KR101263685B1 - Continuous orbital welding device for welding pipe with turnning roller and the method thereof - Google Patents

Abstract

The present invention relates to a pipe continuous orbital welding apparatus and a method using a turning roller that can continuously perform welding in the bottom view position when performing pipe welding,
The orbital welding apparatus includes a turning roller unit 110 for rotating the welding target pipe P, and an opposite direction at the same speed as the rotational speed of the turning roller unit 110 at the outer circumference of the welding target pipe P. A welding mechanism unit 120 which is transferred to and performs welding along the welding line of the pipe to be welded; and a welding controller 130 which controls movement and welding conditions of the welding mechanism portion; and a power source for welding to the welding mechanism portion. It is configured to include; welding power supply unit 140 for supplying
As the pipe welding can be performed by only the following view, there is no deflection phenomenon that can occur in the electric field welding, so the welding power (current) can be increased, and thus, the maximum wire feed rate and the welding speed can be applied, so that the multi-layer pipe It maximizes the welding productivity of welding, enables high-performance welding where the precision of welding robot should be maintained at 0.5mm or less like GTAW, and minimizes the heat affected zone of the weld to minimize the change of weld property. It provides an effect that significantly improves.

Description

Pipe continuous orbital welding device using turning roller and its method {CONTINUOUS ORBITAL WELDING DEVICE FOR WELDING PIPE WITH TURNNING ROLLER AND THE METHOD THEREOF}

The present invention relates to a pipe continuous orbital welding apparatus and a method using a turning roller that can continuously perform welding in the bottom view position when performing the pipe welding.

In general, in the case of onshore and offshore pipe welding, pipes must be connected by direct welding at the site where the characteristics are to be installed. An orbital welding apparatus capable of welding while rotating part is provided.

1 shows an orbital welding apparatus having a transfer carriage 200 and a welding machine 1 disclosed in Korean Laid-Open Patent Publication No. 2002-0072917.

The orbital welding apparatus of the prior art as shown in Figure 1 is a welding torch (6) when the transport carriage 200 travels the outer peripheral surface of the pipe under the control of the control box 52 after mounting the welding machine (1) on the transport carriage (200) Is used to perform welding along the weld line, which is the junction of the two pipes (A, B).

The orbital welding apparatus of the above-described configuration can easily perform the welding on the pipe exterior easily without the troublesome work such as rotating the pipe, thereby significantly improving the pipe welding work speed and reducing the fatigue of the operator. To provide an effect.

However, in the case of the orbital welding apparatus, the transport carriage 200 is transferred along the outer circumference of the pipe to perform welding, so when the bottom surface of the pipe is welded, the welding posture becomes difficult to perform the welding.

In this case, after stopping the welding, there is a problem in that the troublesome welding work that needs to be performed by moving the carriage to the position of the bottom view posture occurs.

This hassle in welding work causes the time delay in the case of the electric field welding, which requires the multi-layer welding, to increase with the number of welding layers, which causes a significant decrease in the productivity of the welding work.

Therefore, the present invention is to solve the problems of the prior art described above, to perform a multi-layer welding continuously without interrupting the welding operation in the welding on the outer peripheral surface of the pipe using a welder mounted on the orbital carriage. An object of the present invention is to provide a pipe continuous orbital welding apparatus using a turning roller and a method thereof.

Pipe continuous orbital welding apparatus (hereinafter, referred to as "orbital welding apparatus") using the turning roller of the present invention for achieving the above object, a turning roller unit 110 for rotating the pipe to be welded (P); and, A welding mechanism part 120 that is transferred in the opposite direction at the same speed as the rotational speed of the turning roller part 110 at the outer circumference of the welding object pipe P and performs welding along the welding line of the welding object pipe; And a welding control unit 130 for controlling the movement and welding conditions of the welding mechanism unit, and a welding power supply unit 140 for supplying power for welding to the welding mechanism unit.

