CA2089574A1

CA2089574A1 - Device and process for laser-welding a pipe

Info

Publication number: CA2089574A1
Application number: CA002089574A
Authority: CA
Inventors: Gerhard Krohnert
Original assignee: Gerhard Krohnert; Siemens Aktiengesellschaft
Current assignee: Siemens AG
Priority date: 1990-08-17
Filing date: 1991-07-23
Publication date: 1992-02-18
Also published as: JPH0777671B2; ES2052385T3; KR930701262A; JPH05509040A; BR9106765A; DE59101460D1; EP0543829B1; WO1992003249A1; DE4115561A1; EP0543829A1

Abstract

ABSTRACT

An apparatus for laser-welding a pipe (14) along its inner periphery with a probe (1) that can be introduced into the pipe (14) contains within the probe (1) means (73-76) with which part of a flow of protective gas that moves within the interior is split off before reaching an outlet opening (45) for a focused and deflected laser beam (59), and with an axial flow component that is directed towards the outlet opening (45) to the outer surface of the probe (1). By this means, the condensation of weld metal in the area of the outlet opening (45) and within the probe (1) is reduced.

Description

~ 2 ~ 8 9 ~i 7 4 i~365-3244 ' AN APPARATUS AND A PROCESS FOR LASER WELDING
A PIPE
.
The present invention relates to an apparatus and a process for laser-welding a pipe along its inner periphery using a probe that can be introduced into said pipe.

An apparatus for laser-welding a pipe with a probe that can be introduced into the pipe is known, for example, from EP-Al-0 300 458. The probe that is disclosed therein is connected through a light-wave guide to an Nd:YAG solid body laser. The laser light that emerges within the probe from one end of the light-wave guide is focused to a focal point that is located outside the probe by means of a lens system that consists of a plurality of lenses and a deflector mirror. The deflector mirror is inclined at an angle of 45 to the longitudinal axis of the probe, and it deflects the laser beam that is focused by the lens system and propagated within the probe between the lens system and the deflector mirror by 90. The deflected laser beam leaves the probe through a cylindrical outlet opening that is arranged radially in the probe housing. In addition, the probe is provided with a flow channel for a protective gas, this extending in the housing wall of the probe, opening out into the outlet opening, and flowing out into the space between the deflector mirror and the location of the weld.

In this known apparatus, the flow of protective gas is split into one secondary flow of gas that is directed into the interior of the probe, and into a secondary flow of gas that is directed towards the weld point. This leads to turbulence in the area of the outlet opening, with the result that weld vapour or weld plasma, and, particularly if a pulsed laser is used, droplets that are separated from the smelt, can be deposited on the .. . . .

- . ,.. ~ . ... -,,, ,' 2 ~ ~ 9 ~ ~ 4 deflector mirror and on the outlet opening and thus greatly reduce the service life of the probe.

It is the task of the present invention to describe an apparatus and a process for laser-welding a pipe along its inner periphery using a probe that can be introduced into said pipe, with which condensation of weld vapour on the deflector mirror and in the area of the outlet opening is greatly reduced.

According to the present invention, each of the above problems is solved using the features set out in claim 1 to claim 16. A
probe that can be introduced into the pipe, according to the present invention, contains the following:

a) at least one imaging element to focus and deflect a laser beam that is propagated within the probe, essentially along its longitudinal axis;

b) an outlet opening through which a deflected and focused laser beam generated by the imaging element emerges from the probe;

c) means that are arranged within the probe and used to guide a flow of protective gas right up to the outlet opening, at least a part of said gas flow flowing out through the outlet opening;

d) means by which some of the protective gas flow within the probe can be branched off before reaching the outlet opening and which can be guided, with an axial flow component that is oriented towards the outlet opening, to the outside surface of the probe.

Because of the foregoing, between the outer wall of the probe and the inner periphery of the pipe there is an axially oriented flow , 2a~9~7~
with which weld metal that separates from the weld smelt can be moved rapidly from the area of the outlet opening in the direction towards the head of the probe. This reduces the condensation of weld vapour in the area of the outlet opening and on the imaging elements.

