JP2016019989A - Automatic welding apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an automatic welding apparatus not causing twists to occur in a power cable and a gas hose connected to a welding torch even when the welding torch performs welding operation while revolving and being capable of continuously performing the welding operation.SOLUTION: A conductive plate 3, a gas groove 4 and a cooling medium groove 5 are annularly formed on an annular-shaped fixed rail 2 and are individually connected with a first power cable 15a, a first gas hose 16a and a first cooling medium hose 17a. Annular seal members 25 individually inserted into an electric contactor 7 brought into slide contact with the conductive plate 3, the gas groove 4 and the cooling medium groove 5 and sealing between a drive rail 6 and the fixed rail 2 are provided to the drive rail 6 revolving in a circumferential direction on the fixed rail 2. End portion openings of a second gas hose 16b and a second cooling medium hose 17b are individually opened at gas groove 4 and cooling medium groove 5 sides. On this account, a second power cable 15b joined to the electric contactor 7, the second gas hose 16b and the second cooling medium hose 17b are free of twists even when a welding torch 11 provided on the drive rail 6 performs welding operation while revolving.SELECTED DRAWING: Figure 2

Description

  Embodiments described herein relate generally to an automatic welding apparatus.

  Work to install a storage container for storing spent fuel generated from facilities such as nuclear power plants, and cover the upper opening of the storage container storing the spent fuel, and the covered lid and storage container Welding and assembling work and the like to be sealed in a high dose area is performed. Therefore, it is required to perform welding assembly work using an automatic welding machine that can be remotely operated so that work in a high-dose area is minimized.

  A conventional automatic welding machine (see, for example, Patent Document 1) has a configuration in which a power cable and a gas hose are connected to a welding torch. Then, following the movement of the welding torch, the power cable and the gas hose move while being pulled by the welding torch. For this reason, when welding work is performed on a welded portion at a circumferential location with an automatic welder, the power cable and gas hose connected to the welding torch are twisted as the welding torch revolves in the circumferential direction. It will follow. Since the power cable and the gas hose are twisted, an entanglement is generated. Therefore, it is necessary to prevent the entanglement from occurring.

  In order to prevent the occurrence of entanglement, a welding work that is performed while repeating forward and backward movements is conventionally performed as a welding work. For example, if the welding operation is performed during the forward movement, the non-welding operation is performed during the backward movement. Then, the welding work accompanying the forward movement and the non-welding work accompanying the backward movement are repeated. By repeating this forward and reverse movement, the entanglement of the power cable and the gas hose is prevented.

JP 2002-296383 A

  As described above, in a conventional welding operation using an automatic welding machine, it is necessary to repeat the forward and backward of the welding torch. Therefore, the crater shape at the start end of welding is different from the crater shape at the end, and there is a risk that a welding defect occurs. In addition, when non-welding work is not performed, there is a problem that work time is increased because time is required to move the welding torch backward.

  In the embodiment according to the present invention, the above-described problems can be solved, and the power cable and the gas hose are not pulled to follow the movement of the welding torch, and the welding torch can perform the welding work while revolving. An object of the present invention is to provide an automatic welding apparatus capable of performing welding work along a continuous circumferential direction without causing twisting of a power cable or a gas hose.

In the automatic welding apparatus according to the embodiment of the present invention that can achieve the above-described object, an annular fixed rail that is fixed to a workpiece, an annular fixed rail that is disposed on the fixed rail, and along a circumferential direction of the fixed rail. A first annular groove and an annular conductive plate, and a first conduit and a first power source connected to the first annular groove and the conductive plate, respectively, for supplying a working medium and power from outside the fixed rail. Cable and
A drive rail mounted on the fixed rail and circulated on the fixed rail along a circumferential direction of the fixed rail; an electrical contact disposed on the drive rail and in sliding contact with the conductive plate; A second power cable connected to the contact, a second conduit for taking out the working medium supplied to the drive rail side through the first annular groove to the outside of the drive rail,
An annular seal member that prevents the working medium from leaking to the outside from between the fixed rail and the driving rail, and the working medium and the power are supplied via the second power cable and the second conduit. And a moving mechanism that is provided on the drive rail and moves the welding torch so as to be close to and away from the welding location.

