JPWO2017110065A1 - Welding equipment - Google Patents

Abstract

The welding apparatus according to the present disclosure includes a remote controller connected to a welding power source, a common connection path portion having a common signal line that connects the welding power source and the remote controller. The control unit in the welding power source includes an analog signal processing unit and a reception signal processing unit. When an analog signal is input from the remote control to the analog signal processing unit via the common signal line, the analog signal processing unit outputs a digital signal to the welding output unit in accordance with the analog signal. When a digital signal is input from the remote control to the reception signal processing unit via the common signal line, the reception signal processing unit outputs the digital signal to the welding output unit according to the input digital signal.

Description

  The present disclosure relates to a welding apparatus in which a remote controller (hereinafter referred to as a remote controller) is electrically connected to a welding power source.

  An analog signal type remote controller (hereinafter referred to as an analog remote controller) is used as one method for remotely operating a welding machine as a welding power source. An analog remote controller is connected to the welding machine, and by operating several analog volumes installed on the analog remote controller, it is possible to remotely give welding current and welding voltage commands to the welding machine (for example, patents) Described in reference 1).

JP 60-64773 A

  A welding apparatus according to the present disclosure includes a welding power source including a filter unit, a control unit, and a welding output unit, a first remote controller or a second remote controller connected to the welding power source, and the welding power source. And a common connection path section having a common signal line for directly or indirectly connecting the first remote controller or the second remote controller. The filter unit removes noise from a signal input from the common signal line, and outputs the signal from which noise has been removed to the control unit. The control unit includes an A / D conversion unit. An analog signal is input to the analog signal processing unit from the first remote controller via the common signal line and the filter unit, the analog signal processing unit Outputs a first digital signal to the welding output unit in response to the analog signal, and sends a second digital signal from the second remote controller to the reception signal processing unit via the common signal line and the filter unit. Is input, the reception signal processing unit outputs a third digital signal to the welding output unit in accordance with the second digital signal.

The block diagram of the welding apparatus in Embodiment 1 of this indication The block diagram of the welding apparatus in Embodiment 1 of this indication The block diagram of the welding apparatus in the modification of Embodiment 1 of this indication The block diagram of the welding apparatus in the modification of Embodiment 1 of this indication Block diagram of a welding apparatus according to Embodiment 2 of the present disclosure Schematic of a welding apparatus according to Embodiment 2 of the present disclosure

  Prior to the description of the embodiments of the present disclosure, problems in the conventional apparatus will be briefly described.

  In the above-described conventional analog remote controller, the command value input to the welding power source is changed by a variable resistor installed inside. In this method, the command value may change due to the influence of the distance between the analog remote controller and the welding power source or the influence of noise from the outside. Even if the same command value is set by volume setting or the like, the same command value may not be instructed to the welding power source due to individual differences in the remote control.

  In addition, since the conventional analog remote controller cannot check the welding output value of the welding power source during welding, the operator needs to check the indicator of the welding power source in order to check the welding output value of the welding power source. However, if the welding power source and the welding work site where the welding work is actually performed are separated, or if there is a structure such as a building or installation between the welding power source and the welding work site, the worker should display the welding power source indicator. It cannot be easily confirmed.

  In order to solve these problems, the following measures can be considered. For example, if a digital remote controller (hereinafter referred to as a digital remote controller) is used, individual differences between remote controllers can be reduced. Further, the digital remote control can display the welding output during welding, and the operator can check the welding output at the work site. However, when the digital remote controller is connected to the welding power source, since the cable that the welding power source normally has corresponds to an analog signal, it is necessary to newly prepare a cable and a transceiver corresponding to the digital signal.

  Therefore, it is possible to propose a welding power source that does not support analog signals but supports only digital signals. However, in general, as a welding power source, a remote controller that gives a command to the welding power source using an analog remote controller that uses an analog signal is widely used. Therefore, it is very difficult at this stage to configure the welding power source so that the analog remote controller cannot be connected. Further, since a digital remote controller is more expensive than an analog remote controller, it is often required to use an inexpensive analog remote controller.

