NL8700554A - METHOD FOR MANUFACTURING A CYLINDRICAL METAL BUILDING CONSTRUCTION AND APPARATUS FOR CARRYING OUT THIS METHOD - Google Patents

Abstract

A method and an apparatus are provided for constructing a cylindric metal building construction, in which the building construction is supported by a number of guidings (5 - 12), such, that always a appropriate support is obtained without the need for additional lifting devices. According to the invention the guidings (5 - 12) are each separately or together movable upwards and downwards.

Description

* NL 34.132-Vo / hp *

Method for manufacturing a cylindrical metal building construction as well as a device for carrying out this method

The invention relates to a method for manufacturing a cylindrical metal building construction by placing successive rings on top of one another and attaching them to one another, comprising: 5 - supplying in a vertical position and shaping the desired shape with a molding device. the material for the manufacture of the rings, such as metal strip or metal plates to be combined into a metal strip, - forming the supplied material into a ring by means of suitable guides, - it to a length corresponding to the circumference of the respective ring to be formed, cutting off the metal strip or the metal plates assembled into a metal strip, - attaching the top edge of the metal strip to the lower edge of a building construction part already manufactured, as well as attaching the beginning and the end together. of the cut-off metal strip part, - lifting up the building construction part thus formed in its entirety and the the application of further rings 20 until the building construction has reached the desired height, and - finally placing the building construction on the bottom.

In a known method of this type, the supplied metal belt is continuously applied to a carousel, which comprises a turntable, the rotation speed of which corresponds to the supply speed of the belt. When the length of a metal strip portion corresponding to the circumference of a ring is reached, the metal strip is cut and winding on the merry-go-round is completed. Subsequently, the previously constructed building construction part is placed on top of the ring which has just been produced and attached to it.

This known method has a number of drawbacks. The carousel used for winding the supplied metal strip into a ring is in principle only suitable for a limited number of diameters of the cylindrical building structures to be manufactured. When building structures must be manufactured whose diameter differs greatly from the diameter of the carousel, an entirely new carousel must be used. It will also give problems with thicker materials to properly shape the material in this way. As a further drawback of this method, it can be mentioned that placing the already manufactured building construction part on the top edge of a newly manufactured ring requires a separate lifting device, while accurately positioning the already manufactured building construction part on the top edge of the just manufactured product. ring is very difficult. The causes of this must be sought in the low shape stability of the already manufactured building construction part, the relatively large mass thereof and the wind sensitivity, which can play a major role at a construction site.

The object of the invention is to provide a method for manufacturing a cylindrical metal building construction, wherein these drawbacks are eliminated in a simple, yet effective manner.

For this purpose, the method according to the invention is characterized in that the lifting of the already constructed building construction part is effected by moving the guides upwards synchronously, which are designed as supports engaging on the bottom edge of this building construction part, while each guide, which is located in the circumferential direction of the building construction part for the supplied metal belt, a short time before this guide is reached by the beginning of the metal belt, is moved downwards so far that the metal belt is advanced over this guide and the lower edge of the metal strip is supported by this guide.

In contrast to the known method, an already manufactured building construction part is no longer lifted in its entirety above a new ring to be manufactured, but this already manufactured building construction part initially rests entirely on the guides. As the manufacture of a new ring proceeds, the support of this already manufactured building construction part is increasingly taken over by the ring part located below it, which in turn is supported by the downwardly moved guides. In this manner, a certain and reliable support of the already manufactured building construction part takes place at any time, while also a good positioning of this building construction part relative to the supplied metal strip for forming a new ring is accomplished.

In a preferred embodiment of the method according to the invention the building construction is lowered after the last lower ring has been completed and attached to the building construction part already manufactured by lowering all guides synchronously and placed on supporting blocks, after which the guides of below the bottom edge of the bottom ring are removed and the building construction is lifted slightly with the aid of auxiliary members for removing the supporting blocks and the building construction 15 is finally lowered to the bottom.

In this manner, no additional hoisting device or the like is necessary during the last phase of manufacturing the building construction, namely placing it on the bottom. The guides, which are initially located under the lower edge of the bottom ring, can be removed in a simple manner when the building construction rests on the supporting blocks, after which the building construction is finally placed on the bottom with the aid of the auxiliary members.