  In the automatic welding apparatus according to the embodiment of the present invention, the power cable and the gas hose are pulled following the movement of the welding torch even if the welding torch performs the welding operation while continuously revolving along the circumferential direction. It is possible to prevent twisting and entanglement.

It is an apparatus block diagram which shows an automatic welding apparatus. (Embodiment 1) It is a principal part perspective view of a fixed rail and a drive rail. (Embodiment 1) 4A is a plan view of the fixed rail, FIG. 3B is a bottom view of the drive rail, FIG. 3A is a cross-sectional view taken along line A-A, and FIG. 3B is a cross-sectional view taken along line BB. (Embodiment 1) FIG. 3 is a perspective view (a) of a main part of a drive rail provided with an annular seal member, and a perspective view (b) of a main part of a fixed rail. (Embodiment 1) It is a principal part perspective view which shows the modification of an annular seal member. (Embodiment 1) The arrangement | positioning structure of the cyclic | annular seal member in another structure is shown, and it is principal part sectional drawing (a) of a drive rail, and principal part sectional drawing (b) of a fixed rail. (Embodiment 1) The arrangement configuration of the annular seal member in another configuration is shown, and a plan view of the fixed rail (a), a bottom view of the drive rail (b), a cross-sectional view taken along the line DD in FIG. 7B, and FIG. It is CC sectional drawing (d) of). (Embodiment 1) It is an apparatus block diagram of the automatic welding apparatus using another rotation drive mechanism. (Embodiment 1) It is a principal part perspective view (a) of a drive rail provided with the annular seal member of other composition, and a principal part perspective view (b) of a fixed rail. (Embodiment 2) It is the top view (a) of the state which provided the annular seal member of other composition, and mounted the drive rail on the fixed rail, and a sectional view (b). (Embodiment 2) It is an apparatus block diagram of an automatic welding apparatus. (Embodiment 3) It is another arrangement block diagram in an automatic welding device. (Embodiment 3) It is another apparatus block diagram in an automatic welding apparatus. (Embodiment 4)

Hereinafter, the configuration of an automatic welding apparatus according to an embodiment of the present invention will be described with reference to the drawings.
[Embodiment 1]
The configuration of the first embodiment according to the present invention will be described with reference to FIGS.

(Overall configuration)
FIG. 1 is an apparatus configuration diagram of the automatic welding apparatus 1, and FIG. 2 is a perspective view of main parts of a fixed rail 2 and a drive rail 6. The automatic welding apparatus 1 is arranged on an annular fixed rail 2, a drive rail 6 mounted on the fixed rail 2 and circulated along the circumferential direction on the fixed rail 2, and movably disposed on the drive rail 6. And a moving mechanism provided with a welding torch 11.

  The moving mechanism includes a moving table 13 that slides on the drive rail 6 and a tool head 12 that is supported by the moving table 13 and slides with respect to the moving table 13. As a configuration of the moving mechanism, a configuration in which another tool is supported on the moving table 13 instead of the tool head 12 can be used as necessary.

  The fixed rail 2 can be fixed outside the high-dose area, for example, on an upper lid 27 that covers the storage container 14 containing spent fuel. As a fixing method for fixing the fixed rail 2 on the upper lid 27, a fixing method by welding, a fixing method by bolts and nuts, or the like can be used.

  After the automatic welding apparatus 1 is fixed to the upper lid 27 outside the high dose area, the upper lid 27 and the automatic welding apparatus 1 are carried into the high dose area where the storage container 14 is placed by a crane or the like. The upper lid 27 can be placed over the upper opening of the storage container 14. Thereafter, as will be described later, the covered upper lid 27 and the upper opening of the storage container 14 can be welded to form a sealed state.

  When a fixing method using bolts and nuts is used as a fixing method of the fixed rail 2, for example, a nut is fixed to the upper lid 27 side, and an attachment hole formed in the fixed rail 2 or an outer side from the fixed rail 2 is used. The fixing rail 2 can be fixed to the upper lid 27 by forming a mounting hole in the mounting piece extended in the step, and inserting a bolt into this mounting hole and screwing it into the nut.

  When the welding operation or the like by the automatic welding apparatus 1 is completed, if the fixed rail 2 is fixed to the upper lid 27 by the fixing means using bolts and nuts, the fixed state by the bolts and nuts is released and automatic welding is performed. The device 1 can be removed from the top lid 27 and used for other welding operations.

