JP2013136066A - Arc welding system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an arc welding system by which the breaking of the shape of a bead is suppressible.SOLUTION: The arc welding system includes: a feeding device for sending out a consumable electrode toward a welding torch; a route length changing device for periodically changing a feeding route length which is the length from the feeding device to the welding torch in the axial direction of the consumable electrode, in the consumable electrode; a power source circuit for making a welding current flow between the consumable electrode and a base material; and a feed control circuit for transmitting a feed stop directing signal, for stopping the driving of the feeding device, to the feeding device. The route length changing device reduces the frequency Ff of the feeding route length when the feed stop directing signal is generated at a time t21. Because of such a constitution, it is suppressible that the shape of the bead which is formed at and after the time t21 is broken.

Description

  The present invention relates to an arc welding system.

  As shown in Patent Document 1, there is known an arc welding method in which welding is performed while an arc is generated between a consumable electrode and a base material while supplying the consumable electrode. In this document, the wire feeding device feeds the consumable electrode at a constant speed toward the welding torch. The path length changing device periodically changes the length (feeding path length) from the wire feeding device to the welding torch in the axial direction of the consumable electrode among the consumable electrodes. Thus, welding is performed by repeating a short-circuit period in which the consumable electrode and the base material are short-circuited and an arc generation period in which an arc is generated between the consumable electrode and the base material at a constant cycle. .

Japanese Patent No. 4745453

  When ending the arc welding method described in the document, the supply of the consumable electrode from the wire feeding device is stopped by stopping the driving of the wire feeding device. When the wire feeding device receives a signal for stopping the driving, the driving of the wire feeding device does not stop immediately. That is, the motor of the wire feeder continues to rotate for a while due to inertia. For this reason, when the arc welding method is finished, there is a period in which the feeding path length is periodically changed while the feeding speed of the consumable electrode from the wire feeding device is gradually reduced. If it does so, the repetition period of a short circuit period and an arc generation | occurrence | production period will shift | deviate from the period before the time of receiving the signal for a wire feeder to stop a drive. In such a thing, there exists a possibility that the shape of the bead formed in a base material may collapse.

  The present invention has been conceived under the circumstances described above, and it is a main object of the present invention to provide an arc welding system capable of suppressing the collapse of the bead shape.

  According to the first aspect of the present invention, the length of the feeding device that feeds the consumable electrode toward the welding torch and the length of the consumable electrode from the feeding device to the welding torch in the axial direction of the consumable electrode. A path length changing device for periodically changing a certain feeding path length, a power supply circuit for passing a welding current between the consumable electrode and the base material, and a feed stop instruction for stopping the driving of the feeding device A feed control circuit that sends a signal to the feed device, and the path length changing device reduces the frequency of the feed path length when the feed stop instruction signal is generated. A system is provided.

  Preferably, when it is determined that feeding of the consumable electrode by the feeding device is stopped, the feeding device further includes a feeding stop detection circuit that sends a feeding stop detection signal, and the path length changing device includes the feeding stop detection signal. The frequency is gradually decreased until the time when is generated.

  Preferably, a path length control circuit is further provided that, upon receiving the feed stop detection signal, sends a path length change stop signal for stopping driving of the path length change device to the path length change device.

  Preferably, the power supply circuit applies an anti-stick voltage between the consumable electrode and the base material from the time when the short circuit is resolved and the arc is generated after the feed stop detection signal is generated. Start.

  Preferably, the path length control circuit sends the path length change stop signal to the path length change device after the power supply circuit starts applying the anti-stick voltage.

  Preferably, a calculation circuit for calculating a descent time at which the value of the welding current is lowered is further provided, and the power supply circuit decreases the welding current value to reach the sputter time as the welding current when the descent time is reached. Any of the start of energization of the suppression current, the occurrence of a short circuit between the consumable electrode and the base material, and the occurrence of an arc between the consumable electrode and the base material when the short circuit is eliminated On the other hand, at the time when an arc state change occurs, the energization of the sputtering suppression current is continued.

  According to such a configuration, the repetition period of the short-circuit period and the arc generation period after the time when the feed stop instruction signal is generated is set to the repetition period before the time when the feed stop instruction signal is generated. It can be closer. Therefore, it can suppress that the shape of the bead formed after the time when the above-mentioned feed stop instruction signal was generated collapses.

  Other features and advantages of the present invention will become more apparent from the detailed description given below with reference to the accompanying drawings.

It is a figure which shows the structure of the arc welding system concerning 1st Embodiment of this invention. It is a principal part enlarged view (partially see-through | perspective) of the vicinity of the path | route length change apparatus in the arc welding system shown in FIG. It is an enlarged view which shows only the path | route length change apparatus of FIG. It is a figure which shows the change state of the cam mechanism of the path | route length change apparatus of FIG. It is a principal part expanded sectional view which shows typically the state by which the path | route length change apparatus was fixed to the welding torch and the conduit cable. It is a figure which shows typically the supply path | route length of a consumable electrode. It is a block diagram which shows the detail of the robot control apparatus and power supply device in the arc welding system of FIG. It is a timing chart which shows each signal etc. in the steady welding state of the arc welding method of a 1st embodiment of the present invention. It is a timing chart which shows each signal etc. at the time of the end of welding of the arc welding method of a 1st embodiment of the present invention.

[About arc welding system A1]
An arc welding system A1 shown in FIG. 1 includes a welding robot 1, a robot control device 2, and a power supply device 3.

  The welding robot 1 automatically performs, for example, arc welding on the base material W. The welding robot 1 includes a base member 11, a plurality of arms 12, a plurality of motors 13, a welding torch 14, a feeding device 16, a path length changing device 17, and a conduit cable 19.