The invention further relates to an apparatus for carrying out the method according to the invention. This device is characterized in that it is provided with a number of lifting units, each of which has an up and downwardly movable guide and which are positioned such that the location of their guides corresponds to the diameter of the building construction to be manufactured. Due to the presence of a number of lifting units, the device according to the invention is very versatile, since the placement of the lifting units can be selected in accordance with the diameter of the building construction to be manufactured. Therefore, the same device can be used to manufacture building structures of any desired diameter. Only the number of lifting units used can vary, whereby a larger number of lifting units can be used in building constructions with a very large diameter.

40 In a convenient embodiment of the device 6> 1; , ·;

V

According to the invention, it has at least one drive unit for moving the already manufactured building construction part in the circumferential direction, which drive unit, viewed in the direction of travel, is located a short distance in front of the place where the top edge of the metal strip is attached to the bottom edge of the already constructed building construction part. In this way, a synchronous advancement of the building construction part and the metal strip is obtained.

It is furthermore advantageous here that the driving unit for moving the already manufactured building construction part in the circumferential direction has two pairs of driving roller placed one above the other, the driving rollers of the upper driving roller pair engaging on both sides of the lower edge of the already manufactured building construction part, while the drive rollers of the lower drive pair of rollers engage on either side of the top edge of the metal strip.

If it is further ensured that the drive pulleys are placed at an angle such that the rotation axes of drive rollers located on the same side of the building construction wall diverge in the direction of movement of the building construction, the already manufactured building construction part and the metal strip are which is important for proper positioning of the two parts.

The invention is explained in more detail below with reference to the drawing, in which an embodiment of the method and device according to the invention is shown. FIG. 1 schematically shows a side view of a device according to the invention for applying the method according to the invention;

Fig. 2 shows the device of FIG. 1 in top plan view at an earlier point of time, however showing only the last ring, and

Figures 3-6 show a part of the device during a number of successive steps of the method according to the invention.

Figures 1 and 2 show a device suitable for manufacturing a cylindrical metal building 8 * 7 Λ. ƒ * «« n-. · ƒ / U v? : i <-5- ft construction, by superimposing and fastening successive rings. It can be seen in Fig. 1 that a number of rings 1, 2 and 3 have already been placed one above the other. Fig. 2 shows the manufacture of a new ring 4.

If a roof construction is to be placed on the cylindrical building construction, it is mounted in a known manner after the production of a first ring.

As can be seen from Fig. 1, the device has a number of lifting units 5-12, which are placed in accordance with the diameter of the building construction to be manufactured, or in this case, the diameter of the ring 4 to be manufactured. Although in the shown embodiment the number of lifting units equals eight (see fig. 2), this number of lifting units can be varied according to the diameter of the building construction to be manufactured. The lifting units 5-12 are mounted on a previously prepared foundation, for example of concrete.

It is also possible that, when the building construction to be manufactured is a tank with a welded bottom, this bottom is first manufactured and the lifting units are subsequently mounted thereon. Especially with heavier and higher constructions to be manufactured, it is necessary to brace the lifting units in order to obtain sufficient stability as a whole, which is not shown in Figures 1 and 2. In addition, it is important that the lifting units are placed level.

The lifting units 5-12 each have a guide 13, which is attached to a slide 16 which can be moved up and down via a guideway 14. This up and down movement is effected by a motor 15 / which drives a screw spindle or the like. However, the up and down movement of the guides 13 can be effected in any suitable manner, allowing mechanical, electrical or hydraulic or pneumatic solutions.

It is furthermore possible here that the lifting devices are switched in such a way that all can simultaneously move synchronously, both upwards and downwards, and that each lifting device can be moved downwards independently and preferably accelerated.

40 During the manufacture of a cylindrical metal building construction, a metal tape 17 is wound from a coil 18 and fed in a vertical position. The metal strip 17 is first brought into the desired shape by a molding device to form the ring 4 to be manufactured. As can be seen from Fig. 2, the molding device in this case consists of a stretching unit 19 for stretching the unwound from the coil 18. metal strip, as well as a rolling unit 20 for rolling the metal strip to the desired diameter. It is noted that when a thicker material is used, it is possible that it does not originate from a coil 18, but consists of separate metal plates coupled together to reach the rolling unit 20.