When the fixed rail 2 is fixed to the upper lid 27 by welding, the drive rail 6 can be detached from the fixed rail 2 and used for other welding operations. At that time, the first power cable 15a (see FIG. 2), the first gas hose 16a (see FIG. 2), the first cooling medium hose 17a (see FIG. 2) connected to the fixed rail 2 described later, It can be set as the structure connected to the fixed rail 2 via the detachable connector.
By configuring in this way, only the fixed rail 2 remains on the upper lid 27, and the remaining members in the automatic welding apparatus 1 can be removed from the upper lid 27.

(Configuration of fixed rail)
As shown in FIGS. 2 and 3, a pair of conductive plates 3, a gas groove 4, and a cooling medium groove 5 formed in an annular shape are formed on the upper surface of the fixed rail 2. The gas groove 4 and the cooling medium groove 5 constitute a first annular groove. As shown in FIGS. 2, 3 (a) and 3 (d), a first power cable 15 a is connected to each of the pair of conductive plates 3 arranged in an annular shape. Each first power cable 15a is led out from the inner surface side of the fixed rail 2, and is connected to a control device (not shown).

  Below, although the structure which provided the annular | circular shaped gas groove 4 and the annular | circular shaped cooling medium groove | channel 5 on the upper surface of the fixed rail 2 is demonstrated, another annular groove | channel which flows other gas and liquid as needed is demonstrated. Can also be formed on the upper surface of the fixed rail 2.

  As shown in FIGS. 2, 3 (a) and 3 (d), gas holes 8 a and cooling medium holes 9 a are formed in the bottom surfaces of the gas groove 4 and the cooling medium groove 5, respectively. The first gas hose 16a is connected, and the first cooling medium hose 17a is connected to the cooling medium hole 9a. The 1st gas hose 16a and the 1st cooling medium hose 17a comprise the 1st pipe line, and are derived | led-out from the inner surface side of the annular | circular shaped fixed rail 2, and are connected to the control apparatus etc. which are not shown in figure. .

  In the illustrated example, a configuration example is shown in which one gas hole 8a and one cooling medium hole 9a are formed on the bottom surfaces of the gas groove 4 and the cooling medium groove 5, respectively. Depending on the length dimension, etc., it may be formed at a plurality of locations along the circumferential direction.

  Even when a plurality of gas holes 8a and cooling medium holes 9a are formed, the first gas hose 16a and the first cooling medium hose 17a may be connected to the gas holes 8a and the cooling medium holes 9a, respectively. it can. With a configuration in which a plurality of gas holes 8a and cooling medium holes 9a are formed, the gas concentration and the flow rate of the cooling medium can be maintained substantially constant over the entire circumferential direction of the gas groove 4 and the cooling medium groove 5. it can.

(Configuration of drive rail)
As shown in FIGS. 2, 3 (b) and 3 (c), the surface of the drive rail 6 placed on the upper surface of the fixed rail 2 is a pair of electrical contacts that are elastically slidably contacted with each conductive plate 3. A contact 7 and an annular annular seal member 25 into which the front end surface side is inserted into the gas groove 4 and the cooling medium groove 5 are provided. In addition, a rail drive unit 10 for rotating the drive rail 6 around the fixed rail 2 is provided between the fixed rail 2.

  A second power cable 15 b is connected to each of the pair of electrical contacts 7. The pair of electric contacts 7 is configured using a leaf spring or the like, and can be slidably contacted with the conductive plate 3 while maintaining a state of being elastically pressed from above by the weight of the drive rail 6 or the like. Thereby, even if the unevenness | corrugation is formed in the surface of the electrically conductive plate 3, the electrical contactor 7 can follow this unevenness | corrugation and can maintain an electrical conduction state by elastically deforming the electrical contactor 7. FIG.

  As a configuration for receiving and receiving power between the fixed rail 2 and the drive rail 6, a configuration using a pair of conductive plates 3 and a pair of electrical contacts 7 slidably contacting each conductive plate 3 is shown. When a plurality of types of electrical appliances are mounted on the 6 side, an appropriate number of conductive plates 3 and electrical contacts 7 corresponding to the number of the conductive plates 3 are provided in order to supply power to each electrical appliance. Can be configured.