The welding mechanism part 120 may include a guide rail R installed at an outer circumference of the pipe P in parallel with the welding line L of the pipe to be welded, and a carriage to be transported along the guide rail R. C); and, a welding torch unit 123 mounted on the carriage C to perform welding on the welding line L; and a welding line mounted at the front end of the welding torch unit 123 in the welding direction. A welding line detection unit 121 to detect; and a temperature sensor unit mounted at a rear end of the welding torch unit 123 in the welding direction to detect a temperature of the welding portion; and a welding direction of the welding torch unit 123 in the welding direction. It is characterized in that it comprises a; cooling unit 124 is mounted to the rear end to cool the welding portion.

The temperature sensor unit, the first temperature sensor unit 123 mounted to the front end of the cooling unit 124 at the rear end of the welding direction of the welding torch unit 123 in order to control the heat input of the welding torch unit 123. And, the second temperature sensor unit 125 is mounted to the rear end of the cooling unit 124 to control the cooling function of the cooling unit 124 to measure the temperature of the welding portion; Characterized in that it comprises one or more of.

The welding control unit 130, the welding line tracking unit 131 for generating a welding line tracking signal after receiving and analyzing the detection signal of the welding line detection unit 121; and the welding line tracking signal of the welding line tracking unit 131 Transfer control of the carriage C and arc generation control according to the temperature detection signal of the temperature sensor unit, movement of the welding torch and power control according to the welding conditions stored therein, heat input control of the welding torch and cooling of the welding part Weld mechanism control unit 132 for outputting a welding control signal including one or more of the control; and a control panel unit 133 for receiving a user control command for welding control; characterized in that it comprises a.

The heat input control measures the temperature of the welded part after the set reference time has elapsed after the start of welding, and sets the reference temperature. When the value has a predetermined ratio or more than the temperature, the current is increased by a predetermined value. When the value has a predetermined ratio or less than the reference temperature, the current is lowered by the predetermined value.

The heat input control is also set to the reference temperature by measuring the temperature of the welded part after the set reference time has elapsed after the start of welding, and by measuring the temperature repeatedly at a predetermined time interval after the measurement of the reference temperature is measured In the range of a certain ratio including the reference temperature is characterized in that it is configured to further perform the control to pause the temperature control.

The welding mechanism control unit 132 may include a welding condition database storing the welding conditions for each pipe welding pass and the welding mechanism control conditions as data.

The welding power supply unit 140 may include an interface unit 143 that receives a welding control signal from the welding control unit 130 and a current control signal included in the welding control signal input through the interface unit 143. It characterized in that it comprises a; power supply unit 141 for controlling the power applied to the welding torch unit 123.

Pipe continuous orbital welding method (hereinafter referred to as' orbital welding method) using the turning roller of the present invention for achieving the above object, a turning roller unit 110 for rotating the welding target pipe (P); and, A welding mechanism part 120 that is transferred in the opposite direction at the same speed as the rotational speed of the turning roller part 110 at the outer circumference of the welding object pipe P and performs welding along the welding line of the welding object pipe; A welding control part 130 including a welding line tracking unit 131 and a welding mechanism part control unit 132 for controlling the movement and welding conditions of the welding mechanism part; and a welding power supply part for supplying power for welding to the welding mechanism part. In the orbital welding method for performing orbital welding on a pipe, the welding conditions and welding control stored in the welding mechanism control unit 132 by the welding mechanism control unit 132 When the welding is started according to the signal, the welding mechanism control unit 132 of the turning roller unit 110 with the carriage (C) of the welding mechanism 120 having the rotational speed of the turning roller 110 Synchronizing the traveling speed (S10) for driving in the opposite direction of the rotation direction; and the welding mechanism unit control unit 132 by the welding mechanism unit 120 using the temperature information on the welding unit detected by the welding mechanism unit 120 Welding part cooling process (S20) for performing the cooling to the welding portion by controlling the; and the welding mechanism portion control unit 132 by the welding mechanism portion control unit 132 by using the temperature information of the welding portion detected by the welding mechanism portion 120 Characterized in that it comprises a; heat input control process (S30) for adjusting the intensity of the arc generated in the welding torch unit 123 of (120).

