NL9000366A - METHOD FOR ATTACHING A METAL SHEET MATERIAL TO A CORE OR BASE PLATE MATERIAL, AND AN APPARATUS FOR CARRYING OUT THIS METHOD - Google Patents

Description

A method for bonding a metal sheet material to a core or base sheet material, as well as a device for carrying out this method.

The invention relates to a method for bonding a metal sheet material to a core or base sheet material using a fusible adhesive layer.

A method of this type is widely used to bond metal plates to all kinds of core or base plates. This method is generally referred to as lamination, and the product with laminate. A known product is the so-called sandwich plate, in which a core plate of, for example, light or cheap material is covered on both sides by a metal plate. Such plates can be a light or cheap alternative to, for example, steel plate. Products are also known in which a base plate is covered on one side by a metal plate. The metal plate then has, for example, a protective function for the base plate. Conversely, it is also possible for the base plate to protect the metal plate. Finally, plate-shaped products are also known which consist of an alternation of metal plates and core or base plates. This could for instance be a sandwich plate covered on one or both sides with a base plate. Such an outer base plate has, for example, the function of protective layer for the metal plate below it. Such a base plate often also has a decorative function.

In the laminates discussed above, the metal plates as well as the core or base plates can themselves be laminate again. For example, in the case of aluminum, a so-called clad layer could be applied to a metal plate. A core or base plate often has relatively thin surface layers which are intended to realize the adhesion with a metal plate. In addition, it is also possible that a separate adhesive layer, in the form of a foil, is used or that the adhesive layer is applied to the metal sheet material. The core or base plate material can also consist entirely of the adhesive material. In the known compositional processes, the entire laminate is thoroughly heated to a temperature at which the adhesive layers melt. The different layers of the laminate are then pressed firmly together and cooled in that state, after which the laminate forms a whole. Problems are expected in this process when the adhesive layer is relatively thick or when other relatively thick layers of the laminate are also melted. By vigorously pressing the layers of the laminate together, there is a danger with relatively fairly thick molten layers that molten material is pressed out of the laminate, while thickness variations also occur. To avoid this problem, it is usual to use very thin adhesive layers, the melting point of which is above that of the other materials in the laminate. Such a solution limits the freedom of choice of material for the laminate.

In another solution, the edges of the laminate are sealed to prevent the melt from flowing out. However, the laminate maintains an insufficiently constant thickness.

The present invention contributes to the manufacture of laminates, solving the problem that relatively thick layers are in the molten state during manufacture.

This problem is solved according to the present invention in that the adhesive layer in a laminate is heated for a short time to a temperature which is considerably above the melting point, because a limited part of the metal sheet material is heated by electromagnetic radiation, in particular inductive heating and metal sheet material and the core or base sheet material in the heating zone or directly behind it are strongly pressed together, whereby the heat necessary for melting said surface layer is extracted from the heated part of the metal sheet material.

These measures make it possible to increase the temperature of the adhesive layer which contacts the electromagnetically heated metal plate very quickly above its melting point, the other parts of the laminate, such as the core or base plate, hardly increasing in temperature. . Because only a limited part of the metal plate is heated, its heat can be quickly dissipated after the adhesive layer has melted. This prevents the adhesive layer from being exposed to the high temperatures for a longer period of time, which can possibly damage the surface. This also prevents the remaining parts of the laminate, such as the core or base plate, from becoming too hot and from melting. In this method, it is also possible that with a relatively thick adhesive layer, only a surface layer in contact with the metal plate is melted. Only with the help of electromagnetic heating it is possible to heat a limited part of the metal plate to the desired temperature. It is also possible with electromagnetic heating to press sufficient heat calories into the surface layer of the core or base plate with a metal plate material with a low heat capacity (for instance a relatively thin plate). It is now possible to press the metal plate firmly onto the core or base plate without risk of squeezing out part of the core or base plate.

The metal plate thus acts as a heat buffer which, depending on the nature, can be additionally heated during contact with the core or base plate.

This form of deformation is also economical, because the entire laminate does not have to be heated.