  The driving rail 6 is provided with a second gas hose 16b and a second cooling medium hose 17b for taking out the gas and the cooling medium to the driving rail 6 side through the gas groove 4 and the cooling medium groove 5. The second gas hose 16b and the second cooling medium hose 17b constitute a second pipe line.

  In the state where the drive rail 6 is placed on the fixed rail 2, the gas hole 8b, which is the end opening of the second gas hose 16b, is located on the circumference of the gas groove 4, and the end of the second cooling medium hose 17b. The cooling medium hole 9 b that is a part opening is located on the circumference of the cooling medium groove 5.

  A rail drive unit 10 is provided as a configuration for rotating the drive rail 6 along the circumferential direction of the fixed rail 2. As shown in FIGS. 3 (b) and 3 (c), the rail drive unit 10 has a configuration in which a plurality of rollers 32 are provided on the drive rail 6 at equal intervals, and the rollers 32 are applied to the outer surface of the fixed rail 2. It is possible to make a contacted configuration.

  Then, an appropriate number of rollers 32 among the plurality of rollers 32 can be configured as drive rollers, and the rest can be configured as driven rollers to configure a rotation drive mechanism. By driving and controlling the drive roller using a motor or the like, the drive rail 6 can be rotated around the fixed rail 2 in any direction in the forward and reverse directions.

  Alternatively, as shown in FIG. 8, the rail drive unit 10 is provided on the drive rail 6 in such a manner that an annular guide surface portion 38 formed on the outer surface of the fixed rail 2 and upper and lower surfaces of the guide surface portion 38 are sandwiched. The thrust bearing 39 and a rotation drive mechanism for rotating the drive rail 6 in the forward and reverse directions with respect to the fixed rail 2 can also be used. As a rotation drive mechanism in this case, for example, a configuration using a drive roller (not shown) in contact with the side surface of the guide surface portion 38 can be used.

  By configuring such a rotational drive mechanism, the drive roller can be rotationally controlled by a control device (not shown), and the rotational amount of the drive rail 6 can be arbitrarily controlled. Power can be supplied to a motor or the like that drives the drive roller by further forming an annular conductive plate 3 on the fixed rail 2. And the circumference | surroundings of the drive rail 6 can be controlled by remote operation.

  3 shows a configuration in which the roller 32 is disposed on the drive rail 6 side. However, as shown in FIG. 6, the roller 32 is disposed on the fixed rail 2 side, and an annular flange portion formed on the drive rail 6 is formed. Can also be configured so as to be in sliding contact with the outer peripheral surface of the roller 32. In this configuration, when an arbitrary roller 32 among the rollers 32 arranged on the fixed rail 2 side is used as a driving roller, a motor or the like for driving the driving roller can be provided on the fixed rail 2 side.

(Configuration of annular seal member)
As shown in FIGS. 2 to 4, the base end surface side of the annular seal member 25 is fixed to the surface of the drive rail 6 facing the fixed rail 2. For example, as shown in FIGS. 3B, 3 </ b> C, and 4 </ b> A, the base end surface side of the annular seal member 25 is annularly formed on the surface of the drive rail 6. A groove can be formed, and the base end face side of the annular seal member 25 can be fitted into the annular groove.

  In FIG. 4, the gas groove 4 and the cooling medium groove 5 which are the first annular grooves, and the pair of annular seal members 25 respectively inserted into the gas groove 4 and the cooling medium groove 5 are illustrated without being illustrated. One annular groove and one annular seal member 25 are shown.

  The front end face side of the annular seal member 25 can be inserted into the gas groove 4 and the cooling medium groove 5, respectively. The annular seal member 25 configured in this manner slides in the gas groove 4 and the cooling medium groove 5 as the drive rail 6 circulates in close contact with the side surfaces of the gas groove 4 and the cooling medium groove 5. Can do. Further, it is possible to prevent the gas and the cooling medium from flowing out from the gap between the fixed rail 2 and the drive rail 6.

  In a state where the drive rail 6 is placed on the fixed rail 2, the annular seal member 25 inserted into the gas groove 4 and the cooling medium groove 5 and the bottom surface of the gas groove 4 and the cooling medium groove 5 are disposed between the driving rail 6 and the cooling medium groove 5. Is formed with a space. This space portion is filled with the gas and the cooling medium supplied from the first gas hose 16a and the first cooling medium hose 17a, respectively.

