WO2005021200A1 - A method of attaching a sheet panel to a metal structure and a stud welding system for this - Google Patents

Abstract

The invention concerns a method of attaching a sheet panel onto a metal structure by placing a number of studs through the sheet material and welding said studs onto the metal structure by using a stud-welding system in which the stud is positioned in a stud-welding gun, where the method comprising the steps of penetrating a stud through the sheet material and positioning a stud-welding gun of the stud-welding system on the stud, providing an electrical contact between a stud and the underlying metal structure, and then applying a welding current to the stud, and retracting the stud providing a gap between the stud and the metal structure and establishing a welding arc, and then forcing the stud against the metal structure after a predetermined duration of time.

Description

A METHOD OF ATTACHING A SHEET PANEL TO A METAL STRUCTURE AND A STUD WELDING SYSTEM FOR THIS

The present invention relates to a method of attaching a sheet panel onto a metal structure by placing a number of studs through the sheet material and welding said studs onto the metal structure by using a stud-welding system, a stud for use by attaching a sheet panel onto a metal structure comprising a head with a protruding pin member and a stud welding gun for welding on studs comprising spring-loaded stud holding means for receiving a stud and pinching this stud through a sheet panel and forcing the stud towards an underlying metal structure.

In steel structures covering panels of fibrous insulation material may often be fitted in order to provide fire, thermal and/or noise insulation, e.g. of steel structures in building constructions, metallic ventilation ducts, steel chimneys/stacks, pipes or metal structures for maritime purposes. This insulation is often required in order to provide an effective fire protection.

In order to fit an insulating layer to a metal structure, typically a steel structure, it is known to weld a number of needle pins onto the steel surface. On these needles, panels of fibrous insulation material are mounted. When the panels are mounted, the needles are pinched through the panel and a locking disc is secured to the ends of the pins, which protrude through the fibrous insulation panels. In order to ensure that the insulation panels are properly secured, the needle pins must be positioned relatively close.

This method of mounting the insulation layer is extremely time-consuming, due to the excessive amount of needle pins, which must be secured to the steel structure. For the personnel fitting the insulation panels, there is a risk of being injured on the protruding needle pins or spikes. Moreover, the panels must be mounted with tremendous precision since they cannot be moved sideways once they have been pressed onto the needles. It is of utmost importance that the panels must be closely fitted to each other. This means that there is a risk that a considerable amount of insulation panels must be ejected and remounted/refitted if they have not been properly mounted in the first attempt. Moreover, this method makes it difficult - if not impossible - to fit a fire insulation onto surfaces in a confined space.

Another method of attaching fire insulation to a steel structure is to use welding studs pinched through an insulation panel, which are fitted to the surface of the structure, and then welded to the structure by use of a welding gun. By this method, it is possible to position the attachments in relation to the assembling joints of the fibrous insulation panels. The mounting of the insulating panels is also easier and the danger of being injured on the needles is eliminated.

The studs are pinched through the insulation panels or layers and into contact with the underlying steel surface at desired positions, i.e. away from the joining lines between the panels. Thereby, the amount of attachment points may be reduced and the mounting is easier and less time-consuming. This method is also applicable to rolls of insulation material.

However, this method is significantly less applicable to non-conducting, corrosion protected surfaces, such as painted surfaces, since the welding must bum away the paint before a metallic contact between the steel and the stud can be established. The welding attachment may be of a poor quality due to residues in the welding areas, since the worker needs to remove the paint prior to performing the welding operation. Furthermore, the corrosion protective layer cannot be re-established if it is damaged. The method demands a great power from the worker in order to shoot the studs into the panel and they may fall out or become damaged during the penetration due to the high resistance.

Such working procedures are costly, in particularly in maritime applications where up to 80% of the costs for mounting the insulation are labour related costs. In summary, in the known method, any paint or rust scales must initially be removed, e.g. by grinding, before the welding can take place. This results in inaccuracies since many areas are left exposed without any protection against corrosion.

In this light, it is an object of the present invention to provide a method and a stud welding system, which allows for a better attachment of insulating panels onto a metal structure and to ensure a proper metallic contact for the welding process. Moreover, it is an object of the invention to provide a method and a system, which is less labour intensive and thus allows for a more cost effective way of attaching insulating panels .

The object is achieved by a method of attaching one or more sheet panel onto a metal structure by placing a number of studs through the sheet material and welding said studs onto the metal structure by using a stud-welding system in which the stud is positioned in a stud- welding gun, said method comprising the steps of penetrating a stud through the sheet material and positioning a stud-welding gun of the stud- welding system on the stud, providing an electrical contact between a stud and the underlying metal structure. A welding current is applied, and the stud is retracted providing a gap between the stud and the metal structure and establishing a welding arc, and forcing the stud against the metal structure after a predetermined duration of time.