In the orbital welding method, the welding mechanism part control unit 132 rotates the turning roller part 110 while performing welding including the welding part cooling step S20 and the heat input control step S30. Determining whether the one-time welding (1 pass) of the pipe is terminated by detecting the detection, and if the one-time welding is not finished, the welding including the cooling of the welding part (S20) and the heat input control process (S30) is continuously performed. Pass passage determination process (S40) to; and, as a result of the determination of the pass passage determination process (S40) by the welding mechanism control unit 132, when the one-time dedicated welding of the pipe is finished, the welding mechanism control unit 132 In order to perform the multi-layer welding under the control of), the welding condition and the welding mechanism control condition for the next pass are detected from the welding condition database stored in the welding mechanism control unit 132 to perform welding for another pass. The welding condition changing process (S60); characterized by further comprising a.

The heat input control process (S30), under the control of the welding mechanism control unit 132 measures the temperature of the welding site after the reference time set after the welding mechanism 120 starts welding, the welding mechanism control A reference temperature measurement process (S31) of setting the temperature of the welded portion detected by the unit 132 as a reference temperature; and the welding mechanism 120 according to the control of the welding mechanism control unit 132 after the measurement of the reference temperature. A unit temperature measuring process (S32) for repeatedly measuring a temperature at a predetermined time interval; and the temperature measured by the welding mechanism control unit 132 in the unit temperature measuring process (S32) is constant than the reference temperature. When the value is greater than the ratio, the welding power supply 140 to control the current to increase the current by a predetermined value, when the value is less than a predetermined ratio than the reference temperature to lower the current by a predetermined value Control process (S33); including characterized in that formed.

In the heat input amount control process (S30), the welding mechanism part 120 measures the temperature of the welding portion repeatedly at predetermined time intervals after the measurement of the reference temperature by the welding mechanism part control unit 132. For example, a temperature control stop process (not shown) for temporarily stopping temperature control when the measured temperature is within a range of a predetermined ratio including a reference temperature may be further included.

In the present invention described above, the welding conditions include the welding current and voltage supplied to the welding torch for welding, the carriage running speed of the carriage for the transfer of the welding torch, the wire feeding speed condition of the wire for welding supplied to the welding torch, The welding mechanism control conditions include a weaving width and weaving speed for the weaving driving including the center position of the welding torch, the oblique line and the linear running of the welding torch, and the change of the dwell time, which is the stop time of the welding torch.

According to the present invention having the above-described configuration, when welding a pipe by using an orbital welding apparatus, the pipe welding can be performed only by the following view, so that there is no sag phenomenon that can occur in the electromagnetic wave welding, thereby increasing the welding power (current). In this way, the wire feed amount and the welding speed of the maximum speed can be applied, thereby providing an effect of significantly improving welding productivity.

The present invention also provides the effect of maximizing the welding productivity of multi-layer pipe welding using an orbital welding device because the whole pass can be performed without stopping during multi-layer welding.

In addition, the present invention, when rotating the pipe using a turning roller and a general robot such as an orthogonal robot or a six-axis robot to perform a GTAW welding of less than 0.5mm precision, the rotation axis of the turning roller and the center axis of the pipe It should be aligned correctly, and the robot and the turning roller should be installed without any deviation. In reality, however, it is impossible to install without any deviation. Therefore, the operator had to continuously observe and manually adjust the left and right of the torch. However, in the present invention, since the welding robot is directly installed in the pipe, the robot moves together even when the pipe moves left and right, up and down, so that the position of the welding line and the robot can be precisely controlled. This provides the effect of performing high performance welding, such as GTAW, in which the precision of the welding robot should be maintained at 0.5 mm or less.

In addition, in the present invention, since the welding robot is always located at the top of the pipe, it is easy to visually observe the welding currently performed by the operator compared to the position of the robot when welding the electric pipe, and thus, the welding line tracking sensor and the temperature sensor Even when no automatic equipment is attached, it is possible to perform welding line tracking and heat input control in real time, thereby significantly improving welding quality.