In a preferred embodiment, within the probe there are means to r adjust the ratios of the quantities of the two secondary gas flows, in particular a reducing nozzle that is arranged in a flow channel for a secondary gas flow.

In one advantageous embodiment of the present invention, in order to guide the secondary gas flow that is branched off to the outside, there is a sleeve that surrounds the probe, said sleeve having on its inner surface an annular groove into which a flow channel for the secondary gas flow, which runs within the probe, opens out. This sleeve is provided with axial drillings that extend from the face surface of the sleeve that is proximate to the head of the probe as far as the annular groove. This results in a particularly homogenous axial flow of protective gas into the space between the probe and the pipe.

In another embodiment of the present invention, the condensation of vaporizing weld metal onto the deflector mirror is additionally reduced in that there are means with which a secondary gas flow is split off from a flow of protective gas within the probe to the outlet opening and guided by channels within the probe.

In particular, provision is made such that the channels open out into a recess in the deflector mirror, said recess being located directly opposite the outlet opening.

In a further advantageous configuration of the present invention there is an imaging element that generates a laser beam that is .. . . . .

focused to a point located outside the probe, the direction of propagation of this beam being inclined to the longitudinal axis.
An imaging element is understood to be an optical component with which the direction of propagation of a laser beam can be altered, i.e., a plane mirror, a mirror with a curved surface, or a lens.

Because of the inclined decoupling of the deflected laser beam it has been made possible to avoid having the outlet opening directly opposite the weld point, so that the condensation of weld vapour in the area of the outlet opening and in the interior of the probe is reduced.

The angle of inclination of the deflected laser beam relative to the longitudinal axis of the probe amounts preferably to 60 to 80. This ensures that, even if there is a large outlet opening for the laser light, for all practical purposes there is no reflection of the laser light back into the interior of the probe.

In a preferred configuration of the present invention, within the probe there is a deflector mirror with a flat mirror surface to deflect the focused laser beam; the surface normal relative to the longitudinal axis of the probe subtends an angle that is greater than 45, and is preferably between 50 and 60~.

In a further configuration of the present invention the apparatus incorporates a concave deflector mirror that is provided both for focusing and also deflecting the laser beam that is propagated in the centre along the longitudinal axis of the probe. Because of this, the cross-section of the laser beam that strikes the deflector mirror is enlarged relative to the embodiment with a flat deflector mirror. The radiation power that strikes each unit of area of the deflector mirror, and thus the local heating of the deflector mirror, are both reduced thereby.

2089S7~

In a further preferred embodiment, in order to improve the imaging characteristics of the imaging systems, in a probe that is optically coupled through a light-wave guide with a laser, between the end of the light-wave guide and the concave deflector mirror there are means to collimate the laser beam that emerges from the light-wave guide.

In particular, a deflector mirror that is of a material with greater thermal conductivity, preferably copper Cu, is used.
Because of this, the thermal load on the deflector mirror is reduced even further and the durability of the reflective layer is improved even more.

In a preferred embodiment, in order to decouple the deflected a laser beam from the probe, there is an outlet opening that imparts an axially oriented flow component to a flow of protective gas that emerges from it.

A process for laser-welding a pipe along its inside periphery includes the following features:

a) a laser beam that is deflected and focused onto a point on the inside periphery of the pipe, and which is propagated essentially along its longitudinal axis, is generated within a probe that is introduced into the pipe, essentially along its longitudinal axis;

b) the laser beam emerges from the probe through an outlet opening;

c) a flow of protective gas is fed into the probe, and this flows within the interior of the probe towards the outlet opening, when .:

8~7~

d) some of the flow of protective gas flows out of the outlet opening, and e) some is split off before it reaches the outlet opening and conducted, with an axial flow component, into the space between the pipe and the probe.
.
A further reduction of weld-metal condensation on the deflector mirror is achieved in that, within the probe, an additional secondary flow of gas with an axially oriented flow component is split off from the protective gas flowing towards the outlet opening, within the probe, at the outlet opening.

In a preferred version of the process, the laser beam is deflected obliquely to the longitudinal axis of the probe.