  The base member 11 is fixed to an appropriate location such as a floor. Each arm 12 is connected to the base member 11 via a shaft.

  The welding torch 14 is provided at the distal end portion of the arm 12 a provided on the most distal end side of the welding robot 1. The welding torch 14 guides the consumable electrode 15 to a predetermined position in the vicinity of the base material W. As schematically shown in FIG. 5, the welding torch 14 has a contact tip 141 and a nozzle 142. The contact chip 141 is made of, for example, Cu or Cu alloy. The contact chip 141 is provided with a through hole for inserting the consumable electrode 15. The through hole has a size such that the inner surface rubs against the consumable electrode 15. The nozzle 142 is made of, for example, Cu or a Cu alloy. The nozzle 142 has a water cooling structure as appropriate. An opening 143 is formed in the nozzle 142. A shield gas SG such as Ar is supplied between the nozzle 142 and the contact chip 141. The supplied shield gas SG is ejected from the opening 143. The consumable electrode 15 is fed into the shield gas SG.

  The motor 13 is provided at both ends or one end of the arm 12 (partially omitted from illustration). The motor 13 is rotationally driven by the robot control device 2. By this rotational drive, the movement of the plurality of arms 12 is controlled, and the welding torch 14 can move freely up and down, front and rear, and left and right. The motor 13 is provided with an encoder (not shown). The output of this encoder is given to the robot controller 2. Based on this output value, the robot controller 2 recognizes the current position of the welding torch 14.

  The feeding device 16 is provided in the upper part of the welding robot 1. The feeding device 16 is for feeding the consumable electrode 15 to the welding torch 14. The feeding device 16 includes a feeding motor 161 (see FIG. 1) and a push device 162 (see FIG. 6). The feed motor 161 drives the push device 162. The push device 162 feeds the consumable electrode 15 wound around the wire reel WL (see FIG. 6) to the welding torch 14 using the feed motor 161 as a drive source.

  The conduit cable 19 is used to insert the consumable electrode 15 and guide the consumable electrode 15 from the feeding device 16 to the welding torch 14. As clearly shown in FIG. 1, the conduit cable 19 has a curved portion in the middle portion from the feeding device 16 to the welding torch 14. As schematically shown in FIG. 5, the conduit cable 19 includes a coil liner 191 and a covering tube 192.

  The coil liner 191 is formed, for example, by forming a metal wire into a coil shape. The consumable electrode 15 is inserted through the coil liner 191. As described above, the conduit cable 19 has a curved portion. Therefore, the consumable electrode 15 is fed while being rubbed against the inner wall of the coil liner 191 at the curved portion. The covering tube 192 has a tube shape. The covering tube 192 is made of, for example, chlorinated polyethylene (CPE). The covering tube 192 surrounds the coil liner 191. Since the conduit cable 19 has a curved portion as described above, the covering tube 192 rubs against the coil liner 191 at the curved portion.

  The path length changing device 17 shown in FIGS. 1 to 3 changes the feeding path length La (see FIG. 6). The feed path length La refers to the length of the consumable electrode 15 from the push device 162 to the welding torch 14 in the axial direction of the consumable electrode 15. In the present embodiment, the path length changing device 17 includes a motor 171, an eccentric shaft 172, a cam mechanism 173, bearings 174 a and 174 b, a mount 175, a bush 176, and a shaft 177.

  As shown in FIG. 2, the motor 171 is fixed to the welding torch 14. That is, the motor 171 does not move relative to the welding torch 14. The motor 171 drives the path length changing device 17. The motor 171 uses a shaft extending in the left-right direction in FIG. An encoder (not shown) is attached to the motor 171. The eccentric shaft 172 is fixed to the rotating shaft of the motor 171. The eccentric shaft 172 is provided with a bolt at a position eccentric with respect to the rotation axis of the motor 171. The cam mechanism 173 is a drive cam, and two holes are formed in the cam mechanism 173 (see FIG. 4). The cam mechanism 173 is connected to the bolt of the eccentric shaft 172 via a bearing 174a provided in one of these two holes. The mount 175 is connected to the cam mechanism 173 via a bearing 174b provided in the other of the two holes. The mount 175 is connected to the shaft 177 via the bush 176. The shaft 177 is fixed to the main body of the motor 171. The mount 175 can move in the vertical direction of FIG. 2 along the shaft 177. As shown in FIG. 5, the mount 175 is fixed to the coil liner 191 of the conduit cable 19.

  When the motor 171 rotates, the bolt of the eccentric shaft 172 rotates eccentrically. Then, according to the eccentric rotation, as shown in FIG. 4, the cam mechanism 173 performs a series of operations from (K1) to (K4). As shown in FIG. 3, the mount 175 reciprocates along the shaft 177. As a result, the conduit cable 19 (in this embodiment, the coil liner 191) reciprocates slightly up and down in FIG. As the coil liner 191 reciprocates, the consumable electrode 15 that rubs against the coil liner 191 reciprocates. The reciprocating motion of the coil liner 191 changes the feeding path length La. The path length changing device 17 sends a rotation angle signal Sθ relating to the rotation angle θ (t) of the motor 171 to a current control circuit 32 described later. When the cam mechanism 173 is in the state shown in FIG. 4 (K1), the rotation angle θ (t) = 0 (rad). When the cam mechanism 173 is in the state shown in FIG. 10K2, the rotation angle θ (t) = π / 2 (rad). When the cam mechanism 173 is in the state shown in the figure (K3), the rotation angle θ (t) = π (rad). When the cam mechanism 173 is in the state shown in FIG. 4K4, the rotation angle θ (t) = 3π / 2 (rad).