During the formation of the first ring of a metal building construction to be manufactured, all guides 13 of the lifting units 5-12 are in their lowest position.

The end of the metal strip 17, which has passed the rolling unit 20, is advanced by means of a driving unit 21 (seen in clockwise direction in Fig. 2), and successively over the guides 13 of 20 the lifting units 5 -12 moved. To guide the metal strip 17 correctly, the guides each consist of a support roller with flange edges. It is possible to use locks or additional guides for holding the structure in strong winds or the like.

When the metal strip 17 has been passed in this way around the guides 13 of the lifting units 5-12, the metal strip 17 is cut to a length corresponding to the circumference of the ring 4 to be formed by means of a cutting device 22. This cutting device 22 may consist of a cutting torch, a plasma cutter, a cutting disc, cutting shears or the like. Finally, the beginning and the end of the cut metal strip portion are secured together to form a finished ring 4.

After the first ring 4 has been formed, the guides 13 of the lifting units 5-12 are simultaneously moved upwards, to which the motors 15 are energized. The distance over which the guides 13 move upwards is equal to the width of the metal strip 17 to be supplied. This stroke of the guides 13 can be adjusted in advance.

40 Next, the metal belt 17 is fed again via the stretching unit 19, by the 8700554 -7- * $ drive unit 21 and along the rolling unit 20. When the front end of this metal band 17 has come in the vicinity of the lifting unit 12, the guide 13 of this lifting unit 12, for example 5, is moved downwards, so that the metal band 17 can pass above this guide. The top edge of this metal strip 17 comes into contact with the bottom edge of the already manufactured building construction part, as is clear from Fig. 1, wherein the top edge of metal strip 17 comes into contact with the bottom edge of ring 3. Then said top edge can the said bottom edge is fastened, after which the already constructed building construction part is rotated simultaneously with the supplied metal belt 17. During this continuing rotation, each guide 13, which is located in the circumferential direction of the building construction part for the supplied metal strip 17, is moved downward by the beginning of the metal strip 17 so far that the metal strip 17 is reached before the guide strip 13 is reached. this guide 13 is advanced and the lower edge of the metal strip 20 17 is supported by the guide 13. Fig. 1 shows the situation in which the guide 13 of the lifting unit 5 is about to move downwards to assume the dotted position of this guide.

In this way, the already constructed building construction part is in each case suitably supported. After reaching the suitable length of the metal strip 17, it is cut again with the aid of the cutting device 22, the ends are fastened together and the steps described above are repeated, until the building construction has reached the desired height reached.

A further drive unit 23 is used for advancing the metal strip 17 and the already constructed building construction part. Seen in the direction of advancement, this drive unit 23 is located a short distance in front of the place, where the top edge of the metal strip 17 is attached to the bottom edge of the already manufactured building construction part. The drive unit 23 has, as shown in Fig. 1, two superimposed drive roller pairs 24, 25. The drive rollers 24 of the top drive 40 pair of rollers engage on either side of the lower edge of the drive edge. * ccv> D * - «-8- the already manufactured building construction part, while the driving rollers 25 of the lower driving roller pair engage on either side of the upper edge of the metal strip 17. The driving rollers 24, 25 are placed at such an angle here, that the rotation axes drive rollers located on the same side of the building construction wall diverge in the direction of travel of the building construction. The driving force hereby has a resultant which presses the metal strip 17 and the already manufactured building construction part together.

In the manufacture of a metal building construction, the thickness of the material used often increases from ring to ring downwards. It is therefore advantageous if at least one roller of each drive roller pair 24, 25 is spring-adjustable, so that an automatic adjustment is possible in response to various material thicknesses. For automatic welding of different materials with different thicknesses, a variable peripheral speed of the building construction is required. The drive units 21 and 23, as well as the roller used in this exemplary embodiment, will have to be geared to each other for this purpose with regard to their drive speeds.