In a further advantageous version of the process a solid body laser that operates in cw-mode is used. This prevents the separation of droplets from the weld-metal smelt.

One embodiment of the present invention is described in greater detail below on the basis of the drawings appended hereto. These drawings show the followinq:

Figure 1 is a cross-sectional drawing of the probe according to the present invention that is introduced into the pipe;

Figures 2, 3, and 4 each show, at larger scale, advantageous configurations of the probe in the area of the deflection device.

As shown in figure 1, a probe 1 according to the present invention incorporates a centring unit 2, a deflector unit 4, a focusing unit 6, and a drive unit 8, all of which are arranged one behind the other along a longitudinal axis 10 of the probe 1.
The probe 1 is introduced into a pipe 12 upon which work is to be 7 L~
.
done, when its head section that contains the deflector unit 4 extends into the interior of a sleeve or slip pipe 14 that has been inserted into the pipe 12 that is to be welded to the pipe 12.

The centring unit 2 includes a shaft 21 that, at the head end of the probe 1 is,rotatably supported through ball bearings 22 on the deflector unit 4 and fixed in the axial direction by means of the collar nut 23. The centring unit incorporates at least three rollers 24, of which only two are shown in the drawing; these are each supported flexibly through a pivot joint drive with two links 25 so as,to be sprung. The two links 25 form two sides of an equilateral~triangle and rest in a pivot joint 26 that accommodates the roller 24. The two links 25 are similarly supported on the shaft 21 through the pivot joint 28 so that they can be moved on the shaft 21. One of these two pivot joints 28 is force-fitted to a moveable flange 29 that surrounds the shaft 21. A further flange 30 is secured to the shaft at its unattached end. Between the flange 29 and the flange 30 there is a coil spring 31 so that a movement of the roller 26 that is directed radially inwards against the action of this coil spring 31 results. A spacer sleeve 27 that is arranged on the shaft 21 prevents the pivot joint 26 from closing completely and makes it simpler to introduce the probe 1 into the pipe 12.

The deflector unit 4 comprises a cylindrical housing 40 within which there is a deflector mirror 41. The deflector mirror 41 consists of a solid cylindrical copper block that has on its end that is proximate to the centring unit 2, a flange-like wider section 42 that serves to fix the deflector mirror 41 axially with a collar nut 43. At its end that is remote from the flange-like wider section 42, the copper block has a face surface that is oriented so as to be inclined to its longitudinal axis. This face surface is covered with a reflective coating and forms a mirror surface 44. As an example, the reflective coating can be .... .. . . .

2 ~ ~ 9 ~ ~ ~

dielectric coating, preferably titanium nitride TiN, or a metal coating, preferably gold Au that is applied as vapour. In addition, the reflective coating can also be given a protective layer of quarz.

The mirror surface 44 is so arranged within the probe 1 that its normal line 18 subtends an angle ~1 with the longitudinal axis 10 of the probe, this angle ~1 being greater than 45, and preferably between 50 and 60~. A laser beam that is propagated in the centre along the longitudinal axis 10, and which strikes the mirror surface 44 is thus deflected obliquely forwards. The middle ray of the deflected laser beam 59 emerges from the housing 40 through an outlet opening 45 at an angle ~2 between 60 and 80 relative to the longitudinal axis 10. In the example shown in figure 1, a drilling that is also inclined relative to the longitudinal axis 10 is provided as the outlet opening 45.

The deflector mirror 41 is also secured against rotating within the housing 40, by a groove 46 that extends parallel to its longitudinal direction 10 and by a set pin 47.

Using a solid copper block as a deflector mirror 41 reduces the heating of the mirror surface by the laser beam 58 and increases the service life of the mirrored surface.

On its end that is remote from the deflector mirror 41 the housing 40 of the deflector unit 4 has a ring gear 48 on its inner periphery in which a pinion that is driven from the drive unit 8 engages. This pinion 49 is connected to a flexible shaft 50 that is coupled with a drive shaft of an electric motor 81 that is arranged within the drive unit 8. The housing 40 is caused to rotate by the pinion 49 that is driven by the electric motor 81, so that the point F at which the laser beam 59 that emerges strikes the interior surface of the sleeve pipe 14 that 2 ~ 7 ~

i8 to be welded is moved in the peripheral direction and describes a circular path.