  FIG. 7 is a block diagram showing details of the robot control device 2 and the power supply device 3 in the arc welding system A1 of FIG.

  The robot control device 2 includes an operation control circuit 21 and a teach pendant 23. The robot control device 2 is for controlling the operation of the welding robot 1.

  The operation control circuit 21 has a microcomputer and a memory (not shown). The memory stores a work program in which various operations of the welding robot 1 are set. Further, the operation control circuit 21 sets a robot moving speed VR described later. The operation control circuit 21 sends an operation control signal Ms to the welding robot 1 based on the work program, the coordinate information from the encoder, the robot moving speed VR, and the like. The welding robot 1 receives the operation control signal Ms and rotates each motor 13. As a result, the welding torch 14 moves to a predetermined welding start position in the base material W or moves along the in-plane direction of the base material W.

  The operation control circuit 21 has an end determination circuit 211. When determining that the welding should be ended, the end determination circuit 211 sends a welding end instruction signal Ws. The reason why the end determination circuit 211 determines that welding should be ended is based on, for example, that the welding torch 14 has reached a predetermined end position of the base material W or that a predetermined time has elapsed since the start of welding. Alternatively, the determination by the end determination circuit 211 that welding should be ended may be based on the input from the user to end welding to the following teach pendant 23.

  The teach pendant 23 is connected to the operation control circuit 21. The teach pendant 23 is for the user of the arc welding system A1 to set various operations.

  The power supply device 3 includes a power supply circuit 31, a current control circuit 32, a voltage control circuit 33, a calculation circuit 35, a feed control circuit 36, a path length control circuit 37, a feed stop detection circuit 38, a current A value storage unit 39. The power supply device 3 is a device for applying the welding voltage Vw between the consumable electrode 15 and the base material W and causing the welding current Iw to flow, and for supplying the consumable electrode 15.

  The power supply circuit 31 includes a power generation circuit MC, a power supply characteristic switching circuit SW, a current error calculation circuit EI, a voltage error calculation circuit EV, a current detection circuit ID, and a voltage detection circuit VD. The power supply circuit 31 applies a welding voltage Vw with a value instructed between the consumable electrode 15 and the base material W, and allows a welding current Iw to flow with a value instructed from the consumable electrode 15 to the base material W. Is.

  The power generation circuit MC receives, for example, a commercial power supply such as a three-phase 200V as input, performs output control such as inverter control and thyristor phase control according to an error signal Ea described later, and outputs a welding voltage Vw and a welding current Iw.

  The current detection circuit ID is for detecting the value of the welding current Iw flowing between the consumable electrode 15 and the base material W. The current detection circuit ID sends a current detection signal Id corresponding to the welding current Iw. The current error calculation circuit EI is for calculating a difference ΔIw between the value of the welding current Iw that is actually flowing and the set value of the welding current. Specifically, the current error calculation circuit EI receives a current detection signal Id and a current setting signal Ir described later corresponding to the set welding current value, and sends a current error signal Ei corresponding to the difference ΔIw. The current error calculation circuit EI may send a current error signal Ei corresponding to a value obtained by amplifying the difference ΔIw.

  The voltage detection circuit VD is for detecting the value of the welding voltage Vw applied between the consumable electrode 15 and the base material W. The voltage detection circuit VD sends a voltage detection signal Vd corresponding to the welding voltage Vw. The voltage error calculation circuit EV is for calculating a difference ΔVw between the value of the welding voltage Vw actually applied and the value of the set welding voltage. Specifically, the voltage error calculation circuit EV receives a voltage detection signal Vd and a voltage setting signal Vr described later corresponding to the set welding voltage value, and sends a voltage error signal Ev corresponding to the difference ΔVw. The voltage error calculation circuit EV may send a voltage error signal Ev corresponding to a value obtained by amplifying the difference ΔVw.

  The power supply characteristic switching circuit SW switches the power supply characteristic (constant current characteristic or constant voltage characteristic) of the power supply circuit 31. When the power supply characteristic of the power supply circuit 31 is a constant current characteristic, the output is controlled in the power supply circuit 31 so that the value of the welding current Iw becomes a set value. On the other hand, when the power supply characteristic of the power supply circuit 31 is a constant voltage characteristic, the output of the power supply circuit 31 is controlled so that the value of the welding voltage Vw becomes a set value. More specifically, the power supply characteristic switching circuit SW receives a power supply characteristic switching signal Sw described later, a current error signal Ei, and a voltage error signal Ev. When the power supply characteristic switching signal Sw received by the power supply characteristic switching circuit SW is at a high level, the switch in the power supply characteristic switching circuit SW is connected to the a side in FIG. In this case, the power supply characteristic of the power supply circuit 31 is a constant voltage characteristic, and the power supply characteristic switching circuit SW sends the voltage error signal Ev to the power generation circuit MC as the error signal Ea. At this time, the power generation circuit MC performs control such that the value of the welding voltage Vw becomes a set value (that is, the above difference ΔVw becomes zero). On the other hand, when the power supply characteristic switching signal Sw received by the power supply characteristic switching circuit SW is at the low level, the switch in the power supply characteristic switching circuit SW is connected to the b side in FIG. In this case, the power supply characteristic of the power supply circuit 31 is a constant current characteristic, and the power supply characteristic switching circuit SW sends the current error signal Ei to the power generation circuit MC as the error signal Ea. At this time, the power generation circuit MC performs control such that the value of the welding current Iw becomes a set value (that is, the above-described difference ΔIw becomes zero).

  The current value storage unit 39 stores the value of the sputtering suppression current value ir1. The sputtering suppression current value ir1 is input from the teach pendant 23, for example, and stored in the current value storage unit 39 via the operation control circuit 21.