1 is a side view of an orbital welding apparatus having a transport carriage 200 and a welding machine 1 disclosed in Korean Laid-Open Patent Publication No. 2002-0072917,
2 is a plan view of the orbital welding apparatus 10 according to an embodiment of the present invention,
Figure 3 is a flow chart showing the processing of the welding method using the orbital welding apparatus 10 of the present invention,
4 is a flowchart illustrating a detailed process of the heat input control process (S30) of the process of FIG.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings showing embodiments of the present invention.

2 is a front view of the orbital welding apparatus 100 according to the embodiment of the present invention.

As shown in FIG. 2, the orbital welding apparatus 100 includes a turning roller 110, a welding mechanism 120, a welding control unit 130, and a welding power supply 140.

The turning roller 110 is coupled to the welding target pipe (P) is configured to rotate the pipe (P) at a constant speed. In this case, the pipe rotational speed of the turning roller 110 is performed by the turning roller control speed control data for each welding pass of the pipe of the welding condition database stored in the welding mechanism control unit 132.

The welding mechanism 120 is a welding condition of the welding condition database stored in the welding mechanism control unit 132 and the welding current and voltage, welding running speed, wire feeding speed conditions, the center position of the welding torch, weaving width , Conveying the carriage (C) according to the conditions, such as changing the weaving speed, the dwell time, adjust the size of the arc by the welding torch, and move the position of the welding torch, by the cooling control unit 124 And perform full welding, such as performing cooling to the weld.

In order to perform the function, the welding mechanism part 120 includes a guide rail R, a carriage C, a welding torch unit 123, a welding line detection unit 121, a temperature sensor unit, and the like as shown in FIG. It is configured to include a cooling unit (124).

The guide rail (R) is installed on the outer periphery of the pipe in parallel with the weld line (L) of the pipe (P) is configured to induce the movement of the carriage (C).

The carriage C is movably mounted to the guide rail R, and according to the control command of the welding mechanism control unit 132, the outer edge of the pipe P according to the pipe rotation speed of the turning roller 110. It is configured to rotate in the direction opposite to the rotational direction of the turning roller 110 with the same speed as the circumferential movement speed of one point. Therefore, when located at the apex of the pipe (P) of the carriage (C), while welding is in progress, the carriage (C) is always located at the apex of the pipe (P) to weld the bottom view along the weld line (L) of the pipe (P) Will be able to perform

The welding line detection unit 121 is mounted on the side of the carriage (C) so as to be located above the welding line (L), the guide rail by the relative movement of the pipe (P) and the carriage (C) during the welding process ( The welding torch is located on the welding line L during the movement of the carriage C on the R), and is configured to output the detected signal to the welding line tracking unit 131 of the welding control unit 130. . The welding line detection unit 121 and the welding line tracking unit 131 is a "welding line tracking device having an eccentric cylindrical reflection mirror" of the Republic of Korea Patent Publication No. 1998-037902, the "electromagnetic sensor of the Republic of Korea Patent Publication No. 2006-0114566 Welding line tracking device "," Laser Vision Sensor for Welding Seam Tracking "of Korean Patent Publication No. 2007-2466," Welding Carrier of Welding Line Automatic Tracking and Welding Condition Adaptive Control Method "of Korean Patent Publication No. 2002-35186 As described above, various welding line tracking devices such as an electromagnetic sensor, an eccentric cylindrical reflection mirror, and a laser vision system may be applied.

The welding torch unit 123 is mounted on the side of the carriage (C) so as to be located on the welding line (L) at the rear end of the welding line detection unit 121 is moved in accordance with the movement of the carriage (C) for the welding line (L) Configured to perform welding.

The temperature sensor unit includes a first temperature sensor unit 123 mounted at the rear end of the welding torch unit 123 and a second temperature sensor unit 125 mounted at the rear end of the cooling unit 124.

In the temperature sensor unit of the above configuration, the first temperature sensor unit 123 is mounted at a position for measuring the temperature of the welded portion in which the welding torch unit 123 performs welding from the welding torch unit 123 after a predetermined time. The first temperature sensor unit 123 mounted as described above detects the temperature of the welded portion after a predetermined time has passed after welding is performed, and the detected welded temperature controls the heat input amount of the welding torch unit 123. It is used as data for

The second temperature sensor unit 125 is located at the rear end of the cooling unit 124 and detects the temperature of the welded portion cooled by the cooling unit 124 and outputs the detected temperature to the welding mechanism control unit 132. And control the cooling function by 124.