  The welding apparatus according to the present disclosure enables both an analog signal and a digital signal to be used in a connection path portion that is a signal path between a welding power source and a remote controller. With this configuration, in the welding device of the present disclosure, both an analog device (here, an analog remote controller) and a digital device (here, a digital remote controller) can be used. Therefore, an additional device or the like necessary for using a device with a different method is not necessary. Further, the operator can select and use an analog remote controller or a digital digital remote controller without any special preparation.

  Hereinafter, embodiments of the present disclosure will be described.

(Embodiment 1)
The first embodiment will be described with reference to FIG. 1 and FIG. 1 and 2 are diagrams for explaining a mechanism for sharing an analog remote controller and a digital remote controller in welding power supply 16 according to the first embodiment. FIG. 1 is a block diagram of a welding apparatus in which the analog remote controller 1 is connected to the welding power source 16, and FIG. 2 is a block diagram of the welding apparatus in which the digital remote controller 2 is connected to the welding power source 16.

  1 and 2, the welding apparatus of the present embodiment includes either the analog remote controller 1 or the digital remote controller 2 connected to the welding power source 16, the welding power source 16, and the common connection path portion 4. The analog remote controller 1 is an analog signal type remote controller. The digital remote controller 2 is a digital signal type remote controller. An analog signal command value (welding signal) is input to the welding power source 16 from the analog remote controller 1, and a digital signal command value (welding signal) is input to the welding power source 16 from the digital remote controller 2. When the analog remote controller 1 is used, the operator operates the analog volume 15 to set a command value for the analog remote controller 1. When the digital remote controller 2 is used, the operator sets a command value to the digital remote controller 2 from the input unit 18. An operator of the welding apparatus uses either the analog remote controller 1 or the digital remote controller 2. The common connection path unit 4 includes a common signal line a and a common signal line b that enable the analog remote controller 1 or the digital remote controller 2 to be connected directly or indirectly to the welding power source 16.

  The welding power source 16 includes a control unit 10 that processes a welding signal transmitted from the analog remote controller 1 or the digital remote controller 2 (hereinafter referred to as “remote control (1, 2)”). The welding power source 16 receives a welding signal from the remote control (1, 2) via the common signal line a or the common signal line b (hereinafter, referred to as “common signal line (a, b)”). When the welding signal passes through the common connection path portion 4, noise from the outside is superimposed on the welding signal. Then, the welding signal is input to the filter unit 5, and noise is removed by the filter unit 5. Note that the filter unit does not necessarily remove all noise, but may remove some of the superimposed noise.

  Furthermore, the welding signal from which noise has been removed is input from the filter unit 5 to the control unit 10. The control unit 10 can process an analog signal transmitted from the analog remote controller 1 and a digital signal transmitted from the digital remote controller 2, respectively. The control unit 10 includes an analog signal processing unit 7 having an A / D conversion unit 6, a reception signal processing unit 8, and a transmission signal processing unit 9. The welding signal output from the filter unit 5 is branched and input to each of the A / D conversion unit 6 and the reception signal processing unit 8. As shown in FIG. 1, when the remote controller connected to the welding power source is the analog remote controller 1, the analog signal welding signal transmitted from the analog remote controller 1 is converted into a digital signal by the A / D converter 6, and analog signal processing is performed. The unit 7 processes the digital signal and then outputs it to the welding output unit 11.

  On the other hand, as shown in FIG. 2, when the remote controller connected to the welding power source is the digital remote controller 2, the reception signal processing unit 8 receives a digital welding signal from the digital remote controller 2. The reception signal processing unit 8 converts the information into necessary information and outputs it to the welding output unit 11.

  The welding output unit 11 outputs welding output data to the welding torch 102 based on the command value of the welding current input from the analog signal processing unit 7 or the reception signal processing unit 8.