  The current control circuit 32 is for setting the value of the welding current Iw flowing between the consumable electrode 15 and the base material W. The current control circuit 32 generates a current setting signal Ir for indicating the value of the welding current Iw based on the sputtering suppression current value ir1 stored in the current value storage unit 39. Then, the current control circuit 32 sends the generated current setting signal Ir to the power supply circuit 31.

  The voltage control circuit 33 is for setting the value of the welding voltage Vw applied between the consumable electrode 15 and the base material W. The voltage control circuit 33 sends a voltage setting signal Vr for instructing the value of the welding voltage Vw to the power supply circuit 31 based on the setting voltage value stored in a storage unit (not shown).

  The calculation circuit 35 calculates a descent time td1 (see FIG. 8) at which the value of the welding current Iw is lowered. The calculation circuit 35 includes an arc state detection circuit 351, a calculation circuit 352, and a set time storage unit 353.

  The set time storage unit 353 stores the value of the set time Tb. The value of the set time Tb is input from the teach pendant 23, for example, and stored in the set time storage unit 353 via the operation control circuit 21.

  The arc state detection circuit 351 detects whether the arc a1 between the consumable electrode 15 and the base material W is generated or disappears. In the present embodiment, the arc state detection circuit 351 receives the voltage detection signal Vd. The arc state detection circuit 351 determines whether or not the arc a1 is generated based on the value of the welding voltage Vw. The arc state detection circuit 351 determines that the arc a1 is extinguished when the welding voltage Vw is below a certain threshold value. The arc state detection circuit 351 determines that the arc a1 is generated when the welding voltage Vw exceeds the threshold value.

  When the arc state detection circuit 351 detects the arc state change Ch1 (see FIG. 8), the arc state change detection signal As1 is sent to the calculation circuit 352. The arc state change Ch1 is one of the occurrence of a short circuit between the consumable electrode 15 and the base material W and the occurrence of an arc a1 between the consumable electrode 15 and the base material W when the short circuit is eliminated. is there. In the present embodiment, the arc state change Ch1 is that the short circuit is eliminated and the arc a1 is generated between the consumable electrode 15 and the base material W.

  Calculation circuit 352 receives arc state change detection signal As1, rotation angle signal Sθ, and welding end instruction signal Ws. The calculation circuit 352 obtains the above descent time td1. In the present embodiment, the calculation circuit 352 calculates the descent time td1 based on the arc state change detection signal As1, the rotation angle signal Sθ, and the set time Tb stored in the set time storage unit 353. The step of calculating the descent time td1 by the calculation circuit 352 will be described later. When reaching the descent time td1, the calculation circuit 352 switches the power supply characteristic switching signal Sw sent to the power supply circuit 31 (specifically, the power supply characteristic switching circuit SW) from the High level to the Low level. Thereby, the power supply characteristic of the power supply circuit 31 is switched from the constant voltage characteristic to the constant current characteristic.

  The feed control circuit 36 is for controlling the speed (feed speed Vf) at which the feed device 16 sends out the consumable electrode 15. The feeding control circuit 36 sends a feeding speed control signal Fc for instructing the feeding speed Vf to the feeding device 16.

  The path length control circuit 37 is for controlling the value of the above-described feeding path length La. In the present embodiment, the path length control circuit 37 sends the rotation speed signal Wc to the path length changing device 17. The rotation speed signal Wc indicates the rotation speed dθ (t) / dt of the motor 171 in the path length changing device 17.

  The feed stop detection circuit 38 generates a feed stop detection signal Sst when detecting that the feed of the consumable electrode 15 by the feeding device 16 is stopped. The feed stop detection circuit 38 sends the generated feed stop detection signal Sst to the path length control circuit 37.

[Arc welding method using arc welding system A1]
Next, an arc welding method using the arc welding system A1 will be described with reference to FIGS. FIG. 8 is a timing chart showing each signal and the like in the steady welding state of the arc welding method of the present embodiment.

  8A shows the rotation angle θ (t) of the motor 171, FIG. 8B shows the amount of change V1 (t) of the feed path length La, and FIG. 8C shows the part surrounded by the welding torch 14 (Ra in FIG. 5). ) Of the consumable electrode 15 relative to the base material W from the welding torch 14 to the base material W, (d) is the welding voltage Vw, (e) is the current setting signal Ir, and (f) is the welding. Currents Iw and (g) indicate the change state of the power supply characteristic switching signal Sw. Note that the amount of change V1 (t), speed V2 (t), feed speed Vf, and the like is positive in the direction from the welding torch 14 toward the base material W. The speed V2 (t) is the same as the speed of the portion of the consumable electrode 15 at the tip of the welding torch 14.

In the steady welding state of the present embodiment, the path length control circuit 37 sends a rotation speed signal Wc for instructing the rotation speed dθ (t) / dt of the motor 171 to a constant value 2π / T _W to the path length changing device 17. Send (T _W is, for example, 10 to 20 ms). Thus, the motor 171 is rotated at a rotational speed dθ (t) / dt value 2π / T _W. The rotation angle θ (t) of the motor 171 shown in FIG. 8A is represented by the following equation (1).

θ (t) = (2π / T _w ) · (t− (n−1) T _w )
((N−1) T _w ≦ t <nT _w ) (n is an integer) (1)

As shown in FIG. 8A, when the motor 171 rotates, the change amount V1 (t) of the feed path length La changes as shown in FIG. 8B. The change amount V1 (t) is expressed by the following equation (2).

V1 (t) = Va · cos (θ (t)) (2)

In the equation (2), Va is an amplitude and is a constant value. Thus, the change amount V1 (t) changes periodically.