Such a method can be used both in laminating in which at least the surface layer of the core or base plate material facing the metal plate material is formed by the adhesive layer, and in which the adhesive material is applied to the surface layer of the metal plate material facing the core or base plate material. as where the adhesive layer is applied as a separate film between the metal sheet material and the core or base sheet material.

In many cases it will be necessary to keep the metal sheet material pressed onto the core or base sheet material until the adhesion is achieved. This is necessary to prevent the metal plate from coming loose immediately after it has been pressed onto the core or base plate, because the core or base plate material is pressed together slightly in the pressing area, so that the metal plate material does not run flat and as a result of its bending stiffness after the pressing area of the core or base plate will come off. This tendency will be particularly high if a strong pressing takes place in a small area (for example when using pressure rollers). A melted adhesive layer will often be unable to prevent this problem. When it has cooled down sufficiently. Until then, a contact pressure remains required.

It is preferable that the metal sheet material, the adhesive layer and the base or core sheet material are continuously guided along an inductive heater at the same speed. This achieves a more or less continuous manufacturing process of the laminate.

Such a method will for instance be very suitable for manufacturing a so-called sandwich plate material, in which a metal plate material is bonded to both sides of the core plate material, the thickness of which is less than the thickness of the core plate material, which is customary here. Such a sandwich can for instance be composed as follows: two aluminum layers, each 0.2 mm thick, with a layer of plastic 0.6 mm thick in between. With a specific mass for aluminum of 2.73 kg / dm3 and for plastic of 1.1 kg / dm3, 1 square meter of this weighs 1.752 kg, while the same sheet of 1 mm thick aluminum weighs 2.73 kg. In this way a light sheet material is obtained.

It will expand by heating a metal plate. Because in the present method a heated metal plate part borders on an unheated part, expansion differences arise. With relatively thin plates, this can cause folds in the plate. This can be prevented by causing the surface of the metal sheet material in or after the heating zone to undergo kinking or bending. Due to this bending or bending, the stiffness of the plate in the plane increases and no more creases can arise.

The invention also relates to an apparatus for carrying out the present method, which comprises means for electromagnetically, in particular inductively, heating the metal sheet material and pressing means for pressing the metal sheet material in or after the heating zone on the core or base sheet material.

It is preferred that the device comprises means for placing the part of the metal sheet material located in or after the heating zone at an angle with respect to the exit surface of the heating zone. This prevents folds in the plane of the sheet material that arise as a result of differences in expansion.

The invention will now be further elucidated on the basis of a number of exemplary embodiments of devices for carrying out the method according to the present invention. In these exemplary embodiments, a core or base plate material is used which is provided with a fusible adhesive layer on the surface facing the metal plate material. Of course, for the purpose of the invention, an adhesive layer in the form of a separate film may be used in the same manner, or the adhesive layer may be applied to the surface of the metal sheet material facing the core or base sheet material. Use is made of the attached drawings, in which:

Fig. 1 shows a schematic view of the part of the device where the heating and pressing zone for bonding the metal sheet to the core or base plate is located.

Fig. 2 shows in a view another embodiment of the heating and pressing zone.

Fig. 3 shows a last embodiment in a view of the area where the heating and pressing zone is located.

Fig. 4 shows a temperature-time diagram of the metal sheet as it passes through the heating zone.