  As shown in FIG. 2, FIG. 3B, and FIG. 4, the annular seal member 25 is formed in a shape in which a part of the annular shape is notched, and the first portion provided on the drive rail 6 side is provided in the notch. The gas hole 8b and the cooling medium hole 9b which are the edge parts of 2 gas hose 16b and the 2nd cooling medium hose 17b are opening.

  As the shape of the annular seal member 25, a configuration in which a concave portion 28 is formed on the front end surface of the annular seal member 25 as shown in FIG. You can also. A gas hole 8b and a cooling medium hole 9b which are ends of the second gas hose 16b and the second cooling medium hose 17b provided on the drive rail 6 side are opened on the bottom surface of the recessed part 28.

  FIG. 5 is a perspective view of the annular seal member 25 as viewed from the front end surface side. By using the annular seal member 25 having the shape shown in FIG. 5, the annular seal member 25 is inserted into the gas groove 4 and the cooling medium groove 5, respectively. The medium groove 5 can be brought into sliding contact with both side surfaces in close contact with each other, and the sealing performance on the side surfaces can be improved.

  As a structure of the annular seal member, a structure using an O-ring 29 can be used as shown in FIG. In FIG. 7, a gas groove 34 and a cooling medium groove 35 are formed on the surface of the drive rail 6 facing the fixed rail 2 so as to face the gas groove 4 and the cooling medium groove 5. The gas groove 34 and the cooling medium groove 35 constitute a second annular groove.

On the fixed rail 2 side, O-ring housing grooves 29 a along the gas groove 4 and the cooling medium groove 5 are formed on the inner peripheral edge side and the outer peripheral edge side of the gas groove 4 and the cooling medium groove 5, respectively. On the drive rail 6 side, an O-ring storage groove 29b is formed along the gas groove 34 and the cooling medium groove 35 on the inner peripheral edge side and the outer peripheral edge side of the gas groove 34 and the cooling medium groove 35, respectively.
In FIG. 7A, since there are a plurality of concentric circles and the drawing becomes difficult to understand, the O-ring storage groove 29a is not shown.

  By sandwiching the O-ring 29 between the O-ring housing grooves 29a and 29b, gas leaks to the outside from between the gas groove 4 and the gas groove 34 facing each other, and the cooling medium groove 5 and the cooling medium groove The O-ring 29 can seal the leakage of the cooling medium from the gap 35.

(Configuration of moving mechanism)
As shown in FIGS. 1 and 2, a moving base 13 that slides in the radial direction of the driving rail 6 is disposed on the driving rail 6. A tool head 12 that moves forward and backward is provided. The moving table 13 and the tool head 12 constitute a moving mechanism. A welding torch 11 is provided at the tip of the tool head 12.

  The movable table 13 and the tool head 12 can be linearly slid using a conventionally known linear drive mechanism such as screw drive, ball nut drive, linear motor drive, or the like. Further, if necessary, the moving table 13 can be provided with a turning mechanism to perform a two-dimensional movement, or the welding torch 11 can be attached to the tool head 12 via another turning mechanism. .

  If comprised in this way, a multidimensional motion can be given with respect to the front-end | tip part of the welding torch 11. FIG. And the welding torch 11 is welded from a desired direction to the welding location 30 between the upper lid 27 covering the opening of the body portion 14a of the storage container 14 and the opening end portion of the body portion 14a by a moving mechanism. be able to.

  The electric power extracted by the second power cable 15 b and the gas (for example, argon gas) extracted by the second gas hose 16 b are supplied to the welding torch 11. The cooling medium (for example, air) taken out by the second cooling medium hose 17b can be ejected from the cooling nozzle 18 to cool the welded portion 30 and its surroundings.

(Function and effect)
According to the configuration of the first embodiment of the present invention, the power supply cable, the gas hose, and the cooling medium hose connected to the resource (not shown) and the welding torch 11 are not directly connected to the fixed rail 2 and the drive rail 6. It can be connected by rotating connection between them. And welding work can be performed by remote control.

  With this configuration, even if the welding torch 11 continuously performs the revolving motion along the circumferential direction and continuously performs the welding operation on the welding location 30, the second power cable 15b, the second gas hose 16b, the second 2 The cooling medium hose 17b is not pulled following the movement of the welding torch 11, and the occurrence of twisting and entanglement is prevented.