The electrical contact may be provided by positioning a distal end of the stud immediately above the metal structure, whereby a high frequency voltage is applied to the stud, preferably between 6 kV to 14 kV with a frequency of 100 kHz to 200 kHz. The high frequency high voltage power supply is similar to the one known from a TIG (Tungsten Inert Gas) welding system. The gap is preferably between the distal end of the stud and the metal structure between 0.1 mm to 1 mm, preferably approx. 0.5 mm, and the high frequency voltage is applied for a sufficient amount of time to establish a welding arc whereafter the welding current is applied, preferably within the interval of 0.25 to 1 second. By establishing an electrical contact by applying a high-frequency high-voltage on the stud when the stud is positioned immediately above the underlying metal structure, a cleaning of the surface to which the stud is to be welded can be obtained. Any coating or other impurities may be burned off and a small drawn arc may be created between the distal end of the pin of the stud and the surface of the metal structure. Subsequently, the stud welding process may be performed.

According to the invention, the attachment of panels may be carried out in a single operation and with a better precision, since the panels may be placed in position before the attachment points are established. By the hitherto known techniques, the spikes must be welded onto the exposed surface before the panels are pressed into position. Moreover, by the method according to the invention, there are no exposed areas on the steel surface.

This method is particular advantageous for attachment of fibrous insulation to steel constructions in maritime insulation and fire insulation of steel columns and girders. The method is also advantageous in that insulation panels in certain occasions may be attached to confined spaces of a steel structure since a considerably smaller amount of space is required for performing the attachment.

During the application of the high-frequency voltage, the electrical conductivity is measured by measuring means and when the electrical conductivity exceeds a predetermined value the surface coating is sufficiently broken or removed and the surface is sufficiently clean so that a good electrical contact between the stud and the metal structure may be established. The welding current is established and right after, almost simultaneously, the stud is moved backwards creating a second gap and draw the welding arc.

The second gap which is provided is preferably between 0.5 mm to 4 mm, more preferably between 0.75 mm to 2.25 mm. The welding current is applied as, or after, the electrical contact is being provided. The welding arc forms a melting pool between the stud and the metal construction. The welding current has a magnitude of 50 A to 850 A, preferably 100 A to 500 A, and duration between 0.5 ms to 500 ms, preferably 10 ms to 200 ms.

In order to improve the mechanical properties of the weld metal and the surrounded heat affected zone, the welding current may be replaced by a current sequence comprising at least two different current levels where a first period with a current of approximately 10 A to 100 A, is used for preheating the metal in the welding zone. This preheating current has duration of approximately the same order of magnitude as the welding current. The welding current is applied after the preheating current. If using a sequence of currents, the gap is created as the welding current is initiated.

After the welding arc has created a molten pool, the stud is forced into the pool by releasing the spring-loaded receiving means holding the stud in the stud- welding gun. The time delay before this release and the welding current to be applied are determined according to the type of stud, e.g. stud pin diameter and the material of the metal structure.

By the invention, the sheet material is preferably a fibrous insulation sheet material. However, it is realised that the method may also be applied in relation to the attachment of other types of panels, such as for instance calcium silicate boards, gypsum boards or cementious boards. The panels are usually stiff, but soft materials may also be used as panels, e.g. rolls, batts, foam panels or other sound or vibration absorption panels.

In the preferred embodiment of the invention, the metal structure is a steel structure. However, the method may also be applied in connection with other metal structures such as e.g. aluminium structures. The method is preferably applied in connection with a coated steel structure, e.g. with a corrosion resistant coating in order to remove the coating. However, it is realised that the method according to the invention may also be advantageously used for uncoated structures for removing impurities on the surface at the point of welding. Otherwise, impurities, such as scaling, heat residues etc., must be removed before the welding process, which is very time consuming. The structures may be coated with plastic coatings, paint or any other suitable protective coating.

The invention also relates to a stud welding system comprising a stud for use by attaching a sheet panel onto a metal structure comprising a head, preferably a discshaped head, with a protruding pin member, wherein said pin member is provided with top layer removing means at its free end. In the present context, the top layer corresponds to the corrosion protective layer or coating, e.g. paint.

The stud according to this aspect of the invention is thus adapted for use by a method according to the above-described first aspect of the invention.

In order to ensure a firm grip on the head of the stud so that the stud does not slide inside the welding gun, the head may be provided with a non-rotary symmetric shape. Alternatively or as a supplement, magnetic holding means may be provided and/or the disk-shaped head may be provided with indexing means, such as one or more indentations on the outer rim of the head. The indentations may also be provided in the interior of the head.