The cooling unit 124 is located at the rear end of the first temperature sensor unit 123 to cool the weld, thereby minimizing the change in the physical properties of the weld due to the high temperature of the arc to optimize according to the preset welding conditions and welding mechanism control conditions Allow welding to be performed.

Welding to the welded portion by the cooling unit 124 described above is such that the nozzles for spraying the cooling fluid are arranged in the longitudinal direction of the weld line, in a direction perpendicular to the weld line, or arranged to form a polygonal region including the weld line. It can be configured to perform welding at a time on an area disposed in various ways.

Next, the welding control unit 130 is configured to control the entire welding control process by the orbital welding apparatus 100 including a welding line tracking unit 131, a welding mechanism control unit 132 and a control panel unit 133. do.

To this end, the welding line tracking unit 131 analyzes the welding line information detected by the welding line detection unit 121, and then determines whether the welding torch of the welding torch unit 123 is located at a position for each pass on the welding line. When out of the position is configured to output a signal for correcting the position of the welding torch to the welding mechanism control unit 132.

The welding mechanism control unit 132 has a welding database for storing welding conditions and welding mechanism control conditions for welding therein to control the entire process of orbital welding. Specifically, the welding condition includes a welding current and voltage, a carriage running speed, a wire feeding speed condition, and the welding mechanism control condition includes a weaving width of the weaving driving including a central position of the welding torch, a straight line and a diagonal running of the welding torch. , Conditions such as changing the weaving speed and the dwell time, which is the stop time of the welding torch.

The above-described welding mechanism control unit 132 controls the traveling speed of the carriage C, the weaving of the welding torch, the weaving speed control, the heat input control, the change of the dwell tine, etc. using the data of the welding condition database described above. After generating the signal is configured to output it to the welding power supply 140 and the welding mechanism 120.

In addition, the welding mechanism control unit 132 measures a predetermined time (20 seconds in the case of the embodiment of the present invention) after welding of the welding part when the initial welding is performed using the detected temperature of the first temperature sensor unit 123. After setting to the reference temperature by measuring the temperature of the welding unit at a predetermined unit time interval (1 second in the embodiment of the present invention) during the process of welding proceeds to the current applied to the welding torch when out of a certain temperature range around the reference temperature To control the heat input.

In addition, the welding mechanism control unit 132 uses the detected temperature of the second temperature sensor unit 125 to control the cooling function of the cooling unit 124 to maintain the lowest temperature at which the change in the physical properties of the weld is the smallest. The signal is output to the welding mechanism unit 120.

The control panel unit 133 is provided with an input unit such as a key input unit and a display or a plurality of instrument panels or status indicator lamps to enable a user to change welding conditions or welding mechanism control conditions, and to control welding conditions during welding. It is configured to be grasped.

Next, the welding power supply unit 140 includes a power unit 141 and an interface unit 143.

The welding power supply unit 140 converts into a welding current after receiving external power and receives a heat input control signal for heat input control of the welding mechanism control unit 132 to perform heat generation appropriate for the heat input control signal. It is configured to vary the output to the welding torch unit 123 and at the same time to control the welding wire feed rate of the welding wire feeder.

The interface unit 143 is configured to provide a communication interface between the welding control unit 130 and the welding power supply 140. In other words, the interface unit 143 includes a connection port and a communication protocol.

3 is a flow chart showing the processing of the welding method using the orbital welding apparatus 10 of the present invention, Figure 4 is a flow chart showing the detailed processing of the heat input control process (S30) of the processing of FIG.

Hereinafter, a process of the orbital welding method of the present invention will be described with reference to FIGS. 2 to 4.

As shown in Figure 3, the orbital welding method of the present invention is a driving speed synchronization process (S10), welding part cooling process (S20), heat input control process (S30), pass elapsed judgment process (S40), welding end process ( S50) is made.