On the other hand, in the steady welding state of the present embodiment, the feed control circuit 36 sends a feed speed control signal Fc for instructing the feed speed Vf to the feed device 16. For this reason, the consumable electrode 15 is fed from the feeding device 16 toward the welding torch 14 at a feeding speed Vf. Therefore, as shown in FIG. 8C, the speed V2 (t) of the portion surrounded by the welding torch 14 (Ra in FIG. 5) is obtained by adding the above-described change amount V1 (t) and the feeding speed Vf. Will be. That is, the speed V2 (t) is expressed by the following equation (3).

V2 (t) = Vf + Va · cos (θ (t)) (3)

As shown in FIG. 8 (c), the steady welding state in this embodiment, the consumable electrode 15, so that the speed V2 (t) is a periodic function of the one period of the unit period T _W, fed . Actually, according to the equations (1) and (3), the relationship of V2 (t + T _w ) = V2 (t) is satisfied. The unit period Tw is a constant. The unit period _Tw is composed of a forward feed period T _{W1 in} which the speed V2 (t) is a positive value and a reverse feed period T _{W2 in} which the speed V2 (t) is a negative value. In the forward feeding period T _W 1, the speed V2 (t) is a positive value, so the consumable electrode 15 is in a state of being fed from the welding torch 14 (a state of being fed forward). On the other hand, in the reverse feed period T _W 2, the speed V2 (t) is a negative value, so the consumable electrode 15 is in a state of being pulled up from the welding torch 14 (in a reverse feed state).

As described above, in the steady welding state of the present embodiment, the consumable electrode 15 is fed so that the speed V2 (t) becomes a periodic function of a constant period regardless of changes in the values of the welding current Iw and the welding voltage Vw. Be paid. Then, in a state where the consumable electrode 15 is fed in this way, an arc a1 is generated between the consumable electrode 15 and the base material W and a short circuit period Ts in which the consumable electrode 15 and the base material W are short-circuited. The arc generation period Ta is repeated. At some point in each forward feed period T _W 1, the consumable electrode 15 is short-circuited to the base material W. Thereby, the short circuit period Ts starts. Further, at a certain point in each backward feeding period T _W 2, the consumable electrode 15 is separated from the base material W, and the short-circuit state between the consumable electrode 15 and the base material W is released. Thereby, the arc generation period Ta starts. Hereinafter, the process from the start of welding will be specifically described.

  First, at the start of welding, a welding start signal St (not shown) for starting welding is input to the teach pendant 23 with the welding torch 14 and the base material W separated to some extent. The input welding start signal St is sent from the teach pendant 23 to the calculation circuit 35, the path length control circuit 37, and the feed control circuit 36 via the operation control circuit 21. Then, the feeding control circuit 36 sends a feeding speed control signal Fc to the feeding device 16, the path length control circuit 37 sends a rotation speed signal Wc to the path length changing device 17, and the consumable electrode 15 is shown in FIG. It is fed at a speed V2 (t) shown in c). Next, the welding torch 14 is moved closer to the base material W to shift to a steady welding state in which the short circuit period Ts and the arc generation period Ta are repeatedly generated. In the steady welding state, the welding torch 14 moves at the robot moving speed VR along the welding progress direction in the in-plane direction of the base material W while keeping the distance from the base material W constant.

(1) Arc generation period Ta (time t0 to time t3)
The arc generation period Ta is a period for generating the arc a1 and heating the base material W. As shown in FIG. 8G, the power supply characteristic switching signal Sw is at a high level in almost the entire arc generation period Ta (time t1 to time t3). Therefore, from time t1 to time t3, the power supply characteristic of the power supply circuit 31 is a constant voltage characteristic. Further, as shown in FIG. 10C, at time t2, the state is changed from the state where the consumable electrode 15 is fed backward to the state where it is fed forward.

(2) Short-circuit period Ts (time t3 to time t5)
<Time t3—Descent time td1>
The short-circuit period Ts is a period for bringing the tip of the consumable electrode 15 into contact with the base material W and transferring a part of the consumable electrode 15 to the base material W. When the consumable electrode 15 is fed forward, the consumable electrode 15 and the base material W come into contact with each other and the consumable electrode 15 and the base material W are short-circuited at time t3. When the consumable electrode 15 and the base material W are short-circuited, as shown in FIG. 8D, the value of the welding voltage Vw rapidly decreases at time t3. From time t3 to descent time td1, the consumable electrode 15 is melted by Joule heat, and the contact area between the consumable electrode 15 and the base material W gradually increases. As a result, the resistance value with respect to the welding current Iw flowing from the consumable electrode 15 to the base material W becomes small, and the value of the welding current Iw gradually increases as shown in FIG. As shown in FIG. 8C, the consumable electrode 15 is fed forward from time t3 to descent time td1. However, from time t3 to descent time td1, the consumable electrode 15 is less likely to buckle because it is melted and softened as described above.

<Descent time td1 to time t5>
As shown in FIG. 8G, the calculation circuit 352 of the calculation circuit 35 changes the power supply characteristic switching signal Sw from High level to Low level at the drop time td1. Thereby, the power supply characteristic of the power supply circuit 31 changes to a constant current characteristic. On the other hand, as shown in FIG. 5E, the current control circuit 32 generates a current setting signal Ir for energizing the welding current Iw with a relatively small sputtering suppression current value ir1 in the power supply circuit 31 (in this embodiment, Current error calculation circuit EI). Therefore, as shown in FIG. 6F, when the descent time td1 is reached, the value of the welding current Iw drops to the spatter suppression current value ir1, and the sputter suppression current Iw1 flows as the welding current Iw. A method for determining the descent time td1 will be described later. Then, as shown in FIG. 3C, at time t4, the state where the consumable electrode 15 is fed forward is changed to the state where it is fed backward.

