NL2010714C2 - METHOD FOR CONNECTING TUBES. - Google Patents

Description

METHOD FOR CONNECTING TUBES

The present invention has for its object to provide a method for joining high-quality pipes in technical installations. The method according to the invention is characterized by the following steps: a) Applying an annular casing around mutually facing ends of the tubes; b) Welding the annular casing to each of the tubes along its circumference.

The method according to the invention is suitable both for connecting new pipes and for repairing existing pipes. The unique application of an annular envelope around the pipe ends has several advantages. An important advantage is that machining on the tubes is no longer necessary as welding preparation. Another important advantage is that mutual tilting or angular rotation of the existing tubes can be compensated for by tension-free connection by means of the annular enclosure. The annular envelope is reliably welded to each of the tubes all around.

In a specific preferred embodiment, the method according to the invention comprises the following steps for replacing a coupling between connected pipes: disconnecting the pipes by removing the coupling connecting the pipes, placing a customized further pipe between the disconnected tubes, arranging annular enclosures around mutually facing ends of the further tube and the disconnected tubes; and welding the annular enclosures to each of the tubes along their circumference.

In the specific preferred embodiment, the method according to the present invention is particularly suitable for carrying out repair work on pipes in use, for example pipes connected to district heating. District heating is a system in which every user is supplied with heat to the home via a network of water pipes. The heat is transferred via a heat exchanger and hot water from the industry. It is known to use tension-resistant couplings for the pipes connected to district heating to connect these pipes to each other. It is a known problem of these tension-resistant couplings that they will leak over time. This is mainly caused by damage to the coupling that is difficult to isolate with rising groundwater. With the aid of the method according to the invention, the tension-resistant couplings can be replaced by the annular envelopes, which can be insulated well. Tests have furthermore shown that tubes connected by the method according to the invention can withstand a higher tensile force than tubes which are connected in the traditional way by means of a tension-resistant coupling.

According to a first preferred embodiment, the method comprises the steps of applying a further casing to at least one of the ends of the tubes facing each other for cooperation with the annular casing, welding the further casing onto the tube around its circumference and welding together the annular envelope and the further envelope along its periphery. The first preferred embodiment makes it possible to connect different types of tubes to each other.

According to a further elaboration of the first preferred embodiment, a further casing is selected, the ends of which have a different diameter and wherein the narrowest end is received in the annular casing. The further elaboration makes it possible to connect tubes of different diameters with each other.

According to a practical preferred embodiment, the tubes are made of steel and the annular envelope is made of higher alloy steel. By means of this practical preferred embodiment, a very strong and reliable weld connection is obtained.

In a first preferred embodiment, the welding is carried out by means of a welding device which is suitable for orbital welding. The orbital welding process can be performed automatically.

According to a very advantageous preferred embodiment, the welding device is provided with a closed welding head. The method according to the invention is hereby suitable for use in closed spaces, for example underground use. The current Health and Safety legislation is complied with, which prescribes that no open fire may be used in a closed room.

The welding device is preferably suitable for welding according to the TIG process. With TIG there is an arc and a fixed electrode where the distance to the material remains constant. The TIG process is known for the good and high-quality resulting weld.

According to a very reliable embodiment, the welding device is provided with a break-through sensor. With the help of a break-through sensor, the break-through security can be monitored and a high-quality weld connection can be guaranteed.

According to a further practical preferred embodiment, the method according to the invention further comprises the step of applying insulating material around the annular envelope. The connection hereby obtains improved quality and a longer service life.

In a further elaboration of the further preferred embodiment, the method comprises the following steps: applying shell-shaped insulating material around the annular envelope and the adjacent tubes; and applying waterproof material around the shell-shaped insulating material. A moisture-resistant connection is hereby obtained with a very long service life.

The invention will be further elucidated with reference to the annexed figures, in which:

The invention will now be described in more detail with reference to the figures.

Figure 1A shows the connection of a set of tubes according to the prior art;

Figure 1B shows the set of tubes in cross-sectional view;

Figure 1C shows a tension-resistant coupling for use in the method according to the prior art;

Figure 2A illustrates the connection of a first set of tubes according to the method according to the invention;

Figure 2B shows the first set of tubes in connected condition in a first orientation;

Figure 2C shows the first set of tubes in connected condition in a second orientation;

Figure 3A illustrates the connection of a second set of tubes according to the method according to the invention;

Figure 3B shows the second set of tubes, partly in sectional view; and

Figures 4A and 4B illustrate the use of an orbital welding device in the method according to the invention in a schematic view and a partial cross-sectional view, respectively.