  For the automatic welding apparatus 1 according to the first embodiment, the distance between the welding object and the welding torch, such as a conventional arc voltage adjustment apparatus (AVC) and distance measurement (contact type or non-contact type by image analysis), is used. By adding a function of keeping constant (that is, maintaining the arc length), continuous circumferential welding without a seam (so-called crater start / end) is possible.

  And it becomes possible to improve welding quality and shorten work time. Moreover, the risk that the second power cable 15b, the second gas hose 16b, and the second cooling medium hose 17b interfere with an obstacle in the work area can be reduced. Thereby, compared with a prior art, the automatic welding apparatus 1 which concerns on Embodiment 1 can show | play the effect excellent also in the installation property.

  In addition, when supplying electric power to a plurality of types of electric appliances mounted on the drive rail 6 side, an appropriate number of conductive plates 3 are arranged on the fixed rail 2, and electrical contact is made in sliding contact with each of the conductive plates 3. A configuration in which an appropriate number of children 7 are provided can be provided. Similarly, when it is necessary to supply a working medium to a plurality of types of tools provided on the drive rail 6, an appropriate number of annular grooves are formed on the fixed rail 2 side, and the working medium supplied to each annular groove is provided. Can be taken out by the take-out hose provided on the drive rail 6 side, that is, by the second pipe line.

[Embodiment 2]
The configuration of the second embodiment according to the present invention will be described with reference to FIGS. In the second embodiment, with respect to the same configuration as the configuration in the first embodiment, the same reference numerals as those used in the first embodiment are used to omit the overlapping description of the members.

  9A, 9 </ b> B, and 10 </ b> B, the gas groove 4 and the cooling medium groove 5, which are the first annular grooves disposed on the fixed rail 2, and the gas groove 4 and the cooling medium groove 5. The second gas hose 16b and the second cooling medium hose 17b that are respectively inserted in the drive rail 6 and are not illustrated, but typically one annular groove and one hose inserted into the annular groove. That is, the second pipe line is illustrated.

(Overall configuration)
As shown in FIGS. 9A and 9B, in the second embodiment, the pair of annular seal members 26 a are formed so as to cover the upper opening surfaces of the gas groove 4 and the cooling medium groove 5 formed in the fixed rail 2. Is provided. The pair of annular seal members 26a are closely arranged in surface contact with each other in the circumferential direction.

  The drive rail 6 is provided with a second gas hose 16b and a second cooling medium hose 17b protruding from the drive rail 6 to the fixed rail 2 side. And as shown to Fig.9 (a) and FIG.10 (b), the seal piece 26b is provided in the 2nd gas hose 16b and the 2nd cooling-medium hose 17b.

  As shown in FIG. 10B, when the second gas hose 16b and the second cooling medium hose 17b are inserted between the pair of annular seal members 26a, the second gas hose 16b and the second cooling medium in the circumferential direction of the drive rail 6 are used. The front and rear regions of the hose 17b are in a gap state that is not sealed by the annular seal member 26a. The front and rear regions in the gap state can be sealed by the seal piece 26b.

  FIG. 10A shows a configuration including three projecting portions 6 </ b> A to 6 </ b> C as a planar configuration of the drive rail 6, but the drive rail 6 is configured in an annular shape as shown in the first embodiment. You can also keep it. In addition, the moving mechanisms described in the first embodiment can be disposed in each of the overhang portions 6A to 6C.

  In FIG. 10A, a pair of electrical contacts 7, a second gas hose 16b, and a second cooling medium hose 17b are provided on the overhang portions 6A and 6B, and a pair of electric contacts are provided on the overhang portion 6C. 7 is provided. These arrangement configurations are examples, and other arrangement configurations may be used. Moreover, although the structure which provided the three overhang | projection parts 6A-6C as the drive rail 6 is shown, the number of formation of an overhang | projection part is not limited to three, It can form suitably.

(Function and effect)
According to the configuration of the second embodiment of the present invention, the same effects as those of the first embodiment can be achieved, and the volume of the drive rail 6 can be reduced. Thereby, the weight of the automatic welding apparatus 1 can be reduced in weight.