In detail, when the welding to the pipe is started, the welding controller 130 rotates the turning roller 110 set for each pipe and the turning roller 110 of the carriage C on the guide rail R. The driving speed synchronization process (S10) is performed to match the traveling speed so that the moving speed in the opposite direction of rotation of the same is the same. At this time, the above-described welding condition and the welding mechanism control condition are data for each pipe, and are pre-stored in the welding ball control unit 132 as a welding condition database. The welding conditions and welding mechanism control conditions described above also include data for each pass when performing multi-layer welding on a pipe.

After the traveling speed synchronization process S10 is performed, the turning roller 110 rotates the pipe P according to the welding condition and the welding mechanism control condition, and at the same time, the carriage C rotates the outer periphery of the pipe P. The welding is performed by traveling along the guide rail R so as to be always positioned at the apex of the pipe P in the phase.

In the process of performing such welding, the welding part cooling process S20 for cooling the welded part welded by the welding torch unit 123 and the heat input control process for controlling the amount of heat input by the welding torch are performed at the same time.

The welding part cooling process S20 is performed to lower the temperature of the welding part detected by the second temperature sensor unit 125 to a predetermined temperature, and the preset temperature is a temperature at which metal of the pipe does not cause a change in physical properties by temperature. In the multi-pass, the weld is cooled to perform optimally after the first pass.

And the heat input control process (S30) is to control the arc generation by the welding torch unit 123 and the temperature for the welding portion, by the welding torch unit 123 detected by the first temperature sensor unit 123 After the welding is performed, the amount of heat input is controlled by controlling the amount of current and gas applied to the welding torch based on the temperature data of the welding portion after a predetermined time has elapsed.

4 illustrates a specific process of the heat input control process (S30), and the heat input control process (S30) will be described below with reference to FIG. 4.

After a predetermined time has elapsed (20 seconds in the embodiment of the present invention) with respect to the welding portion where the welding is performed by the first temperature sensor unit 120 of the welding mechanism portion 120, the welding mechanism portion control unit ( 132 performs a reference temperature measurement process (S31) of setting the detected temperature as the reference temperature.

Thereafter, the welding mechanism control unit 132 controls the welding mechanism unit 120 to measure the temperature of the welding unit at unit time intervals (1 second in the embodiment of the present invention) after the welding is performed (S32). ).

Next, the welding mechanism control unit 132 compares the temperature of the weld detected by the unit temperature measurement process S32 every time the unit is elapsed with the reference temperature, and the temperature measured in the unit temperature measurement process S32 is determined based on the reference temperature. When the value has a predetermined ratio or more than the temperature, the current is increased by a predetermined value, and when the value is lower than the reference temperature by a predetermined value, the current control process (S33) is performed for controlling the heat input amount by lowering the current by the predetermined value.

As an example of the current control process (S33) by the welding mechanism control unit 132, when the temperature measured in the unit temperature measurement process (S32) has a value (eg 10%) or more than the reference temperature. When the current is increased by a predetermined value (eg 1A) and has a value lower than a reference temperature (eg 10%) below the reference temperature, the current may be lowered by a predetermined value (eg 1A).

The heat input control process (S30) by the welding mechanism control unit 132 is repeatedly executed until the welding is finished.

In addition, during the above-described welding process, the welding mechanism control unit 132 determines whether one rotation welding (one pass) of the pipe P is performed by using the pipe rotation speed of the turning roller 110 and performs one rotation welding. If this is not performed, the pass elapsed determination process S40 is performed to determine whether the one pass welding is performed by continuing the welding including the welding part cooling process S20 and the heat input control process S30.

In addition, the welding mechanism control unit 132 performs the welding termination determination process (S50) to determine whether the welding is completed when the one pass welding is performed as a result of the pass passage determination process (S40).