The focusing unit 6 is arranged between the deflector unit 4 and the drive unit 8; the housing 60 of this unit is connected rigidly to the housing 80 of the drive unit 8. The housing 60 incorporates a central drilling 61 in which, on the side that is proximate to the drive unit 8, a sleeve 62 to accommodate a light-wave guide 63 is installed. The unattached end 64 of the light-wave guide 63 opens out in the drilling 61 and is centred axially by the sleeve 62. The other end of the light-wave guide 63 is coupled to a laser (not shown herein), preferably a solid body laser, in particular an Nd:YAG solid body laser.

At the end of the focusing unit 6 that is proximate to the deflector mirror 41 there is a focusing element, preferably a lens 65 or a system of lenses; this focuses a divergent laser beam 57 that emerges from the end 64 of the light-wave guide 63.
The position of the focus F of the laser beam 59 can be adjusted by changing the distance between the end 64 and the lens 65.

The housing 40 encircles the housing 60 in the area of the lens 65, and is supported on the housing 60, so as to be able to rotate, by the ball bearing 66 and the spacer sleeve 68, and is connected with it axially by a force fit. Thus, rotation of the pinion 49 causes only the housing 40 that supports the deflector unit 41 to rotate. The lens 65 and the light-wave guide 63 do not rotate when this is done.

The lens 65 is supported by a plurality of housing elements 60a, 60b, 60c that are connected to each other by force fit and that do not rotate; these extend into the interior of the housing 40.
The housing section 60b and 60c form an almost V-shaped space 71 that is connected through the drilling 78a to a flow channel 70 that is arranged within the housing section 60c. This flow 20(~S7~

channel 70 conducts protective gas, for example argon, into the space 71 that is located between the lens 65 and the unattached end 64 of the light-wave guide 63. A reducer nozzle 77 that restricts its cross-section is installed in the flow channel 70.
The protective gas flowing in the flow channel 70 above the reducer nozzle 77 passes through the drillings 78a into the space 71, leaves this space 71 through additional drillings 78b within the housing section 60b, enters an annular channel 79, and passes from there into the space 72 located between the lens 65 and the deflector mirror.

The protective gas that passes around the lens 65 and flows past the deflector mirror 41 in this way leaves the probe through the outlet opening 45. This means that not only is the weld point ventilated with protective gas but, in addition, there is a cooling effect felt at the imaging elements that are acted upon by the laser beams 57 and 58. In addition, the flow of protective gas that is directed towards the outside prevents any welding vapour from condensing on the deflector mirror.

In the example shown in this figure, the outlet opening 45 is formed in the example shown in this figure by a drilling in the wall of the housing 40 that is inclined forward. This means that an additional axial flow component is imparted to the protective gas flowing through the outlet opening 45 and this enhances the removal of weld vapour from the area of the outlet opening 45.

In addition, the flow channel 70 is connected to a flow channel 73 that branches off radially and which opens out into an annular groove 74 of a sleeve 75 that surrounds the housing 60. The sleeve 75 forms a collar-like wider section of the probe 1. The sleeve 75 is provided with a plurality of drillings 76 that are parallel to the longitudinal axis 10 of the probe 1, and these form a connection to the annular groove 74. A radial secondary flow of gas is split off from the flow of protective gas that , .

.. ~ , , .

~ `; 20~9~7~

enters the flow channel 70, starting from the drive unit 8 through the transverse channel 73; this is deflected in the annular channel 74 in an axial direction and emerges at the face surface of the sleeve 75 that is proximate to the deflector unit 4 in the channel that is located between the pipe 12 and the outer casing of the probe l. This ensures the maintenance of an effective atmosphere of protective gas in the area of the weld location. In addition, the weld vapour that forms during the welding process is effectively removed from the weld location by the axial flow and the danger that weld vapour will condense in the interior of the probe 1 is reduced.

In order to adjust the ratio of the quantities between the flow of protective gas flowing within the probe 1 to the deflector mirror 41 and the flow of protective gas that is exhausted radially to the exterior there is a reducer valve 77 installed in the flow channel 70.