Fig. 1 of a device 1 for carrying out the method according to the present invention shows the means for inductive heating, which are hereinafter referred to as inductor 2 and 3 »which are located opposite pressure rollers 4 and 5. Here the heating zone is bounded by the area of influence of the inductor 2, 3 and the pressure zone through the area of influence of the pressure rollers 4, 5 · With the aid of this device, a metal plate 6 is first applied to the core plate 7 at the location of the inductor 2, after which the metal plate 8 the same core plate 7 is bonded at the location of the inductor 3. In this case, the metal plates 6, 8 and the core plate 7 are guided along inductor 2, 3 at the same constant speed. The metal plate 8 is brought to the desired temperature by the inductor 3. Because the metal plate 8 moves at a certain speed along the inductor 3, the metal plate 8 must be irradiated by the inductor 3 for heating for a certain length in the direction of movement. In order to keep the heating constant at a variable speed, for example, a part of the inductor 3 can make an angle with respect to the plane of the core plate 7. The distance between the metal plate 8 and the inducer 3 can then be varied in that part by varying the angle at which the metal plate approaches the core plate 7. For example, the distance between the metal plate 8 * and the inductor 3 in the front region thereof is greater than that between the metal plate 8 and the front region of the inducer 3. Due to this greater distance, the heating in this area is smaller, because the degree of heating is inversely proportional to the distance squared in electromagnetic heating. Varying the angle can for instance take place computer-controlled. The inductor 3 now heats the metal plate 8 in a very short time to a temperature above the melting point of the surface of the core plate 7, which in this case forms the adhesive layer. Subsequently, the surface of the core plate 7 also undergoes a temperature increase in a very short time sufficient to melt the surface. Due to the speed at which the temperature increase takes place, the remaining part of the core plate 7 will hardly have increased in temperature, so that this part retains its solid shape. There is therefore no danger of squeezing out a part of the core plate 7 if the metal plate 8 is then pressed onto the core plate 7 by the inductor 3 which in this case is on a foundation 9 and the pressure roller 5 which exerts force in the direction of inductor 3. Here, the pressure roller 5 can be driven to rotate, so that the throughput of the different plates is realized. It is also possible that the pressure roller 5 rotates freely, while elsewhere in the device the throughput of the different plates through the device is realized. For applying the metal plate 6 by means of the inductor 2 and the pressure roller 4, the same applies as for the metal plate 8, with the proviso that in Fig. 1 the distance between the metal plate 6 and the inductor 2 in the front region this is greater than that between the metal plate 8 and the inductor 3 · This may be necessary, for example, if, for example, the composition of the surface layer of the core plate 7 with which the metal plate 6 comes into contact shows a different melting behavior, or that, for example, the thickness of the metal plate differs from that of the metal plate 8, so that the heating behavior differs. In this case, the metal plate 6 is pressed onto the core plate 7 by an inductor 2 energized by a spring 10 and the pressure roller 4 which, for example, bears with respect to a foundation. Of course there are also other possibilities to generate a pressing force between the inductor 2 and the pressure roller 4 and the inductor 3 and the pressure roller 5 · It is often necessary that behind the heating zone, after the metal plate material has been pressed onto the core or base material , this pressure is more or less maintained until the surface layer has cooled sufficiently. This is to prevent the metal sheet material from being able to remove itself again from the core or base material immediately after the pressing zone. In Fig. 1, unheated pressing elements 13 are provided for this purpose, which are arranged after the induction tower 2, 3.

In Fig. 2, the inductor 2, 3 are designed as cylindrical rollers. The induction tower 2, 3 now simultaneously form the pressing means.

In this case, the metal plates 6, 8 are simultaneously applied to the core plate 7 · In order to place the metal plates 6, 8 in or after the heating zone at an angle to the exit surface of the heating zone, these plates can for instance be placed over guide rollers 11, 12 be guided. This causes the metal plates 6, 8 to change direction in or after the heating zone. This prevents creases due to the very local expansion of the metal plates. This also causes, for example, the metal plate 6 to be irradiated over a reasonable length by the inductor 2. Normally, this distance will be almost a line, which does not offer sufficient opportunity to heat up the metal plate 6 with the aid of the inducer 2. Due to the arranged arrangement, the metal plate 6 touches the inductor 2 over a larger circumferential area. In order to increase the irradiation length between the metal plate 6 and the inductor 2, the metal plate can be brought into the position indicated by 6 'by, for example, placing the guide roller 11 in the position 11'. Of course, with some modifications, such a device can also be used to make a laminate consisting of one metal plate 6 and a base plate 7. Furthermore, the inducers 2, 3 can be driven to rotate so that they provide the throughput of the plates. They can also be freely rotatable while the throughput of the plates is provided elsewhere in the device. Here too, pressing elements 13 are used to keep the metal sheet material pressed onto the core or base sheet material until the molten adhesive layer has cooled sufficiently.

