NO159114B - GLIDE FORSKALING. - Google Patents

Description

The present invention relates to a sliding formwork according to the preamble of claim 1.

The purpose of the present invention is to provide instructions for a new and improved sliding formwork construction, with the help of which heavily sloping, hollow building components whose transverse dimension can also vary according to height, can be erected simply and rationally.

For this purpose, according to the invention, it is proposed that the sliding formwork is also given the features specified in the characterizing part of claim 1. Thereby, a relatively light formwork construction is achieved which causes relatively small stresses on the parts of the already cast part of the building component against which the diagonal braces act.

With the arrangement according to claim 2, a favorable power transmission to the superstructure and a power distribution in this is achieved.

Claims 3-6 state favorable embodiments of the invention, which include eliminates the need for constant adjustments to the position of the inclined beams relative to the superstructure when casting a building component with a constantly increasing transverse dimension. The extent of the mold construction downwards from the lower edges of the mold walls can also be made negligible.

Claim 7 indicates a favorable embodiment of the invention, as the upper and lower edges of the mold walls can be adjusted in a simple way during ongoing casting, so that they will lie essentially in the same horizontal plane regardless of the inclination of the building component.

In the following, the invention will be described in more detail with reference to the drawing, since further special features and advantages of the invention will be apparent from this description. Fig. 1 shows a section through a sliding formwork according to the invention. Fig. 2 shows on a larger scale and in more detail the upper, right part of the sliding formwork according to fig. 1. Fig. 3 is a schematic plan view of the sliding formwork and shows the location of the inclined struts.

With the sliding formwork according to figures 1-3, each lifting yoke consists, as is most clearly evident from fig. 2, of two yoke legs 10, respectively 11, and two yoke beams 12,13 which are rigidly attached to a sleeve 14 which is longitudinally displaceable along one yoke leg 10, and which extends to and is longitudinally displaceable stored in guides 15 on a second sleeve 16 which is longitudinally displaceable along the second yoke leg 11.

Each lifting yoke 10-13 is carried by a support beam 17 which is formed by two U-beams with webs facing each other between which the upper end of the yoke legs 10,11 protrude. The lifting yoke 10-13 is carried via the fasteners 18 which grip the lower flanges of the mentioned U-beams and can slide along the associated support beam 17 and in which the yoke legs 10, 11 are stored pivotably about substantially perpendicular to the respective beam 17 running axes. Each sleeve 14, 16 carries a fastener 19 in which a screw 20 is rotatably stored which cannot be moved axially and which is in threaded engagement with a threaded hole in an ear 21 of the continuous yoke leg 10 or 11 and protrudes through a longitudinal slit in the sleeve. By turning the screws 20, the inclination of the yoke legs 10, 11 relative to the vertical plane can therefore be set to the desired value. In a fixed attachment 22 on each support beam 17, a screw 23 is stored rotatably, but axially immovable, which is in threaded engagement with a threaded hole in a attachment 24 on the lifting yoke 10-13 drilled from the support beam 17, so that the lifting yoke position along the support beam can be regulated by turning the screw 23. To regulate the distance and possibly the inclination between the yoke legs 10, 11, in the fasteners 25 on the yoke beams 12,13 there are rotatably but immovably stored screws 26 which engage with each threaded hole in the parties

27 on the sleeve 16. When turning both screws 26 in a parallel manner, the yoke leg 11 is thus displaced relative to the yoke leg 10, while with unequal rotation of the two screws 26, the yoke legs 10,11 can be tilted relative to each other to a certain and usually smaller extent.

28 denotes a part of a building component, e.g. an inclined leg for an oil platform which is being built up by means of the sliding formwork and which on it in fig. 3 indicated way can have, in horizontal section, substantially circular limiting surfaces which are shown to lean outwards 4° relative to the longitudinal axis 29 of the part 28, which in turn inclines 16° relative to the vertical.

Opposite formwork walls 30 are used which are formed by overlapping formwork surfaces 31 (fig. 1) which are carried by the yoke legs via first form support members 32, the overlapping arrangement between adjacent formwork surfaces 31 can be arranged on e.g. in the manner shown in more detail in SE patent 351,885 or US patent 4,312,492.

Each yoke beam 13 carries lifting members 33 which are arranged for, in a known manner, by engagement with climbing rods 34 placed in the concrete component and lifting the sliding formwork as the concrete hardens. Between the lifting yokes 10-13, e.g. act as additional form support organs in the way that e.g. shown in and described in SE patent 351,885.

It is obvious that the sliding formwork when casting the sloping building component, as a result of the occurring forces, tends to move too much in the lateral direction to the right in fig. 1-3, and the sliding formwork must in practice therefore be provided with special means to counteract this tendency. Previously known means for this purpose include heavy parts extending very deep under the formwork walls which exert a very high concentrated pressure on already cast parts of the component.