The housing 80 of the drive unit 8 is provided at the end that is remote from the focusing unit 6 with a thrust tube through which the protective gas is moved to the probe, and which accommodates the light-wave conductor 63 and the power lines 82 that are required to supply the electric motor 81 with electrical power.

In the example shown in figure 2, a deflector mirror 41 has a central drilling 51 that, starting from the flange-like wider section 42, passes into the interior of the deflector mirror 41, and is connected through a drilling 52 that runs obliquely to the outside to emerge on the mirror surface 44 in the area of the outlet opening 45, in a recess 56. The flange-like wider section 42 is provided on its face surface that is proximate to the collar nut 43 with a plurality of radial grooves 54. These radial grooves 54 form a connection between the central drilling 51 and drillings 55 that extend radially to the outside within the collar nut 43.

: : 2~9~7~
~ .
The flow of protective gas that spreads over the deflector mirror 41 within the housing 40 is thus split once again before leaving the housing through the outlet opening 45. A secondary flow of gas passes through the drilling 52 into the drilling 51 in the deflector mirror 41 and passes out of the probe 1 through the drillings 55 within the collar nut 43. Cooling of the deflector mirror 41 is improved and its service life is extended because of this gas flow in the interior of the deflector mirror 41.

The outlet opening 45 and the recess 56 are immediately adjacent to each other so that there is no dead space within which there is no flow of protective gas. Such dead spaces between the deflector mirror 41 and the wall of the housing within which the outlet opening 45 is arranged would lead to turbulence and thus to increased condensation of weld metal on the mirror surface 44.

Figure 1 also shows that the laser beam 59 that emerges from the probe 1 impacts at point F, obliquely to the interior surface of the pipe 14. Between the normal line 16 that extends from the focal point F, perpendicular to the inner surface of the pipe 14, and the mid-beam of the emerging laser beam 59 there is preferably an angle B3 that is between 10 and 30.

In the example shown in figure 3, the deflector unit 4 incorporates a deflector mirror 141, the mirror surface 144 of which is curved so as to be concave. In this embodiment, the deflector mirror 141 serves both to deflect the laser beam 58 that is propagated within the probe and also to focus this laser beam 58 at a focal point F that is located outside the probe 1.
In this embodiment, a lens system is no longer required to focus the laser beam that emerges from the light-wave guide.

As is shown in figure 4, a collimator lens 65a can be incorporated ahead of a concave deflector mirror 141a and this collimates a laser beam 57 that emerges from the light-wave guide - ; 2~9~7~
.
63 to a parallel bundle 58a that i5 then focused and deflected by the deflector mirror 141a. Thus, given an equal distance of the focus F from the deflector mirror 141a, it is possible to achieve a greater distance between the light-wave guide 63 and the deflector mirror 141a.

.. ;, . - .

Claims

CLAIMS:

An apparatus for laser-welding a pipe (12, 14) along its inner periphery, with a probe (1) that can be introduced into the pipe (12, 14), said probe incorporating the following:

a) at least one imaging element (41, 65) for focusing and deflecting the laser beam (57) that is propagated within the probe (1), essentially along its longitudinal axis (10);

b) an outlet opening (45) through which the laser beam (59) that is generated, deflected and focused by the imaging element (41, 65) emerges from the probe (1);

c) means (70, 78a, 78b, 79) that are arranged within the probe (1) that guide a flow of protective gas as far as the outlet opening (45);