In a preferred embodiment, the pin and/or the underside of the head is provided with an electrically insulating sleeve. This is advantageous if the insulating panels are provided with a top layer of aluminium foil in order to isolate the aluminium foil from the welding process.

According to another aspect of the invention, the invention comprises a stud- welding gun for welding studs onto an underlying metal surface for attaching an insulation panel to said metal surface, said stud-welding gun comprising first spring-loaded stud holding means for receiving a stud, which is pinched through a sheet panel, and biasing the stud towards an underlying metal structure, welding current application means capable of applying a high frequency voltage and applying a welding current to the stud, wherein said stud receiving means are provided with lifting means for retracting the stud along its pin axis, said lifting means being capable of positioning the stud immediately above the metal structure surface at at least two different levels. Hereby, the stud-welding gun is adapted for use in performing a method according to the first aspect of the invention.

The receiving means are preferably provided with magnetic means for retaining the stud in a predetermined position relative to the metal structure. Hereby, the stud can be placed in a predetermined position in the receiving means of the stud- welding gun and kept in this position before the action of attachment commences.

Moreover, the stud-welding gun is preferably provided with support members, such as support levers, said legs preferably being adjustable, for providing a predetermined distance and pressure during the welding process. The support legs are designed in such a manner, that the distal end of the stud when positioned in the spring-loaded receiving means protrude a certain protrusion distance in front of the legs. When the stud is penetrated through the insulation and abuts the metal surface underneath, the protrusion distance in cooperation with the spring-loaded receiving means ensures that a certain pressure is exercised on the stud during the welding process.

Different number of supporting members has different advantages. Three or more supporting members offer a good adjustment of the stud, always holding it perpendicular to the surface of the metal construction. However, three or more supporting members complicate application of the method in e.g. comers due to limited space. This problem is reduced by only having two legs. With two legs, however, there is a risk of installing the stud not perpendicular to the underlying metal construction surface. With only one supporting member, the application in limited spaces is easier, but also the risk of installing the stud not perpendicular to the underlying metal construction surface is higher. However, one supporting member should be enough for ensuring the correct distance during the welding process.

The invention is described in more detail in the following with reference to examples in the accompanying drawings, in which:

fig. 1 is an illustration of a steel structure with a fibrous insulation mounted thereon, fig. 2 is a principal cross-section view of a steel girder with an insulation fitted around it, fig. 3 is a schematic illustration of the method of attaching a fibrous insulation panel according to the invention, fig. 4 is a perspective drawing of a stud according to the invention, fig. 5 is a top view of a stud according to another embodiment, fig. 6 is a schematic detailed view of the stud as it engages the steel structure; fig. 7 is a schematic illustration of another use of the invention for assembly of panels of a plurality of layers; fig. 8 is a diagram of the welding current as a function of time during the welding process; and figs. 9 and 10 are detailed views of a stud-welding gun according to the preferred embodiment of the invention.

In figure 1 is shown a steel structure 2 with fire insulation 1. The insulation is typically made up of fibrous insulation panels 1, which are mounted on the steel girder structure side by side covering the entire surface of the steel structure. The fibrous insulation panels 1 are secured to the steel structure by studs 3, which are pinched through the insulation panel and brought in contact with the steel surface underneath, as shown in fig. 2 and welded onto the steel structure 2 by use of a stud welding gun 4 by an electric welding process (see fig. 3).

The welding gun 4 has a capacitor unit or a transformer unit (not shown). The capacitor unit is charged by a main voltage-supplied transformer (not shown). By using a capacitor welding process a sufficient high amount of energy may be applied to the stud in a short time (a fraction of a second) so that the stud is welded onto the metallic surface. The welding gun 4 is pressed against a stud 3, which is pressed through the insulation panel 1, as shown in fig. 3. The stud 3 is accommodated in a receiving head 5 of the welding gun 4. The welding gun 4 is placed over the stud 3 so that the receiving head 5 is fitted over the head 31 of the stud 3 (see fig. 4). By the aid of the receiving means 5, the stud 3 is positioned with a small first gap above the metal structure 2 and a high-frequency high-voltage is applied for establishing an electrical contact. When the welding area surface is cleaned for impurities and electrical contact has matured into a small arc, the stud is moved back slightly to a position leaving a second gap between the distal end of the stud pin and the metal structure and a welding current is applied. This establishes a welding arc creating a molten pool. After a predetermined time the stud is forced into this molten pool and the insulation panel 1 is retained between the metal structure and the head of the stud 3.