(3) Arc generation period Ta (time t5)
At time t5, the consumable electrode 15 and the base material W are separated from each other, and an arc a1 is generated. That is, the arc state change Ch1 described above (the short circuit is eliminated and the arc a1 is generated between the consumable electrode 15 and the base material W) occurs. At the time t5, that is, the time when the arc state change Ch1 occurs, the energization of the sputtering suppression current Iw1 is continued. Since the current value of the sputter suppression current Iw1 is a relatively small sputter suppression current value ir1, the occurrence of spatter that may occur when the arc a1 is generated can be suppressed. When the short circuit between the consumable electrode 15 and the base material W is eliminated, as shown in FIG. 8D, the value of the welding voltage Vw rapidly increases at time t5. Based on the increase in the value of the welding voltage Vw, the arc state detection circuit 351 detects the arc state change Ch1 and sends an arc state change detection signal As1 to the calculation circuit 352. The calculation circuit 352 changes the power supply characteristic switching signal Sw from the Low level to the High level at time tu1 after receiving the arc state change detection signal As1. Thereby, the power supply characteristic of the power supply circuit 31 changes to a constant voltage characteristic. Then, as shown in FIG. 5F, the value of the welding current Iw rises to a value sufficient to heat the base material W, and the same process as described above is performed again.

  The descending time td1 is obtained by the calculation circuit 352 in the calculation circuit 35. An example of a method for determining the descent time td1 is as follows.

  First, the calculation circuit 352, based on the change time information regarding the change time (in this embodiment, time t0) when the arc state change Ch1 occurs, the predicted time (in this embodiment) that the arc state change Ch1 occurs after the time t0. Predictive information regarding time t5) is obtained. The change time information includes, for example, values of the time t0 when the arc state change Ch1 occurs, the rotation angle θ (t) at the time t0, the change amount V1 (t) at the time t0, and the speed V2 (t) at the time t0. Etc. In the present embodiment, the change time information is the rotation angle θ (t) at time t0. Similarly, the prediction information includes, for example, the time t5 when the arc state change Ch1 occurs, the rotation angle θ (t) at the time t5, the change amount V1 (t) at the time t5, and the speed V2 (t) at the time t5. Such as value. In the present embodiment, the prediction information is the rotation angle θ (t) at time t5. That is, calculation circuit 352 receives arc state change detection signal As1 from arc state detection circuit 351 when the short circuit is eliminated and arc a1 is generated at time t0. Then, based on the rotation angle signal Sθ sent from the path length changing device 17, the calculation circuit 352 recognizes that the rotation angle θ (t) at time t0, which is information at the time of change, is θ3. In the present embodiment, the speed V2 (t) changes periodically. Therefore, the calculation circuit 352 predicts that the rotation angle θ (t) (prediction information) at the time when the arc state change Ch1 occurs again is θ3.

  Next, the calculation circuit 352 predicts that the time when the arc state change Ch1 occurs after the time t0 is the time t5 based on the prediction that the rotation angle θ (t) as the prediction information is θ3. Then, the calculation circuit 352 determines the time before the set time Tb from the time t5 as the descent time td1. The set time Tb is, for example, 100 to 500 μs.

  Next, the end method of the arc welding method using arc welding system A1 is demonstrated further using FIG. FIG. 9 is a timing chart showing signals and the like at the end of welding in the arc welding method of the present embodiment. The time scale of FIG. 9 is smaller than the time scale of FIG. FIGS. 8A to 8G are the same as the signals in FIGS. 8A to 8G, respectively. FIG. 9 (h) shows a change state of the welding end instruction signal Ws, and FIG. 9 (i) shows a change state of the frequency Ff of the feed path length La. The frequency Ff of the feed path length La is expressed as (dθ (t) / dt) / 2π using the rotation angle θ (t) described above.

  At time t21, the end determination circuit 211 determines that welding should be ended, and generates a welding end instruction signal Ws as shown in FIG. 9 (h). At any time from time t21 to time t5 after generation of the welding end instruction signal Ws, the movement of the welding torch 14 in the welding progress direction stops. The welding end instruction signal Ws is sent to the calculation circuit 352 in the calculation circuit 35, the feed control circuit 36, and the path length control circuit 37. When the feed control circuit 36 receives the welding end instruction signal Ws, the feed control circuit 36 stops the driving of the feed device 16 (a feed speed control signal Fc for setting the feed speed Vf to 0, the feed speed of the present invention). A feed stop instruction signal) is sent to the feeding device 16. Thereby, as shown in FIG.9 (c), the feed speed Vf of the consumable electrode 15 reduces gradually. At time t22, the supply of the consumable electrode 15 is stopped. In addition, at time t21 when the feeding device 16 receives a signal for stopping driving, feeding of the consumable electrode 15 by the feeding device 16 does not stop immediately, and at time t22 slightly after time t21. The supply of the consumable electrode 15 is stopped because the feed motor 161 continues to rotate for a while from time t21 due to inertia. The time from time t21 to time t22 when the feeding of the consumable electrode 15 by the feeding device 16 stops depends on the performance of the feeding motor 161, and is about 50 to 100 msec in this embodiment.