[Embodiment 3]
The configuration of the third embodiment according to the present invention will be described with reference to FIG. In Embodiment 3, about the structure similar to the structure in Embodiment 1, 2, the description which overlaps about the member is abbreviate | omitted by using the member code | symbol used in Embodiment 1,2.

  As shown in FIG. 11, two moving mechanisms, that is, a moving table 13 and a tool head 12 are arranged on the drive rail 6, and a welding torch 11 is mounted on each tool head 12, so that welding is performed at two locations. The welding operation can be performed on the portions 30 simultaneously or with a time interval. Thereby, shortening of welding operation time can be aimed at.

The arrangement position of the two moving mechanisms arranged on the drive rail 6 is not limited to the configuration arranged opposite to the position on the diameter with respect to the annular drive rail 6. It is also possible to adopt an arrangement configuration that is appropriately spaced apart in the upper radial direction. Further, the number of moving mechanisms disposed on the drive rail 6 is not limited to two, and may be appropriately disposed.
For example, as shown to Fig.10 (a), it can also arrange | position so that it may become equal intervals with respect to the circumferential direction of the drive rail 6. FIG.

As shown in FIG. 12, when at least two moving mechanisms are arranged on the drive rail 6, an inspection device 19 (for example, an ultrasonic flaw detection sensor 19a) is used instead of the welding torch 11 for one moving mechanism. It can also be replaced with an inspection device provided. By mounting the inspection device 19 on the moving mechanism, the welding operation and the inspection of the welded portion 30 can be performed simultaneously.
And the tool mounting part in a moving mechanism can be set as the structure which can mount | wear with the tools of welding torch 11 and the inspection apparatus 19 detachably.

(Function and effect)
According to the configuration according to the third embodiment, a plurality of tools can be detachably mounted on the drive rail 6, and when a plurality of welding torches 11 are used as the tools, the welding work time can be increased. Shortening becomes possible. When the inspection apparatus 19 is used as one of the tools, the welding operation and the inspection operation can be performed in parallel at the same time, and the setup time and the operation time can be shortened. In addition, since it is possible to detect the weld defect location in real time, it is possible to quickly cope with cases where measures such as repair are necessary.

[Embodiment 4]
The configuration of the fourth embodiment according to the present invention will be described with reference to FIG. In the configurations of the first to third embodiments, the configuration of the automatic welding device 1 in which the automatic welding device 1 is disposed on the upper lid 27 that covers the storage container 14 and performs a welding operation in the vertical downward direction has been described.

  In the configuration of the fourth embodiment, for example, an automatic welding apparatus for performing welding in the horizontal direction so as to weld the joint portion between the upper body portion 20 and the lower body portion 21 of the cylindrical structure over the circumferential direction. The configuration of 1 will be described. About the structure similar to the structure in Embodiment 1-3, the description which overlaps about the member is abbreviate | omitted by using the member code | symbol used in Embodiment 1-3.

  In the first to third embodiments, the fixed rail 2 is configured to be fixed to the upper surface of the upper lid 27, whereas in the configuration of the fourth embodiment, the fixed rail 2 is attached so as to surround the outer peripheral surface of the lower body portion 21. The fixed rail installation jig 22 is installed. The fixed rail 2 can be fixed on the fixed rail installation jig 22 using an appropriate fixing method such as a fixing method by welding or a fixing method using bolts and nuts.

(Function and effect)
As shown in FIG. 13, the welding torch 11 can be continuously moved in the horizontal direction, and continuous welding is performed on a welding location 30 that is a joint portion between the upper body portion 20 and the lower body portion 21. Work can be done. Moreover, since the welding torch 11 can move along the circumferential direction of the upper body portion 20 and the lower body portion 21, the welding in the lateral direction can be performed continuously and automatically.

Therefore, for example, also in the welding work of a cylindrical structure such as a shroud of a nuclear power plant, it is possible to improve the welding quality and shorten the welding work time.
In addition, by arranging a plurality of moving mechanisms on the drive rail 6, it is possible to simultaneously perform a welding operation on the welding location 30 at a plurality of locations. Furthermore, if it is set as the structure which mounted the inspection apparatus in one of the moving mechanisms, the welding location 30 can be test | inspected simultaneously with welding operation.