Figure 1A shows a schematic view of a first set of tubes 1,2, which are connected using the method according to the prior art. In the top view the tubes 1 and 2 are directed towards each other with the loose ends. A tensile-resistant coupling 10 is then fitted around the ends of each of the tubes. In the bottom view, the set of tubes with tension-resistant coupling is shown in assembled position. Figure 1C illustrates tensile-resistant coupling 10 in more detail. Tensile-resistant coupling 10 is preferably provided with means for clamping body 11 around the tubes. In the preferred embodiment shown, said means comprise two opposite plates 12 and 13 which are arranged on the circumference of body 11 and by means of clamping means, for example screws, can be moved toward each other to reduce the diameter of body 11.

Figures 2A to 2C illustrate the connection of set of tubes 1,2,3 using the method according to the invention. The set of tubes comprise a first, second and third tube, which must be interconnected. To this end, an enclosure 30 is provided around the ends of each pair of tubes 1, 2 and 2, 3 and then welded tightly around the circumference using a welding device suitable for orbital welding. This is illustrated in Figure 2A. Figure 2B shows the assembled tubes in a first orientation, in which the assembled tubes run substantially in line with each other. Figure 2C shows the set of tubes in a second orientation, in which tube 3 is at an angle α with tube 2 and also at an angle β with tube 1. In both cases, four weld seams L1, L2 and L3, L4 are sufficient around each weld transition ring 30 to be connected to each tube on both sides.

A suitable material for weld transition ring 30 is a material with an equal or higher quality of the material of the tubes to be connected. Preferably, the weld transition ring 30 comprises higher alloyed material, ie with a higher tensile strength than tubes 1, 2 and 3. If tubes 1, 2 and 3 are made of, for example, steel 37, then steel 37, but preferably steel 42 or higher is a suitable material for weld transition ring 30.

The method according to the invention can be applied in many situations for joining high-quality pipes in various technical installations. The present invention is particularly suitable for use in installing and repairing district heating, water pipes and central heating pipes. Starting from the situation in figures 1A to 1C, the tension-resistant coupling 10 is removed and replaced by a tube 3 and two annular envelopes 30.

If desired, an insulating material can be applied to all pipes. In the preferred embodiments shown, shell-shaped insulating material 6, 7 is illustrated, which is surrounded by waterproof material. After connecting the tubes, the insulating material can be applied around the annular envelopes 30 and the adjacent tubes. Suitable shell-shaped insulating material is known in the art and can be applied over the annular envelopes 30 but not over the tension-resistant couplings 10.

Figure 3A illustrates a second set of tubes 4, 5 that are connected by the method according to the invention. Tube 4 is a tube of a stiffer material than tube 5, for example carbon steel. Tube 5 is made of a more flexible material than tube 4, for example stainless steel. Figure 3B illustrates the connection of the second set of tubes, partly in sectional view.

Tubes 4 and 5 are connected at ends facing each other by means of an annular envelope 20B and a further envelope 20A. The further enclosure 20A is a reducer whose ends have a different diameter. The narrowest end of the reducer 20A is selected such that it can be received in the ring 20B. Ring 20B fits around one of the tubes, in this example tube 4, while the end with the largest diameter of the further envelope 20A fits around the other tube 5. Figures 3A and 3B show the second set of tubes both in disassembled parts and in assembled or assembled condition. According to the invention, three weld seams are now applied: one weld seam L1, which connects ring 20B to tube 4, one weld seam L3, which connects adapter 20A to tube 5, and a weld seam L2, which connects the adapter 20A and ring 20B. All welding seams run along the circumference of the tubes and / or the enclosures and are preferably applied using a welding device suitable for orbital welding.

A suitable material for reducer 20 A and weld transition ring 20B is a material of equal or higher quality than the material of the pipes to be connected 4, 5. Preferably, reducer 20 A and weld transition ring 20B comprise higher alloyed material, ie with a higher tensile strength than tubes 1 and 2. If tubes 1 and 2 are made of, for example, steel 37, then steel 42 is, for example, a suitable material for the weld transition ring. A suitable material for enclosure 20 in this example is 309 material: an alloy with stainless steel.