  Further, the welding output unit 11 is also connected to the transmission signal processing unit 9. Further, the transmission signal processing unit 9 is connected to the transmission / reception unit 20 of the digital remote controller 2 via the filter unit 5 and the common signal line b. When there is data to be sent from the welding power source 16 to the digital remote controller 2, a signal is output from the welding output unit 11 to the digital remote controller 2, and from the transmission signal processing unit 9 to the digital remote controller 2 via the filter unit 5 and the common signal line b. Can be sent.

  The transmission / reception unit 20 is connected to the display unit 19 and can display information transmitted from the welding power source 16.

  In addition to the common signal line a and the common signal line b, the common connection path unit 4 further includes a common power supply line c and a common power supply line d for supplying power. The common connection path part 4 connects the welding power source 16 and the remote control (1, 2) directly or indirectly.

  Actually, a cable 4a is formed together with common signal lines (a, b) for transmitting signals to the common connection path section 4, a common power line c for supplying power, and a common power line d. In addition, you may comprise a common signal line (a, b) and a common power supply line (c, d) in the cable 4a.

  The common power supply line (c, d) is connected to the power supply unit 100 included in the welding power supply 16.

  Next, the operation of the welding apparatus shown in FIGS. 1 and 2 will be described. As shown in FIG. 1, when the analog remote controller 1 is electrically connected to the common connection path section 4, an analog signal indicating a current command value or a voltage command value is a common signal line ( The data is input to the filter unit 5 via a and b). A filter circuit is formed in the filter unit 5. Here, in order to facilitate understanding of the description, it is assumed that the current command value is input to the common signal line a and the voltage command value is input to the common signal line b. The welding signal transmitted to the welding power source 16 is input to the A / D conversion unit 6 after noise is removed by the filter unit 5. The A / D converter 6 converts the input analog signal into a digital signal and outputs it. The analog signal processing unit 7 calculates a current command value, a voltage command value, and the like based on the digital signal input from the A / D conversion unit 6, and outputs it to the welding output unit 11. The welding output unit 11 performs a welding output corresponding to the input current command value or voltage command value to the welding torch 102.

  When the digital remote controller 2 is electrically connected as shown in FIG. 2, the digital remote controller 2 superimposes a digital signal welding signal indicating a current command value or a voltage command value on the common signal line a or the common signal line b. To do.

  Note that the cable 4a for directly or indirectly connecting the analog remote controller 1 or the digital remote controller 2 to the welding power source 16 is preferably the same. By making the cable 4a the same, when the analog remote controller 1 and the digital remote controller 2 are replaced, the replacement work of the cable 4a and the like are unnecessary, and the workability is improved. In particular, when the cable 4a is long (for example, greater than 10 m and less than or equal to about 40 m), the workability is considerably improved by eliminating the need for replacing the cable 4a.

  For ease of explanation, in the present embodiment, the common signal lines (a, b) of the common connection path portion 4 that electrically connects the analog remote controller 1 or the digital remote controller 2 and the welding power source 16 are as follows. This will be described as follows. When the analog remote controller 1 is connected to the welding power source 16, the signal line for transmitting the current command value in the analog remote controller 1 is described as the common signal line a, and the signal line for transmitting the voltage command value is described as the common signal line b. However, it is not limited to these. Further, here, when the digital remote controller 2 is connected to the common connection path section 4, the common signal line a is used for transmission from the digital remote controller 2 to the welding power source 16, and the common signal line b is connected to the welding power source 16. It will be described as being used for transmission to the digital remote controller 2.

  A digital signal welding signal from the digital remote controller 2 is input from the common signal line a to the reception signal processing unit 8 via the filter unit 5. The reception signal processing unit 8 calculates a current command value, a voltage command value, and the like from the input digital signal and outputs them to the welding output unit 11. The welding output unit 11 performs welding output according to the input current command value and voltage command value. Further, the welding output unit 11 outputs the input current command value and voltage command value to the transmission signal processing unit 9. The transmission signal processing unit 9 converts the welding output value sent from the welding output unit 11 into a digital signal, and transmits the digital signal to the transmission / reception unit 20 of the digital remote controller 2 via the common signal line b of the common connection path unit 4. In the digital remote controller 2, the transmission / reception unit 20 can send the input digital signal to the processing unit 21 and display the output state of the welding output unit 11 on the display unit 19.