Fig. 3 shows another exemplary embodiment of a device in which the metal plates 6, 8 are guided between two inductor 2, 3 and heated there, after which these plates are then pressed onto the core plate 7 with the aid of pressing means 4, 5 behind the inductor 2, 3, which serve as heating and pressing zone, pressing means 4, 5 are placed, which form a double belt press. As a result, pressure can be exerted on it over a certain length in the direction of movement of the plates with the aid of, for example, air pressure, while it is also possible to cool over such a length of the section with such a press. Of course, other pressing means are also possible. The double-belt press 4, 5 can, for example, also be arranged to provide heating. To this end, the front rollers (the left one in Fig. 3) can be designed as induction tower. The pressing elements 13 are then no longer necessary because the belt of the double-belt press 4, 5 printed on the sheet material 6,7 * 8 can now fulfill this function all by itself.

In the device according to Fig. 1-3, the plates move relative to the device. The reverse is of course also possible. For example, with a device as shown in fig. 1-3 * or a variant thereof which falls within the scope of the invention, it is also possible to give the laminate a profile. The laminate thus formed can then, for example, be cut into strips or rolled up.

Fig. 4 shows the change in temperature of a metal sheet as it passes through the heating zone. With temperature TQ, the metal plate enters the heating zone at time tn. In a very short time, the inductor heats the temperature of the metal plate to T2. This temperature is above the melting temperature of the adhesive layer which in this example forms the surface layer of the base or core sheet to which the metal sheet will be bonded. At time t ^ the metal plate comes into contact with the base or core plate. As a result, the temperature of the metal plate will drop rapidly, and it is usually necessary to keep the temperature of the metal plate at T2 with heating. At time t2, the heating of the metal plate is ended, as a result of which the temperature of the metal plate will drop rapidly and at time t ^ will drop below the melting temperature of the respective surface layer of the core plate or base plate. Thus, the surface layer is melted by means of "shotheating". These times are all so short that only a small thickness of the respective surface layer of the base or core plate is melted.

For example, by selecting the heating temperature of the metal plate, it is possible to heat the metal plate for a shorter time. Such a range is shown in dotted lines in Fig. 4. This makes it possible to transport the sheet materials along the heating zone at higher speeds.

It is to be understood that the present invention is not limited to what has been described above. Characteristic of the invention is that when a metal sheet material is bonded to a core or base sheet material by means of a fusible bonding layer, this layer is heated and melted so quickly that the remaining part of the laminate, including the core or base sheet material, is still but has hardly increased in temperature. This very rapid temperature increase is caused by heating the metal sheet material over a limited area by means of electromagnetic heating, in particular induction.

Claims (11)

Method for bonding metal sheet material to a core or base sheet material by means of a fusible bonding layer, characterized in that the said bonding layer is heated for a short time to a temperature which is considerably above the melting point, because a limited part of the metal plate material is heated by electromagnetic radiation, in particular inductive heating, and the metal plate material and the core or base plate material in the inductive heating zone or directly behind it are strongly pressed together, the heat necessary for melting said adhesive layer being added to the heated part of the metal sheet material is extracted. Method according to claim 1, characterized in that at least the surface layer of the core or base plate material facing the metal sheet material is formed by the adhesive layer. Method according to claim 1, characterized in that the adhesive material is located on the surface layer of the metal plate material facing the core or base plate material. Method according to claim 1, characterized in that the adhesive layer is applied as a separate foil between the metal sheet material and the base or core material. Method according to claims 1-4, characterized in that the metal sheet material is kept pressed onto the core or base sheet material until the adhesion is realized. 6. A method according to claims 1-5, characterized in that the metal sheet material, the adhesive layer and the base or core sheet material are continuously guided along an inductive heating device at the same speed. A method according to claims 1-6, characterized in that metal sheet material is bonded to both sides of the core sheet material, the thickness of the core sheet material being greater than the thickness of the metal sheet materials. A method according to any one of the preceding claims, characterized in that the surface of the metal sheet material in or after the heating zone undergoes a kink or bend. Device for carrying out the method according to claims 1 to 8, characterized in that it comprises means for electromagnetic, in particular inductive, heating of the metal sheet material and pressing means around the metal sheet material in or after the heating zone pressing the core or base board material. 10. Device as claimed in claim 3, characterized in that it comprises means for placing the metal plate in or after the heating zone at an angle relative to the exit surface of the heating zone. Device according to claim 10, characterized in that the angle is variable.