  When receiving the welding end instruction signal Ws at time t <b> 21, the path length control circuit 37 sends a rotation speed signal Wc for decreasing the rotation speed dθ (t) / dt of the motor 171 to the path length changing device 17. As a result, the rotational speed dθ (t) / dt of the motor 171 gradually decreases. When the rotational speed dθ (t) / dt of the motor 171 is gradually decreased, the frequency Ff of the feed path length La is gradually decreased as shown in FIG. 9 (i). Thus, the path length changing device 17 is a signal for stopping the driving of the feeding device 16 (a feeding speed control signal Fc for setting the feeding speed Vf to 0, a feeding stop instruction signal of the present invention). Is generated, the frequency Ff of the feeding path length La is decreased.

  When the feed stop detection circuit 38 determines that the feed of the consumable electrode 15 by the feed device 16 is stopped at time t22, the feed stop detection signal Sst is generated (not shown in FIG. 9). The feed stop detection circuit 38 determines that the feed of the consumable electrode 15 by the feed device 16 has stopped when the rotation speed of the feed motor 161 becomes smaller than a certain value. The generated feed stop detection signal Sst is sent to the path length control circuit 37.

  At time t22, the path length control circuit 37 receives the feed stop detection signal Sst. In the present embodiment, the path length control circuit 37 changes the rotation speed signal Wc for reducing the rotation speed dθ (t) / dt of the motor 171 until the time t22 at which the feed stop detection signal Sst is received. It is sent to the device 17. Therefore, the rotational speed dθ (t) / dt of the motor 171 gradually decreases until time t22 when the feed stop detection signal Sst is generated. That is, as shown in FIG. 9 (i), the frequency Ff of the feeding path length La gradually decreases until time t22. In this way, the path length changing device 17 gradually decreases the frequency Ff of the feed path length La until time t22 when the feed stop detection signal Sst is generated.

  The rate of change (inclination) per unit time of the frequency Ff of the feeding path length La from time t21 to time t22 may be obtained in advance by experiments. Furthermore, the rate of change per unit time of the frequency Ff of the feed path length La may be appropriately changed for each welding method in accordance with the value of the feed speed Vf before time t21.

  In the present embodiment, as shown in FIG. 9 (i), after time t22, the frequency Ff of the feed path length La is increased to the value at time t21. Unlike the present embodiment, after the time t22, the frequency Ff of the feeding path length La may be maintained below the value at the time t22 without increasing to the value at the time t21.

  At time t5 in FIG. 9, the short circuit between the consumable electrode 15 and the base material W is eliminated, and the arc a1 is generated. Then, as shown in FIG. 4D, the power supply circuit 31 starts applying the anti-stick voltage Vwa between the consumable electrode 15 and the base material W. That is, after the supply stop detection signal Sst is generated, the power supply circuit 31 starts applying the anti-stick voltage Vwa from time t5 when the short circuit is eliminated and the arc a1 is generated. Application of the anti-stick voltage Vwa continues for the anti-stick time Tta. When the anti-stick time Tta elapses from time t5, the power supply circuit 31 stops output. As a result, as shown in FIGS. 9D and 9F, the welding voltage Vw and the welding current Iw become zero.

  On the other hand, the path length control circuit 37 generates a signal (rotation speed dθ (t) / dt) for stopping driving of the path length changing device 17 after time t5 when the power supply circuit 31 starts to apply the anti-stick voltage Vwa. A signal for setting to 0, which corresponds to an example of a path length change stop signal of the present invention) is sent to the path length changing device 17. As a result, the driving of the path length changing device 17 is stopped, and the rotational speed dθ (t) / dt becomes zero. That is, as shown in FIG. 9 (i), the frequency Ff of the feeding path length La becomes zero.

  The effect of this embodiment is demonstrated.

  In the present embodiment, the path length changing device 17 is a signal for stopping the driving of the feeding device 16 (a feeding speed control signal Fc for setting the feeding speed Vf to 0, a feeding stop instruction of the present invention). When the signal) is generated, the frequency Ff of the feed path length La is decreased. According to such a configuration, even if the feed speed Vf of the consumable electrode 15 decreases after time t21, as shown in FIG. 9D, the short-circuit period Ts and the arc generation period Ta after time t21. The repetition period can be made closer to the repetition period before time t21. Therefore, it can suppress that the shape of the bead formed after time t21 collapses.

  The arc welding system A1 according to the present embodiment includes a path length control circuit 37. When the path length control circuit 37 receives the feed stop detection signal Sst, the path length control circuit 37 sends a signal for stopping the driving of the path length changing device 17 to the path length changing device 17. According to such a configuration, even if the responsive motor 161 in the feeding device 16 is not very responsive, the driving of the path length changing device 17 is stopped until the feeding speed Vf becomes almost zero. I won't let you. Therefore, the short-circuit period Ts and the arc generation period Ta can be reliably repeated until the feed speed Vf becomes substantially zero.

  In the present embodiment, the power supply circuit 31 detects the anti-stick voltage Vwa between the consumable electrode 15 and the base material W from the time when the short circuit is eliminated and the arc a1 is generated after the supply stop detection signal Sst is generated. Starts to be applied. According to such a configuration, application of the anti-stick voltage Vwa can be started after the supply of the consumable electrode 15 is substantially stopped. Therefore, after the application of the anti-stick voltage Vwa is finished and the output from the power supply circuit 31 is stopped, the consumable electrode 15 can be prevented from plunging into the base material W or the molten pool formed in the base material W.