In the welding termination determination process (S50), when the welding is completed by one pass welding, the welding is terminated, and when the multi-pass welding is required, it is determined whether all the set pass procedures are completed. If the multi-pass welding process is not completed, the welding conditions including welding current and voltage, carriage speed and wire feeding speed conditions, the center position of the welding torch and the welding torch are used for welding for the next welding pass. Welding condition changing process for changing welding machine part control conditions including conditions such as changing the weaving width and the weaving speed and the dwell time (stop time) of weaving driving including diagonal driving and linear driving ( After performing S60), the welding part cooling process (S20), the heat input control process (S30), the pass passage determination process (S40), the welding end process (S50), and the welding condition are changed according to the corresponding welding condition and the welding part control condition. The process S60 is repeatedly performed until the welding of the multilayer path is completed.

delete

100: orbital welding device, P: pipe, L: welding line
110: turning roller part
120: welding mechanism portion, 121: welding line detection unit, 122: welding torch unit
123: first temperature sensor, 124: cooling unit, 125: second temperature sensor, R: guide rail
130: welding control unit, 131: welding line tracking unit, 132: welding mechanism control unit
133: control panel unit
140: welding power supply unit, 141: message unit, 143: interface unit

Claims (13)

Turning roller unit 110 for rotating the welding target pipe (P); And,
A welding mechanism part 120 that is transferred in the opposite direction at the same speed as the rotational speed of the turning roller part 110 at the outer circumference of the welding object pipe P and performs welding along the welding line of the welding object pipe;
Welding control unit 130 for controlling the movement and welding conditions of the welding mechanism; And,
Orbital welding apparatus characterized in that it comprises a; welding power supply unit 140 for supplying power for welding to the welding mechanism. The method according to claim 1, The welding mechanism 120,
A guide rail (R) installed at an outer circumference of the pipe (P) in parallel with the welding line (L) of the pipe to be welded;
Carriage (C) for transporting along the guide rail (R); And,
A welding torch unit 123 mounted on the carriage C to perform welding on the welding line L;
A welding line detection unit 121 mounted at a front end of the welding torch unit 123 in a welding direction to detect a welding line;
A temperature sensor unit mounted at a rear end of the welding torch unit 123 in a welding direction to detect a temperature of a welding part;
Orbital welding apparatus characterized in that it comprises a; is mounted on the rear end of the welding torch unit 123 in the welding direction to cool the welding unit (124). The method according to claim 2, wherein the temperature sensor unit,
A first temperature sensor unit 123 mounted at the front end of the cooling unit 124 at the rear end of the welding torch unit 123 in the welding direction for controlling the heat input of the welding torch unit 123; and
A second temperature sensor unit 125 mounted to a rear end of the cooling unit 124 to control a cooling function of the cooling unit 124 and measuring a temperature of a welding part;
Orbital welding apparatus characterized in that it comprises one or more of. The method of claim 2, wherein the welding control unit 130
A welding line tracking unit 131 which receives and analyzes a detection signal of the welding line detection unit 121 and generates a welding line tracking signal;
Feeding control of the carriage C according to the welding line tracking signal of the welding line tracking unit 131, arc generation control according to the temperature detection signal of the temperature sensor unit and movement of the welding torch and power control according to the welding conditions stored therein; A welding mechanism part control unit 132 for outputting a welding control signal including at least one of heat input control of the welding torch and cooling control of the welding part;
Orbital welding apparatus characterized in that it comprises a; control panel unit 133 for receiving a user control command for welding control. The method according to claim 4, wherein the heat input control,
Measure the temperature of the welded part after the set reference time has elapsed since the start of welding and set it as the reference temperature.After measuring the reference temperature, the temperature is measured repeatedly according to the preset time interval. In the case of having an orbital welding device, characterized in that to increase the current by a predetermined value, and to lower the current by a predetermined value when having a value below a certain ratio than the reference temperature. The method according to claim 5, wherein the heat input control,
Measure the temperature of the welded part after the set reference time has elapsed since the start of welding and set it as the reference temperature, and measure the temperature repeatedly according to the preset time interval after measuring the reference temperature Orbital welding apparatus, characterized in that configured to further perform the control to pause the temperature control when in the range of. The method of claim 4,
The welding mechanism control unit (132) is an orbital welding apparatus, characterized in that it comprises a welding condition database that stores the welding conditions for each pipe welding pass and the welding mechanism control conditions as data. The method according to claim 1, The welding power supply unit 140,