  When the digital remote controller 2 is connected to the welding power source 16, another function command (shield gas command or the like) can be superimposed on the welding signal and another operation command can be instructed from the welding output unit 11.

  This will be described using a specific example. The operation content is transmitted from the digital remote controller 2 to the welding power source 16 in a command and data format. The reception signal processing unit 8 instructs welding output according to the command and data. For example, if the command is “A0” and the data is “100”, the current command of the welding command value is “100A”. If the command is “A1” and the data is “180”, the voltage command of the welding command value "18.0V" is indicated. When the command is “A2” and the data is “1”, “shield gas gas valve ON” is instructed. As described above, when the digital remote controller 2 is used, in addition to the setting of the welding output value, other operation commands can be performed.

  On the other hand, when the analog remote controller 1 is connected to the welding power source 16, the two signal lines of the common signal line a and the common signal line b are used to make two types of current command values and voltage command values based on analog signals. Give instructions. Since the digital remote controller 2 transmits a digital signal to the welding power source 16, various instructions can be given to the welding power source 16 by a combination of commands and data.

  In addition, when the digital remote controller 2 is connected to the welding power source 16, data can be transmitted from the welding power source 16 to the digital remote controller 2 using the common signal line b. Information can be given to the digital remote controller 2.

  It is more preferable that the communication speed of the digital signal transmitted and received between the digital remote controller 2 and the welding power source 16 via the common signal line a or the common signal line b is 1200 bps to 9600 bps. At this communication speed, the digital remote controller 2 can stably transmit a digital signal even when the signal line (common signal line a and common signal line b) common to the signal line used for the analog signal and the filter unit 5 are used. I can do it. Further, it is possible to prevent signal communication from being hindered by an increase in electrical capacity generated by lengthening the cable 4a.

  As shown in FIG. 1, the analog remote controller 1 and the welding power source 16 are connected via a common power line c and a common power line d. The common power supply line c and the common power supply line d are connected to an analog volume 15 formed in the analog remote controller 1.

  On the other hand, as shown in FIG. 2, the power supply unit 22 of the digital remote controller 2 is an electronic device such as a common power supply line c and a common power supply line d that are insulated from the common power supply line d. It is electrically insulated by the parts. Thereby, even when the digital remote controller 2 is connected to the welding power source 16 instead of the analog remote controller 1, the power supply from the welding power source 16 is insulated, so that the influence of noise on the digital remote controller 2 can be suppressed. The power supply unit 22 of the digital remote controller 2 is insulated from the common power supply lines (c, d) supplied from the welding power supply 16. In other words, the power supply unit 22 of the digital remote controller 2 is insulated from the power supply unit 100 of the welding power supply 16.

  The reason for configuring the digital remote controller 2 in this way will be described. In the digital remote controller 2, electronic components of a CPU that performs communication and processing of a display unit such as an LCD (liquid crystal display) are generally vulnerable to noise. On the other hand, the analog remote controller 1 uses a variable resistor to change the welding command value, but the variable resistor is more resistant to noise than the CPU. Therefore, it is not necessary to consider the influence of noise on the electronic components included in the analog remote controller 1. It is necessary to prevent the noise of the cable 4 a used in the analog remote controller 1 from affecting the CPU of the digital remote controller 2. Therefore, the power source 22 of the digital remote controller 2 connected to the welding power source 16 via the cable 4a is preferably in an insulated state.

  With this configuration, the insulation resistance of the digital remote controller 2 can be improved. Therefore, even if the digital remote controller 2 uses the cable 4 a that connects the analog remote controller 1 and the welding power source 16, it is possible to reduce the influence on the digital remote controller 2 of noise riding on the cable 4 a and the like.

(Modification of Embodiment 1)
Next, a modification of the first embodiment will be described with reference to FIGS. In addition, about the structure similar to Embodiment 1, the same code | symbol may be attached | subjected and description may be abbreviate | omitted.

