), support motor rotor {9}, support motor end cover (32), screw sleeve ( 10), flat wedge {11}, support screw rod (12) and locking roller (13). The support motor stator {8} is firmly connected to the support base (6). The screw sleeve (10) is firmly installed in the center of the motor support rotor (9). The screw sleeve (10) is screwed onto the support screw rod (12). A flat wedge (11) is arranged on the support screw rod (12). The end of the support screw rod (12) ) is provided with a locking roller (13}. The support screw rod (12), the screw sleeve (10), the support motor rotor (9) and the support motor stator (3) are installed coaxially. The support bases (6} and the motor base (7) face in In the axial direction of the support screw rod (12) there is an inner cavity through which the support screw rod (12) can enter the support base (6). In the inner hole of the support motor end cover (32) there is a keyway for a through hole, which leads to the guide flat tube (11 ) fits. 3. Built-in device for cutting irregular sections for the large pipelines according to claim 1, characterized in that the translation component consists of a flange plate (2), a horizontal guide rod (5), a translation motor rotor (3), a translation motor stator (29, a translation motor guide plate ( 31), a horizontal screw (4) and a horizontal screw sleeve (14) The flange plate (2) is fixed to the end of the horizontal Screw (4} connected and screwed onto the horizontal guide rod (5). The horizontal guide rod (5) is fixed vertically on the side of the support base (6). The horizontal screw sleeve (14) is screwed to the horizontal screw (4), The horizontal screw sleeve (14) is fixed in the center of the translation motor rotor (3). The translation motor stator (29) is firmly connected to the translation motor guide plate (31). The horizontal screw (4), the horizontal screw sleeve (14), the translation motor rotor ( 3} and the translation motor stator (29) are installed coaxially in the middle of the support base (6), 4. Built-in device for cutting irregular sections for the large pipe lines according to claim 1, characterized in that the rotation component consists of a guide plate (30), a rotary motor stator (15) and a rotary motor rotor (16). The rotary motor stator (15) is firmly connected to the right end of the horizontal screw (4). The rotary motor guide plate (30) is connected to the horizontal screw (4) through the bearing. The rotary motor rotor (16) is firmly connected to the rotary motor guide plate (30). 5. Built-in device for cutting irregular sections for the large pipelines according to claim 1, characterized in that the telescopic compensation component from compensation motor stator (24), compensation motor rotor (23), right-hand screw rod (22), right-hand thread nut (21), right-hand thread sleeve (20), infrared Distance sensor (19), laser cutting head (18), left-hand thread screw rod (25), left-hand thread nut (26), left-hand thread sleeve (27) and counterweight (28). The compensating motor stator (24) is fixed to the housing of the rotary motor rotor (16). The compensating motor rotor (23) is coaxially connected to the compensating motor stator (24) and is connected to the motor housing via a bearing. The right-hand thread screw rod (22) and the left-hand thread screw rod (25) are each connected coaxially at both ends of the compensating motor rotor (23). The right-hand thread nut (21) is screwed onto the right-hand thread screw rod (22). At the same time, the right-hand thread nut (21) is screwed onto the vertical guide rod (17). The vertical guide rod (17) is firmly connected to the motor housing and runs parallel to the axis of the motor rotor (23). The left-hand thread nut (26) is screwed onto the left-hand thread screw rod (25). At the same time, the left-hand thread nut (26) is screwed onto the guide rod (17). The right-hand screw nut (21) is firmly connected to the right-hand thread sleeve (20). The left-hand thread nut (26) is firmly connected to the left-hand thread sleeve (27). The right-hand thread sleeve (20) is used to mount the laser cutting head (19) and the Infrared distance sensor (18), while the left-hand thread sleeve (27) is used to mount the counterweight (28). The compensation motor is an AC servo motor. 10