characterized in that d) some of the flow of protective gas flows out through the outlet opening (45) and e) means (73, 74, 76) are provided, with which part of the protective gas flow that moves within the probe (1) can be split off before it reaches the outlet opening (45) and guided to the outside surface of the probe (1) with an axial flow component that is oriented towards the outlet opening (45).
2. An apparatus as defined in claim 1, characterized in that means (77) to adjust the proportional quantities of the two secondary flows of gas are provided within the probe (1).
3. An apparatus as defined in claim 2, characterized in that a reducer valve (77) is provided in a flow channel (70) for a secondary gas flow.
4. An apparatus as defined in one of the claims 1 to 3, characterized in that a sleeve (75) that surrounds the probe (1) is provided for guiding the secondary gas flow that branches off to the outside, this having an annular groove (74) on its inner surface, into which a flow channel (73) for the secondary gas flow opens out, this flow channel (73) running within the probe (1) and being provided with axial drillings (76), these drillings extending from the face end of the sleeve (75) that is proximate to the head of the probe (1) as far as the annular groove (74).
5. An apparatus as defined in one of the claims 1 to 4, characterized in that means are provided with which a secondary gas flow can be split off from the flow of protective gas that moves within the probe (1) at the outlet opening (45) and then guided by channels (53, 54, 55) that lie within the probe (1).
6. An apparatus as defined in claim 5, characterized in that the channels (53, 54, 55) open out into a recess (56) in the deflector mirror (41, 141), said recess being located immediately opposite the outlet opening (45).
7. An apparatus as defined in one of the preceding claims, characterized in that it incorporates an imaging element (41, 65) that generates, focuses and deflects the laser beam (59) at a focal point (F) that is located outside the probe (1), the direction of propagation of this laser beam (59) being oblique to the longitudinal axis (10).
8. An apparatus as defined in claim 7, characterized in that the angle of inclination (.beta.2) of the mid-beam of the deflected laser beam (59) relative to the longitudinal axis (10) lies between 60 and 80° at the centre.
9. An apparatus as defined in claim 7, characterized in that the probe (1) contains a focusing unit (6) with at least one lens (65), and a deflector unit (4) with a deflector mirror (41) with a flat mirror surface (44), the surface normal line (18) of which subtends an angle (.beta.1) that is greater than 45° with the longitudinal axis (10) of the probe (1).
10. An apparatus as defined in claim 9, characterized in that this angle (.beta.1) lies between 50 and 60°.
11. An apparatus as defined in claim 7 or claim 8, characterized in that the probe (1) incorporates a concave deflector mirror (141) that is provided both for focusing and for deflecting the laser beam (57).
12. An apparatus as defined in claim 11, characterized in that in a probe (1) that is optically coupled to a laser through a light-wave guide (63), means to collimate the laser beam (57) that emerges from the light-wave guide (63) are provided between the end (64) of the light-wave guide (63) and the concave deflector mirror (141).
13. An apparatus as defined in one of the claims 9 to 12, characterized in that the deflector mirror (41, 141) is of a material having a high level of thermal conductivity.
14. An apparatus as defined in claim 13, characterized in that the mirror surface (44, 144) of the deflector mirror (41, 141, respectively) has gold Au vaporized onto it.
15. An apparatus as defined in one of the claims 7 to 14, characterized in that in order to decouple the deflected laser beam (59) from the probe (1), an outlet opening (45) is provided, this outlet opening imparting an axially directed flow component to a flow of gas that flows out of it.
16. A procedure for laser-welding a pipe (12, 14) along its inner periphery, this having the following features:
a) a laser beam (59) that is deflected and focused on a point on the inner periphery of the pipe (14) is generated from a laser beam (57) that is propagated, essentially along its longitudinal axis, within a probe (1) that is introduced into the pipe (12, 14).

b) the laser beam (59) emerges from the probe (1) from the outlet opening (45);

c) a flow of protective gas is delivered to the probe (1), this flowing into the interior in a direction towards the outlet opening (45);
characterized in that d) some of the flow of protective gas flows out through the outlet opening (45) and e) some of the flow is split off before it reaches the outlet opening (45) and is conducted with an axial flow component into the space that is located between the pipe (12, 14) and the probe (1).
17. A process as defined in claim 16, characterized in that an additional secondary gas flow with an axially directed flow component is split off from the flow of protective gas that spreads within the probe (1) to the outlet opening (45), this being done within the probe, this then spreading within the probe (1).
18. A process as defined in one of the claims 16 or 17, characterized in that the laser beam (57) is deflected obliquely to the longitudinal axis (10) of the probe (1).
19. A process as defined in one of the claims 16 to 18, characterized in that a solid body laser that operates in cw-mode is used.