  FIG. 3 is a block diagram showing a state where the analog remote controller 1 is connected to the welding power source 16 with the wire feeder 30 as a relay unit. FIG. 4 is a block diagram showing a state where the digital remote controller 2 is connected to the welding power source 16 with the wire feeder 30 as a relay unit. Between the analog remote controller 1 or the digital remote controller 2 and the welding power source 16, a wire feeding device 30 for feeding a welding wire is arranged, and the analog remote controller 1 or the welding power source 16 via the wire feeding device 30 is arranged. A digital remote controller 2 is connected.

  For example, it is assumed that the wire feeding device 30 is disposed near the worker. In this case, even if the distance between the wire feeding device 30 and the welding power source 16 is as long as 10 to 40 m, for example, the wire feeding device 30 and the welding power source 16 are arranged by arranging the wire feeding device 30. If the cable 4b to be connected is used as the common connection path portion 4, there is no problem even if the operator and the welding power source 16 are separated. Further, the cable 4 c is used as the common connection path section 4 between the analog remote controller 1 or the digital remote controller 2 and the wire feeding device 30. Further, the cable 4 b is used as the common connection path portion 4 between the welding power source 16 and the wire feeding device 30. Further, common signal lines a and b and common power supply lines c and d are also passed through the wire feeding device 30. With this configuration, the analog remote controller 1 or the digital remote controller 2 and the power supply unit 100 of the welding power source 16 can be electrically connected using the same cable 4b and the same cable 4c. The entire wiring is extremely simple. Further, even when the cables (cable 4b and cable 4c) need to be replaced, it is only necessary to prepare the same cable, and the trouble of cable replacement work is eliminated. Therefore, workability at the time of switching between the analog remote controller 1 and the digital remote controller 2 is greatly improved.

  As is clear from the above description, according to the modification of the first embodiment, an operator replaces an analog device such as the analog remote controller 1 or a digital device such as the digital remote controller 2 with a dedicated cable as necessary. You can choose freely without having to.

(Embodiment 2)
Next, a second embodiment of the present disclosure will be described with reference to FIGS.

  FIG. 5 is a block diagram showing a configuration of a welding apparatus when the wire feeding device 30 is used as a relay unit and the digital remote controller 2 and the wire feeding device 30 are wirelessly connected. FIG. 6 is a schematic diagram for explaining the operation of the welding apparatus when the digital remote controller 2 and the wire feeding device 30 are wirelessly connected.

  In addition, about the structure similar to the modification of Embodiment 1 demonstrated using FIG. 4, the same code | symbol may be attached | subjected and description may be abbreviate | omitted.

  Differences between the welding apparatus of the modification of the first embodiment shown in FIG. 4 and the welding apparatus of the second embodiment shown in FIG. 5 are as follows. In FIG. 5, the wireless unit 41 (first wireless unit) is connected to the connection unit 3 a of the digital remote controller 2, and the wireless unit 42 (second wireless unit) is connected to the connection unit 3 b of the wire feeding device 30. Has been. In FIG. 3, wired communication using the wired cable 4c is performed between the digital remote controller 2 and the wire feeder 30. In FIG. 5, the digital remote controller 2 and the wire feeder 30 are connected to each other. Wireless communication is used.

  Next, the operation of the second embodiment will be described.

  First, the wireless unit 41 is connected to the digital remote controller 2, and the wireless unit 42 is connected to the wire feeding device 30. The wireless unit 41 wirelessly transmits digital data input from the digital remote controller to the wireless unit 42. The wireless unit 42 transmits a digital signal of digital data to the welding power source 16 via the common connection path unit 4. Since the signal operation in the welding power source 16 is the same as that in the first embodiment, the description thereof is omitted here.

  A digital signal transmitted from the welding power source 16 to the wire feeding device 30 via the common connection path unit 4 is transmitted to the radio unit 42. The wireless unit 42 wirelessly transmits a digital signal transmitted from the welding power source 16 via the wire feeding device 30 to the wireless unit 41 as digital data. The digital remote controller 2 converts the digital data received by the wireless unit 41 and displays it on the display unit 19.