An interface unit 143 which receives a welding control signal from the welding control unit 130;
Orbital for controlling the power applied to the welding torch unit 123 according to the current control signal included in the welding control signal input through the interface unit 143; Welding equipment. A turning roller unit 110 for rotating the welding target pipe P; and the welding roller being transferred in the opposite direction at the same speed as the rotational speed of the turning roller 110 at the outer periphery of the welding target pipe P; Welding mechanism unit 120 for performing welding along the welding line of the target pipe; Welding control unit including a welding line tracking unit 131 and a welding mechanism control unit 132 for controlling the movement and welding conditions of the welding mechanism ( 130); And, in the orbital welding method for performing an orbital welding to the pipe, including; welding power supply unit 140 for supplying power for welding to the welding mechanism portion,
When the welding is started according to the welding condition and the welding control signal stored in the welding mechanism part control unit 132 by the welding mechanism part control unit 132, the welding mechanism part control unit 132 of the welding mechanism part 120 Running speed synchronization process (S10) for driving the carriage (C) in the direction opposite to the rotation direction of the turning roller 110 with the rotational speed of the turning roller 110; And,
A welding part cooling process (S20) in which the welding mechanism part control unit 132 controls the welding mechanism part 120 to perform cooling of the welding part by using temperature information on the welding part detected by the welding mechanism part 120; and,
The mouth of the welding mechanism control unit 132 adjusts the intensity of the arc generated in the welding torch unit 123 of the welding mechanism 120 using the temperature information of the welding portion detected by the welding mechanism 120. Orbital welding method comprising a; calorie control process (S30); The method according to claim 9,
During the welding including the welding part cooling process S20 and the heat input control process S30,
The welding mechanism control unit 132 detects the rotation of the turning roller unit 110 to determine whether the one-time welding (one pass) of the pipe is finished, and if the one-time welding is not finished, the welding part cooling process ( S20) and the pass elapsed determination process (S40) for continuing the welding including the heat input control process (S30); And,
As a result of the determination of the passage passage determining process (S40) by the welding mechanism control unit 132, when the single-use welding of the pipe is finished, the welding mechanism unit control unit 132 performs a multi-layer welding process according to the control. And a welding condition changing step (S60) of performing welding for another pass by detecting a welding condition for the pass and a welding mechanism part control condition from the welding condition database stored in the welding mechanism part control unit 132. Orbital welding method. The method according to claim 9, wherein the heat input control process (S30),
According to the control of the welding mechanism control unit 132, the welding mechanism 120 measures the temperature of the welding site after the set reference time has elapsed after the start of welding, and the welding mechanism control unit 132 detects the temperature of the welding site. A reference temperature measurement process (S31) of setting the temperature as the reference temperature; and,
A unit temperature measurement process (S32) of repeatedly measuring the temperature at a predetermined time interval by the welding mechanism unit 120 under the control of the welding mechanism control unit 132 after the measurement of the reference temperature;
When the welding mechanism control unit 132 has a temperature measured in the unit temperature measuring process S32 has a value greater than or equal to the reference temperature, the welding power supply unit 140 controls the welding power supply 140 to preset a current for welding. And a current control step (S33) of increasing the value and lowering the current by a predetermined value when the value is lower than the reference temperature by a predetermined ratio. The method according to claim 11, wherein the heat input control process (S30),
Under the control of the welding mechanism control unit 132, the welding mechanism 120 repeatedly measures the temperature of the welded portion at predetermined time intervals after the measurement of the reference temperature, so that the measured temperature includes the reference temperature. Orbital welding method characterized in that it further comprises; temperature control stop process (not shown) to temporarily stop the temperature control in the range of the ratio. The method of claim 10,
The welding conditions include the welding current and voltage supplied to the welding torch for welding, the carriage running speed of the carriage for conveying the welding torch, and the wire feeding speed condition of the wire for welding supplied to the welding torch,
The welding mechanism control condition includes a change condition of the weaving width and the weaving speed for the weaving driving including the center position of the welding torch, the oblique line and the linear running of the welding torch, and the dwell time which is the stop time of the welding torch. Orbital welding method characterized in that.

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