Various types of welding devices for orbital welding are known in the relevant field. A suitable welding device preferably uses the TIG process (tungsten electrode with an inert gas), wherein the base metal is melted and itself forms the weld. No welding consumables are required, so that a closed welding head can be used.

During welding, an arc forms between the tungsten electrode and the workpiece. To start the arc, the shield gas is ionized so that a path is created for the welding current. A capacitor sends current into the arc so that the high voltage drops to a point where the energy supply can be regulated. The energy supply responds to the demand for power and provides power to maintain the arc. With orbital welding, the arc moves during a welding process in a rotating path around the tubes and the enclosure.

The welding device is preferably arranged for automatic welding. The welding device preferably uses a process in which the welding parameters can be set largely automatically. The welding device starts with parameters that are conservatively selected and then slowly increases the current. A point is then searched for where the penetration occurs. This method is also known as Automatic Penetration Control (APC). The welding device is preferably provided with a break-through sensor which monitors the break-through reliability by measuring the natural frequency of the melting bath. These frequencies are a good indication of the characteristics of the melt bath dynamics. If the bath has full penetration, i.e. the weld has completely melted, the desired frequency is involved. By varying the current, the penetration can be controlled. The APC in combination with the through-flow sensor provide a high-quality weld with the great advantage that it is fairly easy to find the right welding parameter and set up the machine correctly. One of the applicants, Dutch Innovative Welding B.V. in Rijssen, the Netherlands, markets a welding device with the above-mentioned properties under the name of ServoTIG welding machine, which is furthermore provided with the above-mentioned welding sensor.

Figures 4A and 4B illustrate application of an orbital welding device 100 in the method according to the invention. Three situations from the welding process are shown in a schematic view and a partial sectional view. In situation S1 the tube, 1 and 3, respectively, and ring 30 are clamped in the open head 110 of the welding device 100. Head 110 is then closed in the direction of arrow A. In situation S2, protective gas is introduced into the head. This creates a "room" in an enclosed environment with an atmosphere in which welding can take place. Situation S3 indicates the start of the welding process. The electrode rotor 120 rotates in the head 110 in the direction of arrow B about the tube 1, 3, respectively, with ring 30 and welds them together.

Finally, the invention is of course not limited to the described and shown preferred embodiments, but extends to any embodiment that falls within the scope of the scope of protection, as defined in the claims and viewed in the light of the foregoing description and accompanying drawings.

Claims (11)

A method for connecting pipes, characterized by the following steps: applying an annular envelope around mutually facing ends of the pipes; welding the annular envelope to each of the tubes along its circumference. Method according to claim 1, for replacing a coupling between connected pipes, comprising the following steps: disconnecting the pipes by removing the coupling connecting the pipes, placing a customized further pipe between the disconnected tubes, arranging annular enclosures around mutually facing ends of the further tube and the disconnected tubes; and welding the annular enclosures to each of the tubes along their circumference. 3. Method as claimed in claim 1 or 2, wherein the method comprises the steps of arranging a further casing on at least one of the ends of the tubes facing each other for cooperation with the annular casing, welding the further enclosure around its circumference and welding the annular enclosure and the further enclosure along its circumference. A method according to claim 3, wherein a further casing is selected, the ends of which have a different diameter and wherein the narrowest end is received in the annular casing. A method according to any one of the preceding claims, wherein the tubes are made of steel and wherein the annular casing is made of higher alloy steel. Method according to one of the preceding claims, wherein the welding is carried out by means of a welding device that is suitable for orbital welding. Method according to claim 6, wherein the welding device is provided with a closed welding head. 8. Method as claimed in claim 6 or 7, wherein the welding device is provided with a break-through sensor. A method according to claim 6, 7 or 8, wherein the welding device is suitable for welding according to the TIG process. The method of any one of the preceding claims, wherein the method further comprises the step of applying insulating material around the annular envelope. The method of claim 10, wherein the method comprises the steps of: applying shell-shaped insulating material around the annular enclosure and the adjacent tubes; and applying waterproof material around the shell-shaped insulating material.