  Note that the wireless unit 41 connected to the digital remote controller 2 may be located anywhere such as built-in, on the surface, or in the vicinity as long as it can be electrically connected to the digital remote controller 2 and is not particularly limited. Similarly, the radio unit 42 connected to the wire feeding device 30 may be located anywhere such as built-in, on the surface, or in the vicinity as long as it can be electrically connected to the wire feeding device 30, and is not particularly limited.

  Next, the superiority of the second embodiment will be described with reference to FIG.

  In the example shown in FIG. 6, a structure 200 exists between the digital remote controller 2 and the welding power source 16. In the second embodiment, wireless communication is performed wirelessly only between the digital remote controller 2 held by the worker and the wire feeding device 30 disposed in the vicinity of the worker. There is no fear that the structure 200 shields the wireless section between the apparatus 30 and the structure 200 does not block wireless communication.

  In addition, when the digital remote controller 2 that is a wireless remote controller performs direct wireless communication with the welding power source 16, a structure 200 such as a building or an installation exists between the digital remote controller 2 and the welding power source 16. Even if not, radio waves may not reach if the transmission / reception distance of wireless communication is large. However, as shown in FIG. 6, since the wire feeding device 30 and the welding power source 16 are wired communication, and only the digital remote controller 2 and the wire feeding device 30 are wireless communication, Becomes a sufficiently short distance, and the frequency of wireless communication failure is very small.

  As described above, the wire feeding device 30 and the welding power source 16 are wiredly communicated via the common connection path portion 4 (common signal lines a and b, cable 4b), and the wire feeding device 30 and the welding power source 16 are communicated. It is preferable that the communication speed of the digital signal transmitted and received via the common signal line (a, b) of the common connection path unit 4 is 1200 bps to 9600 bps. As a result, at this communication speed, a digital signal wired from the wireless remote control 2 to the welding power source 16 via the wire feeder 30 is transmitted to the signal line used for the analog signal (common communication). Even if the signal line a and the common signal line b) and the filter unit 5 are used, stable transmission can be performed. Furthermore, it is possible to prevent signal communication from being hindered by an increase in electrical capacity generated by lengthening the cable 4b.

  Generally, the wire feeding device 30 is arranged near an operator having the digital remote controller 2. That is, even if the distance between the digital remote controller 2 and the welding power source 16 is a long distance of, for example, longer than 10 m and not longer than 40 m, generally, the distance between the wire feeder 30 and the worker performing welding is 10 m. It becomes as follows. Wireless communication may be performed within a range of 10 m or less, and the distance of wireless communication is sufficiently short, and the frequency of failure of wireless communication becomes very small. Further, the operator only has to consider that there is no structure 200 between the digital remote controller 2 and the wire feeder 30. Since wireless communication is performed between the digital remote controller 2 and the wire feeding device 30, the operator is freed from the trouble of routing the cable, and the workability is dramatically improved.

  As apparent from the above description, according to the present embodiment, an operator can select an analog machine part as the analog remote controller 1 or the like and a digital machine part as the digital remote controller 2 or the like as needed. In addition, workability is dramatically improved by wireless communication between the digital remote controller 2 and the wire feeder 30.

  Next, a method for setting whether the remote controller to be connected is the analog remote controller 1 or the digital remote controller 2 in the above-described embodiment and its modification will be briefly described.

  As the setting method, there is a method in which an operator directly inputs in advance a type of a remote controller that is manually connected to an input unit (not shown) of the welding power source 16. As another method, the control unit 10 of the welding power source 16 determines the type of the remote control from the signal transmitted from the remote control (1, 2) to the welding power source 16, and whether the analog signal or the digital signal is valid depending on the type of remote control. There is a way to judge.