  As mentioned above, although several embodiment which concerns on this invention was described, these embodiment was shown as an example and is not intending limiting the range of invention. These novel embodiments can be implemented in various other forms, and various omissions, combinations, replacements, and changes can be made without departing from the scope of the invention. These embodiments and modifications thereof are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 1 ... Automatic welding apparatus, 2 ... Fixed rail, 3 ... Conductive plate, 4 ... Gas groove, 5 ... Cooling medium groove, 6 ... Drive rail, 6A-6C ... Overhang | projection part, 7 ... Electric contactor, 10 ... Rail drive part 11 ... welding torch, 14 ... storage container, 14a ... trunk, 15a ... first power cable, 15b ... second power cable, 16a ... first gas hose, 16b ... second gas hose, 17a ... first cooling medium hose, 17b ... second cooling medium hose, 18 ... cooling nozzle, 19 ... inspection device, 20 ... upper body part, 21 ... lower body part, 22 ... fixed rail installation jig, 25 ... annular seal member, 26a ... annular seal member, 26b DESCRIPTION OF SYMBOLS ... Seal piece, 27 ... Top cover, 28 ... Concave part, 29 ... O-ring, 30 ... Welding location, 32 ... Roller, 34 ... Gas groove, 35 ... Cooling medium groove | channel.

Claims (10)

An annular fixed rail fixed to the work piece;
A first annular groove and an annular conductive plate disposed on the fixed rail and formed along a circumferential direction of the fixed rail;
A first conduit and a first power cable connected to the first annular groove and the conductive plate, respectively, for supplying a working medium and power from outside the fixed rail;
A drive rail that is mounted on the fixed rail and circulates on the fixed rail along the circumferential direction of the fixed rail;
An electrical contact disposed on the drive rail and in sliding contact with the conductive plate;
A second power cable connected to the electrical contact;
A second conduit for taking out the working medium supplied to the drive rail side through the first annular groove to the outside of the drive rail;
An annular seal member for preventing the working medium from leaking outside between the fixed rail and the drive rail;
A welding torch to which the working medium and the electric power are supplied via the second power cable and the second conduit;
A moving mechanism that is provided on the drive rail and moves the welding torch so as to be close to and away from the welding location;
An automatic welding apparatus comprising:   2. The automatic welding apparatus according to claim 1, wherein at least two of the first annular grooves are spaced apart in the radial direction of the fixed rail. The base end surface side of the annular seal member is fixed to a portion of the drive rail facing the first annular groove,
The front end surface side of the annular seal member is inserted into the first annular groove so as to be slidable along with the circumference of the drive rail in a close state,
The automatic welding apparatus according to claim 1 or 2, wherein an end opening of the second pipe line communicates with the first annular groove. A second annular groove having a shape facing the first annular groove is formed in the drive rail,
The annular seal member is composed of an O-ring, and the pair of O-rings are arranged on the inner peripheral edge side and the outer peripheral edge side of the first annular groove and the second annular groove, respectively. 3. The automatic welding apparatus according to claim 1, wherein the automatic welding apparatus is disposed along the annular groove, and an end opening of the second pipe line communicates with the second annular groove. The first annular groove is hermetically sealed by a pair of annular seal members closely in the circumferential direction;
The second conduit is inserted between the pair of annular seal members;
The second pipe is provided with a seal piece that covers the periphery of the insertion portion of the second pipe inserted between the pair of annular seal members in a sealed state with respect to the pair of annular seal members. The automatic welding apparatus according to claim 1 or 2, characterized in that:   6. The moving mechanism according to claim 1, wherein the moving mechanism is configured to be movable in a radial direction of the fixed rail and a direction in which the welding torch is moved closer to and away from a welding location of the workpiece. The automatic welding apparatus of Claim 1.   The automatic welding apparatus according to claim 1, wherein the fixed rail is fixed to an upper lid surface that closes an upper opening of the workpiece.   The automatic welding apparatus according to any one of claims 1 to 6, wherein the fixed rail is supported and fixed on an installation jig fixed to a side surface of the workpiece.   9. The automatic according to claim 1, wherein at least two moving mechanisms are provided on the drive rail, and the moving mechanisms are configured to be movable independently of each other. Welding equipment.   The automatic welding apparatus according to claim 9, wherein an inspection device for inspecting a welding portion is placed on at least one of the moving mechanisms.

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