As shown in figure 4, the stud 3 consists of a preferably disc-shaped head 31 from which an elongated protruding pin member or stud pin 32 extends. The head 31 may additionally be provided with indentations and the contour of the head 31 is designed to co-operate with the inner shape (non shown) of the receiving means 5 of the welding gun 4 to ensure a firm grip of the receiving means 5 is transferred to the head 31 and thereby the stud 3. At the free end of the stud 3 opposite the head 31, a top layer penetration means 35 is provided, preferably as a cone or pyramid shaped end of the pin 32. Adjacent the penetration means 35, a small deposit of zinc or similar corrosion protective material may be provided or the entire stud pin may be galvanised or provided with a similar coating. The zinc or similar corrosion resistant protective material gives good protection against galvanic corrosion.

In a preferred embodiment according to the invention, a magnetic grip by the receiving means 5 on the stud may prove sufficient in some circumstances in order to provide the necessary grip of the stud 3 (see figs. 9 and 10).

In fig. 5, another embodiment of the stud 3 according to the invention is shown. According to this embodiment, the pin 32 is provided with a sleeve 36 of plastic or similar non-conductive material extending substantially along the length of the pin between the tip 35 and the head 31. In addition to the sleeve 36 or as a substitute therefore, an isolating coating 38 of non-conductive material may be provided on the underside of the head 31. This prevents damaging an aluminium foil coated insulation panel from the electrical current of the welding gun as the welding energy is released during the welding process.

In some situations, the insulation 1 which has to be fastened to the metal structure is covered by a metal foil, e.g. aluminium, on the surface opposite the metal structure. The first welding pin 3 may therefore make up an electrical connection or short- circuit between the foil and the metal stmcture 2. This will make it more difficult to perform the welding of the second and following pins, as the pin holding means 5 on the welding gun 4 or the pin 3 itself will be in electrical contact with the foil. This will make it impossible to establish a welding arc.

This problem can be solved by having a substantially electrical insulating surface of the pin holding means 5 on the welding gun 4. Furthermore, it might also be an advantage if the end of the pin 3 has a substantially electrically insulating surface. The electrically insulating surfaces on the pin holding means 5 could be ceramic materials applied by e.g. thermal spraying, or some other temperature resistant material. The electrically insulating surface on parts of the pin 3 may be applied by any substantially electrically insulating paint or other substantially electrically insulating surface layer.

The tip 35 of the pin 32 is provided with a pointed distal end, e.g. a conical or a pyramid shape for facilitating a penetration into the molten pool of the steel surface of the steel stmcture 2 when the stud is pressed into the pool.

In an alternative embodiment of the stud pin 3, it is realised that it may be without a stud head. The disc shaped head may be subsequently attached to the pin after the pin has been welded onto the metal stmcture by the welding gun.

Another utility of the invention is shown in fig. 7 where several layers la, lb of panels 1 are attached to a steel stmcture 2 by one or more studs 3.

As shown in fig. 9, the stud 3 is retained in magnetic receiving means 5 in the stud- welding gun 4. The magnetic receiving means retains the stud 3 at its head 31 or at its head end so that the stud pin 32 points towards the surface to which it is to be attached. When retained in the welding gun 4, the stud 3 is penetrated through the insulation layer (not shown in figs. 9 and 10) and positioned so its distal end tip abuts the metal structure 2. As it can be seen in fig. 9, the distal end of the stud 3 protrade beyond the support members, e.g. support legs, 40 of the welding gun 4 when the spring-loaded receiving means 5 are in the spring means are unloaded. The support member 40 also penetrate the insulation and makes contact with the coated metal surface 2, as the spring-loaded receiving means 5 are compressed by a distance D, whereby the distal end of the support members 40 also makes contact with the underlying surface. The stud-welding gun is kept in a predetermined position by the support members 40, e.g. support legs, so that the correct distance D is maintained and controlled during the securing action of the stud pin 3. The spring-loaded receiving means 5 may comprise a compression spring means 41 which in an advantageous embodiment may be provided with adjustment means for regulating the spring force and the protmsion distance D. Moreover, the receiving means 5 may preferably be provided with reciprocating means which may be activated for repetitively knocking or tapping the stud against the surface of the metal stmcture for establishing a sufficiently good electrical contact. Measurement means (not shown) may preferably be provided for measuring the electrical resistance between the stud and the metal surface in order to automatically determine when a sufficiently good electrical contact is established.

During the application of high frequency voltage for establishing the electrical contact, a measurement means is applied for determining when the electrical resistance has fallen below a predetermined level. The welding current is applied and almost simultaneously the stud 3 is lifted slightly and the second gap L appears as indicated in fig. 10. The welding arc is now established. In addition, the second welding current is applied. Hereby, the melting pool is created by the welding arc and after a predetermined amount of time (the welding time), the welding current is cut off and the stud is pressed into the molten pool and the stud is attached to the metal stmcture.