(Summary)
The welding apparatus according to the present disclosure includes a welding power source 16 having a filter unit 5, a control unit 10, and a welding output unit, an analog remote controller 1 or a digital remote controller 2 connected to the welding power source 16, a welding power source 16, A common connection path section 4 having common signal lines a and b that directly or indirectly connect the analog remote controller 1 or the digital remote controller 2 to each other. The filter unit 5 removes noise from signals input from the common signal lines a and b, and outputs the signal from which noise has been removed to the control unit 10. The control unit 10 includes an analog signal processing unit 7 having an A / D conversion unit 6 and a reception signal processing unit 8. When an analog signal is input from the analog remote controller 1 to the analog signal processing unit 7 via the common signal lines a and b and the filter unit 5, the analog signal processing unit 7 outputs a digital signal to the welding output unit in accordance with the analog signal. To do. When a digital signal is input from the digital remote controller 2 to the reception signal processing unit 8 via the common signal lines a and b and the filter unit 5, the reception signal processing unit 8 outputs the digital signal according to the input digital signal by welding. To the unit 11.

  In the welding device of the present disclosure, the control unit may include the transmission signal processing unit 9. When a digital signal is input from the welding output unit 11 to the transmission signal processing unit 9, the digital signal is digitally transmitted via the filter unit 5 and the common signal lines a and b in accordance with the digital signal input to the transmission signal processing unit. It is transmitted to the remote controller 2.

  In the welding device of the present disclosure, the common connection path portion 4 may have common power supply lines c and d. The common power supply lines c and d connect the analog remote controller 1 or the digital remote controller 2 and the welding power supply 16. The power supply unit 22 of the digital remote controller 2 to which the common power supply lines c and d are connected is insulated. It is more preferable that the communication speed of digital signals transmitted and received between the digital remote controller 2 and the welding power source 16 via the common signal lines a and b is 1200 bps or more and 9600 bps or less.

  The welding apparatus of this indication may have a wire feeding device which feeds a welding wire. The common connection path section 4 includes a first common connection path section (common signal lines a and b, cable 4b) and a second common connection path section (common signal lines a and b, cable 4c). A wire feeding device 30 is disposed between the welding power source 16 and the analog remote controller 1 or the digital remote controller 2. The welding power source 16 and the wire feeder 30 are connected by a first common connection path. The analog remote controller 1 or the digital remote controller 2 and the wire feeding device 30 are connected by a second common connection path unit. Between the analog remote controller 1 or the digital remote controller 2 and the welding power source 16, wired communication is performed via the first common connection path section, the wire feeding device 30, and the second common connection path section.

  The welding apparatus of this indication may have a wire feeding device which feeds a welding wire. The common connection path section 4 includes a first common connection path section (common signal lines a and b, cable 4b) and a second common connection path section (common signal lines a and b, cable 4c). A wire feeding device 30 is disposed between the welding power source 16 and the analog remote controller 1 or the digital remote controller 2. The welding power source 16 and the wire feeder 30 are connected by a first common connection path. The analog remote controller 1 and the wire feeding device 30 are connected by a second common connection path unit. Between the analog remote controller 1 and the welding power source 16, wired communication is performed via the first common connection path section, the wire feeding device 30, and the second common connection path section. The digital remote controller 2 has a wireless unit 41, and the wire feeder 30 has a wireless unit 42. Wireless communication is performed between the digital remote controller 2 and the wire feeder 30. Wire communication is performed between the wire feeding device 30 and the welding power source 16 via the first common connection path portion, and the first common connection path portion ( The communication speed of digital signals transmitted and received via the common signal lines a and b and the cable 4b) is 1200 bps to 9600 bps.

  The welding device of the present disclosure may have a welding torch 102. The welding output part 11 is connected to the welding torch 102.

  In the present disclosure, by sharing the common connection path unit 4 in which the analog remote controller 1 or the digital remote controller 2 and the welding power source 16 are directly or indirectly connected, both the analog machine unit and the digital machine unit can be used. Become. As a result, the operator can select either an analog machine part or a digital machine part as necessary, and the degree of freedom in selecting the machine part is greatly improved.