In the device according to fig. 1-3, in order to absorb forces coming from the building component's inclination, a superstructure is arranged in the form of a crown which includes the support beams 17 and truss details 35 that support these, where the support beams 17 extend radially uniformly distributed towards a central ring 36, and the there are arranged between the superstructure 17,35,36 and obliquely upward sloping flat parts 3 7,38 of the already cast part 28 acting inclined struts 39,40, of which at least some act between the superstructure 17,35,36 and the obliquely upwards sloping the parts 37 on the inside of the part 28. The inclined beams 39, 40, of which only a small part of the total number is shown, are designed as truss beams which, at their upper end, can be pivoted relative to the superstructure 17, 35, 36, in order to achieve low weight and great rigidity, and are arranged with bodies 41, 42 to keep their lower parts in contact with said surface parts 37,38. In the embodiment shown, these bodies consist partly of struts 41 which are articulately connected to each of the yoke legs 10 or 11 and at whose lower ends the struts 39,40 lower parts are articulately suspended, and partly of tensile force-absorbing devices 4 2 in the form of drawbars which at opposite ends is hingedly connected to the upper part of an inclined strut 39 or 40 and a lifting yoke 10-13. At the lower end, the inclined struts 39,40 are provided with members 43 which facilitate movement along the outer parts 37,38, such as rollers or sliders.

At their upper ends, the inclined struts 39,40 are movable in guides which are carried by the superstructure and one of which is shown at 44 in fig. 2. More specifically shown in fig. 2, the upper end of an inclined strut 39 which can be articulated in a mount 45 which is displaceably stored along the guide 4 4 and drilled by the guide, to which the end of the device 4 2 facing away from the associated lifting yoke is also connected in an articulated manner. The inclined ribs 39 and 40 are mutually connected by means of spacers 46 which determine and regulate the distance between them and which in the drawing are shown designed as stretchers.

It is realized that the slope of the inclined bars 39.40, which should be between approx. 30° and 60° relative to the horizontal plane, with the help of the devices 42 can easily be set so that the inclined bars act against the obliquely upward sloping surface parts 37, 38, where a slanting upward and to the left in fig. 1-3 directed reaction force which counteracts the said tendency in the sliding formwork and moves in the lateral direction to the right in fig. 1-3, and at the same time also relieves vertical forces on the climbing struts 34 which are exerted by the sliding formwork's own weight. In the embodiment shown, the lower ends of the inclined struts 39, 40 are moved by the upward movement of the sliding formwork and move along lines which substantially coincide with the direction of an associated yoke leg 10 or 11, by setting the spacers 45 corresponding to the increase or decrease of the diameter of the sliding formwork. Assuming that the guides 44 are arranged parallel to the associated support beam 17, no adjustment of the devices 42 is required when the sliding formwork is raised in the case of a constantly increasing or decreasing diameter or in the case of an unchanged diameter of the form. This also applies if the guides 44 are arranged parallel to, but next to the associated support beams 17 in order to direct the reaction forces caused by the inclined struts 39,40 on the superstructure 17,34,35 more parallel to a substantially from right to left in fig. 3 continuous diameter.

The invention is not limited to the embodiment described above and with reference to the drawing, but the invention can of course be realized in the desired manner within the framework of the inventive idea defined in the patent claims.

Claims (1)

1. Sliding formwork for erecting a sloping, hollow building component, in particular a leg for an offshore platform, comprising two opposite formwork walls (30) which are supported by downwardly projecting yoke legs (10,11) on a number of lifting yokes (10,13), which, for variation of the building component's transverse dimension and inclination, are movable and pivotable relative to a formwork superstructure (17,35,36), characterized in that for the absorption of forces coming from the building component's inclination, several inclined struts (39,40) are arranged which act, between the formwork superstructure (17,35,36) and the obliquely upwards facing surface parts (37,38) of an already molded part (28) of the component. 2. Sliding formwork according to claim 1, characterized in that at least some of the inclined struts (39) act between the formwork superstructure (17,35,36) and surface parts (37) on the inside of the component part (28). 3. Sliding formwork according to claim 1 or 2, characterized in that the inclined struts (39,40) at their upper ends are pivotable relative to the formwork superstructure (17,35,36) and coordinated with bodies (41,42) to keep their lower ends in contact with the above-mentioned, obliquely upwards sloping surface parts (37,38). 4. Sliding formwork according to claim 3, characterized in that the inclined struts (39,40) at their upper ends are movable in guides (44) which are carried by the formwork superstructure (17,35,36) and are held in the desired position along the associated guide with the help of the device (42) which essentially takes only tensile forces. 5. Sliding formwork according to claim 3 or 4, characterized in that the inclined struts (39,40) at their lower ends are hingedly suspended at the lower end of bodies (41) which are hingedly connected at their upper end to each yoke leg (10,11 ). 6. Sliding formwork according to one or more of the claims from 3-5, characterized in that the inclined struts (39,40) are interconnected by means of adjustable spacers (46) which determine the distance between the inclined struts (39,40). 7. Sliding formwork according to one or more of the claims from 1-6, where the lifting yokes (10-13) have pivotably mounted yoke legs (10, 11) and yoke beams (12,13) running between the connecting yoke legs, characterized in that each yoke beam (10,12) in each of the lifting yokes (10,13) is fixedly placed on one and longitudinally displaceable in another of two sleeves (14 ,16), which in turn are longitudinally displaceable arranged on and in the desired displacement position adjustable relative to each of the lifting yoke's yoke legs (10,11).