Fig. 2 furthermore diagrammatically shows an automatic welding device 26, which ensures that the top edge of the supplied metal strip and the bottom edge of the already manufactured building construction part are fastened together. Of course, any other fastening method can be used, such as the use of bolts or rivets. However, when materials such as steel, stainless steel, aluminum and the like are used, the welding is an extremely simple yet reliable fastening method.

Guiding rollers 27 are shown on either side of the welding device 26, which guide and direct the metal strip 17 and the already manufactured building construction part at the location of the welding device 26. These guiding rollers can also be adjustable in order to adapt to various material thicknesses.

With thin material it is possible that the welding device comprises a device for one-sided welding, wherein on the side of the building construction wall remote from the welding device, a cooling provision for cooling ε 7 o5 5 $, -9- £ this side has been applied. This can be pressed against the weld seam, resulting in a tighter wall.

Furthermore, changes in the structure of the material and any reduction in corrosion resistance are avoided as much as possible. Furthermore, mechanical properties of the material, such as the tensile strength and tensile limit, are better preserved.

With a number of materials to be processed, when welding on both sides, such a cooling device will be desirable on both sides. These cooling arrangements are not shown in fig. 1 or 2.

Furthermore, it is possible for the welding device 26 to be provided with a device (not shown) for working the edges to be welded, while a device for finishing the welding seams can also be used behind the welding device 26.

In addition to the automatic welding device 26 shown, it is also possible that the welding is carried out by hand.

As can be clearly seen from Fig. 2, the rolling unit 20 is located outside the circumference of a manufactured ring 4. This ensures that the individual rolling rollers of this rolling unit can be joined to each other on both their top and bottom sides in an unshown manner. covenants. As a result, very thick metal strip 17 can also be rolled with this rolling unit 20, without the individual rollers of this rolling unit 20 moving apart.

When a ring is completely ready, before lifting the manufactured building construction part, it can be rotated around 30 on the guides 13. By means of a profile device (not shown), reinforcement profiles can also be pressed into the metal strip, so that the finished building construction obtains a greater stiffness. .

After obtaining a building construction part with the desired height, i.e. a building construction part, in which sufficient rings are placed under each other, this building construction must be placed on the bottom. This can be done as shown diagrammatically in FIG.

3-6.

Fig. 40 3 shows that it is not possible directly to place i'i V r, - r * / / f Q v;, i v ^ φ -10 - with the aid of guides 13 on the bottom ring 4. Therefore, after the whole finished building construction has been slightly lifted, support blocks 28 are placed between the guides 13 (fig. 4), which height is such that the guides 13, after lowering the finished building construction on the support blocks 28, released from the bottom edge of the bottom ring 4 when this bottom edge rests on the support blocks 28. Then the guides 13 are detached from the lifting units 5-12 and removed from under the bottom edge 10 of the bottom ring 4.

Fig. 5 shows the next stage, in which the guides 13 have been replaced by auxiliary members 29 which comprise, for example, a locking lip angle iron. These auxiliary members 29 engage under the lower edge of the ring 4 and lift the entire building structure by a small actuation of all lifting units 5-12 simultaneously. The support blocks 28 are removed, after which the auxiliary members 29 are simultaneously lowered until one or more of them almost touch the highest point of the, usually concrete, bottom. Then 20 are distributed over the circumference, a number of shims placed under the building construction to fill the space between the bottom and the underside of the finished construction, and also to accommodate the unevenness of the bottom. The auxiliary members 29 can now be simultaneously lowered 25 until the entire construction rests on the filling plates (fig. 6), after which the auxiliary members 29 and the lifting units 5-12 can be dismantled. The finished construction can then be anchored and poured in the usual way.

If the finished building construction has to be mounted on a pre-made steel bottom, it will be necessary to mount attachments at the location of the lifting devices 5-12 on the inside and at the bottom of ring 4, so that with the help of special auxiliary members constructed the finished construction can be placed directly on the steel bottom.

The invention is not limited to the embodiment described above, which can be varied in many ways within the scope of the invention.