  Further, by further including a wire feeding device 30 between the digital remote controller 2 and the welding power source 16, wireless communication can be performed between the digital remote controller 2 and the wire feeding device 30, further improving workability. It can be useful.

1 Analog remote control (first remote control)
2 Digital remote control (second remote control)
3a, 3b Connection unit 4 Common connection path unit 4a, 4b, 4c Cable 5 Filter unit 6 A / D conversion unit 7 Analog signal processing unit 8 Reception signal processing unit 9 Transmission signal processing unit 10 Control unit 11 Welding output unit 15 Analog volume Reference Signs List 16 welding power source 18 input unit 19 display unit 20 transmission / reception unit 21 processing unit 22 power source unit 23 DC-DC converter 30 wire feeder 41 wireless unit (first wireless unit)
42 wireless unit (second wireless unit)
DESCRIPTION OF SYMBOLS 100 Power supply part 102 Welding torch 200 Structure a, b Common signal line c, d Common power supply line

Claims (6)

A welding power source having a filter unit, a control unit, and a welding output unit;
A first remote controller or a second remote controller connected to the welding power source;
A common connection path section having a common signal line for directly or indirectly connecting the welding power source and the first remote controller or the second remote controller;
With
The filter unit removes noise of a signal input from the common signal line, and outputs the signal from which noise has been removed to the control unit,
The control unit includes an analog signal processing unit having an A / D conversion unit, and a reception signal processing unit,
When an analog signal is input from the first remote controller to the analog signal processing unit via the common signal line and the filter unit, the analog signal processing unit outputs a first digital signal according to the analog signal. Output to the welding output section,
When a second digital signal is input from the second remote controller to the reception signal processing unit via the common signal line and the filter unit, the reception signal processing unit responds to the second digital signal. A welding apparatus that outputs a third digital signal to the welding output section. The control unit further includes a transmission signal processing unit,
When a fourth digital signal is input from the welding output unit to the transmission signal processing unit, a fifth digital signal is output from the filter unit and the digital signal according to the four digital signals input to the transmission signal processing unit. The welding apparatus according to claim 1, wherein the welding apparatus is transmitted to the second remote controller via a common signal line. The common connection path part further has a common power line,
The common power line connects the first remote controller or the second remote controller and the welding power source,
The power contact portion of the second remote controller to which the common power line is connected is insulated,
The welding apparatus according to claim 1, wherein a communication speed of a digital signal transmitted / received between the second remote controller and the welding power source via the common signal line is 1200 bps or more and 9600 bps or less. A wire feeding device for feeding the welding wire;
The common connection path part has a first common connection path part and a second common connection path part,
The wire feeding device is disposed between the welding power source and the first remote controller or the second remote controller,
The welding power source and the wire feeding device are connected by the first common connection path portion,
The first remote controller or the second remote controller and the wire feeding device are connected by the second common connection path unit,
Between the first remote controller or the second remote controller and the welding power source, the first common connection path section, the wire feeding device, and the second common connection path section are interposed. The welding apparatus according to any one of claims 1 to 3, which is wiredly communicated. A wire feeding device for feeding the welding wire;
The common connection path part has a first common connection path part and a second common connection path part,
The wire feeding device is disposed between the welding power source and the first remote controller or the second remote controller,
The welding power source and the wire feeding device are connected by the first common connection path portion,
The first remote controller and the wire feeding device are connected by the second common connection path unit,
Between the first remote controller and the welding power source, wired communication is performed via the first common connection path unit, the wire feeding device, and the second common connection path unit.
The second remote controller includes a first wireless unit;
The wire feeding device has a second radio unit;
Between the second remote controller and the wire feeder, wireless communication,
Between the wire feeding device and the welding power source, wired communication is performed via the first common connection path portion, and between the wire feeding device and the welding power source via the common connection path portion. The welding apparatus according to claim 1 or 2, wherein a communication speed of a digital signal transmitted and received is 1200 bps or more and 9600 bps or less. It also has a welding torch,
The welding apparatus according to claim 1, wherein the welding output portion is connected to the welding torch.

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