It appears from tests that the combination of a higher current, a larger protrusion distance and a gap which is not too small in size provides the best welding results.

It is realised that the results may vary depending on the stud pin diameter and other parameters, such as material, etc. The welding time may be longer than 10 ms. Generally, the result of the welding process may be enhanced by using a longer welding time. However, the pin size limits the duration of welding time. It is realised that a significant improvement in the welding quality may be achieved making the insulation panel attachment considerably better and less labour intensive.

The above description relates to some of the preferable embodiments of the invention. However, it is realised that other embodiments of the various aspects of the invention may be provided without departing from the scope of the invention as set forth in the accompanying claims.

Claims

PATENT CLAIMS:

1. A method of attaching one or more fibrous insulation sheet panels onto a metal stmcture by placing a number of studs through the sheet material and welding said studs onto the metal stracture by using a stud-welding system in which the stud is positioned in a stud-welding gun, said method comprising the steps of penetrating a stud through the sheet material, providing an electrical contact between a stud and the underlying metal stracture, applying a welding current to the stud, retracting the stud providing a welding gap between the stud and the metal stracture and establishing a welding arc, and forcing the stud against the metal stracture after a predetermined duration of time.

2. A method according to claim 1, whereby the electrical contact is provided by positioning a distal end of the stud immediately above the metal structure in a stud welding system with a first gap between said distal end and said metal stracture and a high-frequency high- voltage is applied to the stud.

3. A method according to claim 2, whereby the high frequency high- voltage applied to the stud, preferably is between 6 kV to 14 kV with a frequency of 100 kHz to 200 kHz.

4. A method according to claim 1, whereby the first gap between the distal end of the stud and the metal stracture is between 0.1 mm to 1 mm, preferably approx. 0.5 mm.

5. A method according to any of the claims, whereby the high frequency voltage is applied for a sufficient amount of time to establish a welding arc whereafter the stud is retracted slightly establishing a second gap and the welding current is applied.

6. A method according to claim 5, whereby the high frequency voltage is applied for a time within the interval of 0.25 to 1 second.

7. A method according to any of the claims, whereby the electrical conductivity is measured by measuring means and the welding current can be established when the electrical conductivity exceeds a predetermined value.

8. A method according to any of the claims, whereby the stud is forced onto the metal structure at least simultaneous with the application of the welding current.

9. A method according to any of the claims, where the metal stracture is a steel structure.

10. A method according to any of the claims, where the metal stracture is an aluminium stracture.

11. A method according to any of the claims, where the metal stracture is a coated stracture, e.g. with a corrosion resistant coating.

12. A method according to any of the claims, where the stud welding gun is supported in a position relative to the metal stracture by at least one support member, such as a support lever.

13. A method according to claim 12, where said at least one support member is penetrated through the insulation sheet and is in contact with the surface of the metal stmcture for supporting the stud-welding gun through the stud-welding process.

14. A stud for use for attaching a sheet panel onto a metal stmcture comprising a head with a protruding electrically conductive pin member, c h ar a c t e r i s e d b y said pin member being provided with top layer penetration means at its distal end.

15. A stud according to claim 14, wherein said head is magnetic metal plate disc.

16. A stud according to any of the claims 14 or 15, wherein the pin is provided with a corrosion protective material deposit adjacent the top layer removing means.

17. A stud according to any of the claims 14 to 16, wherein the pin is provided with an electrically insulating sleeve.

18. A stud- welding gun for welding studs onto an underlying metal surface for attaching an insulation panel to said metal surface, said stud- welding gun comprising first spring-loaded stud holding means for receiving a stud, which is pinched through a sheet panel, and biasing the stud towards an underlying metal stmcture, welding current application means capable of applying a high frequency voltage and applying a welding current to the stud; c h ar a c t e r i s e d b y said stud receiving means are provided with lifting means for retracting the stud along its pin axis, said lifting means being capable of positioning the stud immediately above the metal stmcture surface at at least two different levels.

19. A stud welding gun according to claim 18, wherein the receiving means are provided with magnetic means for retaining the stud in a predetermined position relative to the metal stmcture.

20. A stud welding gun according to claim 18 or 19, wherein the stud welding gun is provided with support members, such as support levers, said legs preferably being adjustable, for providing a predetermined distance and pressure during the welding.

21. A stud welding gun according to any of claims 18 to 20, wherein the stud receiving means is provided with a substantially electrically insulating surface.