6700554

Claims (15)

A method for manufacturing a cylindrical metal building construction by placing successive rings on top of one another and attaching them to one another, comprising: - feeding in a vertical position and bringing the material into the desired shape with a molding device for the production of the rings, such as metal strip or metal plates to be combined into a metal strip, - forming the supplied material into a ring by means of suitable guides, 10. forming it to a length corresponding to the circumference of the ring to be formed - cutting off the metal strip or the metal plates assembled into a metal strip, - fixing the upper edge of the metal strip 15 to an underside of a building construction part already prepared, and attaching the beginning and the end of the cut metal strip part to each other, - lifting the building construction part thus formed in its entirety and arranging further ring below and until the building construction has reached the desired height, 20 and - finally placing the building construction on the bottom, characterized in that the building construction part already manufactured is lifted by moving the guides, which are designed as on The lower edge of this building construction part engages supports, while each guide, which is located in the circumferential direction of the building construction part for the supplied metal strip, is moved downward a short time before reaching this guide through the beginning of the metal strip, that the metal strip is advanced over this guide and the lower edge of the metal strip is supported by this guide. 2. Method according to claim 1, characterized in that after completion and attaching the last lower ring to the already manufactured building construction part, the last lower ring is lowered by synchronously lowering all guides and placed on supporting blocks, after which the guides from below the bottom edge p * 7 t "-12- * of the bottom ring are removed and the building structure is slightly lifted with the aid of auxiliary members to remove the supporting blocks and finally the building structure is lowered to the bottom. Device for carrying out the method according to claim 1 or 2, characterized in that it comprises a number of lifting units, each of which has an up and down movable guide and which are arranged such that the location of their guides corresponds with 10 the diameter of the building construction to be manufactured. Device according to claim 3, characterized in that each guide is attached to a slide which can be moved up and down along a guideway. 5. Device according to claim 4, characterized in that each guide comprises a support roller with flanged edges. 6. Device as claimed in claim 5 and 2, characterized in that each support roller is detachable from its slide and can be replaced by an auxiliary member, which is designed as an angle iron engaging under the lower edge of the building construction. 7. Device according to any one of claims 3-6, with a molding device designed as a rolling unit, characterized in that the rolling device is placed outside the circumferential path of the rolled metal strip determined by the guides. 8. Device as claimed in any of the claims 3-7, characterized in that it has a drive unit for feeding the metal strip or the metal plates assembled into a metal strip, which drive unit, viewed in the direction of advancement of the metal strip, for the molding device located. 9. Device according to any one of claims 3-8, characterized in that it has at least one driving unit for moving in the circumferential direction of the already manufactured building construction part, which driving unit, viewed in the moving direction, is at a short distance located in front of the place where the top edge of the metal strip is attached to the bottom edge of the building construction part already manufactured. · *! · - Λ * ·. - - h / r Λ ï v> V-. f Λ 3 -13- * 10. Device as claimed in claim 9, characterized in that the drive unit for moving the already manufactured building construction part in the circumferential direction has two drive roller pairs 5 placed one above the other, the drive rollers of the top drive roller pair engaging on both sides of the lower edge of the already constructed building construction part, while the driving rollers of the lower driving roller pair engage on either side of the upper edge of the metal strip. 11. Device as claimed in claim 10, characterized in that the drive rollers are placed at an angle such that the rotation axes of drive rollers located on the same side of the building construction wall diverge in the direction of travel of the building construction. 12. Device as claimed in claim 10 or 11, characterized in that at least one roller of each drive roller pair is adjustable spring-loaded, 13. Device as claimed in any of the claims 3-12, wherein a welding device is used for fastening the metal strip and the building construction part already manufactured to each other, characterized in that in the vicinity of the welding device at least one pair of guiding roller pairs for guiding the metal strip and the building construction part has been installed. 14. Device as claimed in claim 13, characterized in that the welding device comprises a device for one-sided or two-sided welding, wherein a cooling provision for cooling this side is provided on the side of the building construction wall remote from the welding device. 15. Device as claimed in any of the claims 3-14, characterized in that it is further provided with pressing rollers for pressing reinforcing profiles into the metal strip and / or the building construction part. 8 / {] ί: 1