  In the present embodiment, the path length control circuit 37 receives a signal (rotation speed dθ (t) / dt for stopping driving of the path length changing device 17 after the power supply circuit 31 starts applying the anti-stick voltage Vwa. To the path length changing device 17 is sent to the path length changing device 17. According to such a configuration, the change in the feeding path length La is not stopped until the application of the anti-stick voltage Vwa is started. Therefore, the arc generation period Ta and the short-circuit period Ts can be repeated until the application of the anti-stick voltage Vwa is started. Thereby, the application of the anti-stick voltage Vwa can be started more reliably from the time when the arc a1 is generated. If the application of the anti-stick voltage Vwa can be started from the time when the arc a1 is generated, the size of the molten particles formed at the tip of the consumable electrode 15 at the end of welding can be set to a desired size. If the size of the molten grains formed at the tip of the consumable electrode 15 at the end of welding can be set to a desired size, it is possible to stabilize the arc start in the next welding.

  In the present embodiment, as described above, the repetition period of the short-circuit period Ts and the arc generation period Ta after time t21 can be made closer to the repetition period before time t21. Therefore, after time t21, before the arc state change Ch1 (in this embodiment, the short circuit is eliminated and the arc a1 is generated between the consumable electrode 15 and the base material W), the value of the welding current Iw is set. It is possible to reliably lower and start energization of the sputtering suppression current Iw1. Thus, after time t21, the spatter suppression current Iw1 can be reliably energized at the time when the arc state change Ch1 occurs, and the spatter that can occur at the time when the arc state change Ch1 occurs can be suppressed. it can.

  The present invention is not limited to the embodiment described above. The specific configuration of each part of the present invention can be changed in various ways. It is not always necessary to lower the welding current before a short circuit occurs or before an arc occurs. When the configuration in which the welding current is reduced before the occurrence of the short circuit or the arc is not employed, the power supply device 3 may not include the calculation circuit 35. In the above-described embodiment, the arc state change Ch1 has been described as the fact that the short circuit is eliminated and the arc a1 is generated between the consumable electrode 15 and the base material W, but the present invention is not limited to this. The arc state change Ch1 may be a short circuit between the consumable electrode 15 and the base material W. That is, a configuration in which the welding current is reduced immediately before the occurrence of a short circuit may be employed. Moreover, you may employ | adopt the structure which drops a welding current in any before immediately before arc generation and short circuit occurrence.

A1 Arc welding system 1 Welding robot 11 Base member 12 Arm 12a Arm 13 Motor 14 Welding torch 141 Contact tip 142 Nozzle 143 Opening 15 Consumable electrode 16 Feed device 161 Feed motor 162 Push device 17 Path length changing device 171 Motor 172 Eccentricity Shaft 173 Cam mechanism 174a Bearing 174b Bearing 175 Mount 176 Bush 177 Shaft 19 Conduit cable 191 Coil liner 192 Covered tube 2 Robot control device 21 Operation control circuit 211 Termination judgment circuit 23 Teach pendant 3 Power supply device 31 Power supply circuit 32 Current control circuit 33 Voltage Control circuit 35 Calculation circuit 351 Arc state detection circuit 352 Calculation circuit 353 Set time storage unit 36 Feed control circuit 37 Path length control circuit 38 Feed stop Detection circuit 39 Current value storage unit a1 Arc As1 Arc state change detection signal Ch1 Arc state change Ea Error signal EI Current error calculation circuit Ei Current error signal EV Voltage error calculation circuit Ev Voltage error signal Fc Feed speed control signal Ff Frequency ID Current Detection circuit Id Current detection signal Ir Current setting signal ir1 Spatter suppression current value Iw Welding current Iw1 Spatter suppression current La Feed path length MC Power generation circuit Ms Operation control signal SG Shield gas Sst Feed stop detection signal SW Power supply characteristic switching circuit Sw Power characteristic switching signal Sθ Rotation angle signal Ta Arc generation period Tb Setting time Ts Short-circuiting period Tta Anti-stick time V1 (t) Change amount V2 (t) Speed VD Voltage detection circuit Vd Voltage detection signal Vf Feeding speed VR Robot movement speed Vr Voltage setting signal Vw Welding voltage Vwa An Stick voltage W matrix Wc rotational speed signal WL wire reel Ws welding end instruction signal theta (t) rotation angle

Claims (6)

A feeding device for feeding the consumable electrode toward the welding torch;
Among the consumable electrodes, a path length changing device that periodically changes a feeding path length that is a length from the feeding device to the welding torch in the axial direction of the consumable electrode;
A power supply circuit for passing a welding current between the consumable electrode and the base material;
A feed control circuit for sending a feed stop instruction signal for stopping the drive of the feed device to the feed device;
The path length changing device is an arc welding system that reduces the frequency of the feed path length when the feed stop instruction signal is generated. When it is determined that the feeding of the consumable electrode by the feeding device is stopped, a feeding stop detection circuit that sends a feeding stop detection signal is further provided,
The arc welding system according to claim 1, wherein the path length changing device gradually decreases the frequency until the time when the feed stop detection signal is generated.   The path length control circuit according to claim 2, further comprising: a path length control circuit that sends a path length change stop signal for stopping driving of the path length change device to the path length change device when receiving the feed stop detection signal. Arc welding system.   The power supply circuit starts applying an anti-stick voltage between the consumable electrode and the base material from the time when the short circuit is resolved and the arc is generated after the supply stop detection signal is generated. The arc welding system according to claim 3.   5. The arc welding system according to claim 4, wherein the path length control circuit sends the path length change stop signal to the path length change device after the power supply circuit starts applying the anti-stick voltage. 6. A calculation circuit for calculating a descent time for reducing the value of the welding current;
The power circuit is
When the descent time is reached, by lowering the value of the welding current, energization of the sputter suppression current is started as the welding current, and
The time when the arc state change occurs, which is one of the occurrence of a short circuit between the consumable electrode and the base material, and the occurrence of an arc between the consumable electrode and the base material when the short circuit is eliminated. The arc welding system according to claim 1, wherein energization of the sputter suppression current is continued.

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