DE20105709U1 - Magnetic formwork - Google Patents

Description

Description; Maanet formwork

The invention relates to a magnetic formwork for placement on a base plate with a formwork housing and a magnetic body suspended therein, which is movable between a raised position and a lowered position magnetically adhering to the base plate, wherein a lifting lever is provided for lifting the magnetic body from the lowered position.

In production plants for precast concrete components, magnetic formwork is used that can be fixed to a ferromagnetic base plate at any point using magnetic force. For this purpose, the magnetic formwork has a formwork housing that is designed according to the formwork purpose and is open at the bottom so that its lower edges rest on the base plate. At least one magnetic body is arranged within the formwork housing, via which the magnetic formwork can be fixed to the base plate with magnetic adhesion. Instead of a single magnetic body, several such magnetic bodies can also be provided.

Magnetic formworks are known in which the magnetic body is guided within the formwork housing so that it can be raised and lowered. The magnetic body is then

zen on the base plate in a raised position in which its underside is above the lower edge of the formwork housing, and at such a distance that the magnetic body is not attracted to the base plate by itself when the magnetic formwork is placed on the base plate. In order to be able to lower the magnetic body onto the base plate, it is connected to an actuating device designed as a lifting rod, which protrudes upwards from the formwork housing. To lower the lifting rod - there can be several - is pressed down by hand against the effect of a spring that holds the magnetic body in the raised position.

In one embodiment, the spring is arranged in such a way that the lifting rod is supported on the formwork housing via the spring (EP 0 842 339 Bl; DE 199 03 819 Al). In another generic embodiment, the magnetic body itself hangs on a spring device consisting of two rubber springs, whereby the rubber springs are attached on the one hand to the inside of the ceiling wall of the formwork housing and on the other hand to the top of the magnetic body, so that the lifting rod is not supported on the formwork housing, but only serves to actuate the magnetic body. In both cases, the lifting rod also serves to release the magnetic formwork from the base plate again by placing a lifting lever on the lifting rod and thus lifting the magnetic body either centrally or at one end, thereby losing its adhesion. The spring then moves the magnetic body

back into the raised position so that the magnetic formwork can be lifted off the base plate again.

The magnetic formwork described above has the disadvantage that the lifting lever for lifting the magnetic body has to be supported on the top of the formwork housing, so the formwork housing practically forms an abutment for the lifting lever. This poses the risk that the formwork housing will be bent or damaged. The stability of the formwork housing limits the adhesive force of the magnetic body. In addition, the lifting rod or rods hinder the tools and devices used for the subsequent processing of the poured concrete.

The invention is therefore based on the object of designing a magnetic formwork of the type mentioned at the beginning in such a way that high lifting forces can be achieved with its actuating device. In addition, annoying protrusions should be avoided. Finally, the aim should be to achieve a structure that is as simple and robust as possible.

The main object is achieved according to the invention in that the magnet body or an extension thereof has a shape forming a recess which is accessible from outside the formwork housing and from its side for the lifting lever, which is designed with an extension which can be inserted into the recess and has a support element which, when the lifting lever is inserted into the recess, is attached to the base plate

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The basic idea of the invention is therefore to make the magnetic body or an extension thereof accessible from the side so that the lifting lever can be inserted into it from the side, whereby it is essential that the lifting lever can be supported on the base plate for lifting the magnetic body, i.e. the base plate forms the abutment for the lifting lever. In this way, the formwork housing is not stressed by the lifting process and is therefore not subject to the risk of deformation or damage. Since the base plate is usually very stable, it can absorb high forces, i.e. high detachment forces can be achieved, with the result that magnetic bodies with significantly higher holding forces can be used. This enables large formwork heights with a narrow design and low weight. The length of the lifting lever allows the force required for the lever effect to be adjusted so that an operator can also lift magnetic bodies with high holding forces.

The lateral accessibility also makes it possible for the formwork housing to be completely smooth, particularly on the top side, and thus does not interfere with the subsequent processing of the poured concrete, i.e. does not hinder the tools and devices used.

In an embodiment of the invention, it is provided that a side wall of the formwork housing has an opening in the area of the recess through which the extension

can be inserted into the recess. It is particularly advantageous to design the support element as an eccentric, from which the extension extends and which can be rotated about a horizontal axis via a lever arm. When inserted, the eccentric should rest with its circumference on the base plate. The eccentric does not have to be circular, but can also describe a progressively rising and/or falling curve. In the case of a circular eccentric, the extension should extend off-center from the eccentric. The lifting lever preferably has a lever arm, via which the lifting lever can be rotated about a horizontal axis.

The recess is preferably arranged at one end of the magnet body, so that the magnet body is tilted from a horizontal position when the lifting lever is operated. It then only has an edge contact at the opposite end of the magnet body. The magnetic force is thereby reduced so much that it is also moved into the raised position at the other end via its suspension.

The invention further provides that the magnetic body is suspended from a spring device attached to the inside of the formwork housing in such a way that it is held in the raised position by the spring device and can be lowered against the action of the spring device, wherein the spring device is designed as a leaf spring, preferably with such a low spring force that the magnetic body can be moved by the spring device being applied intermittently.

The basic idea of the invention is to use a leaf spring arranged inside the formwork housing, on which the magnetic body is suspended, instead of the previously used disc, helical and rubber springs. Such a leaf spring is a particularly simple and robust spring device which is protected by the formwork housing due to its internal arrangement. In addition, the leaf spring forms a rigid connection between the formwork housing and the magnetic body in the horizontal plane, and consequently an exact guide between the two.

In a particularly preferred embodiment of the invention, the leaf spring should have such a low spring force that it just holds the magnetic body in the raised position when it is not placed on the base plate, but on the other hand allows the magnetic body to swing downwards due to its inertia, due to the impact when the magnetic formwork is placed on the base plate, so that the magnetic body comes to rest against the base plate in an adhesive manner, thereby fixing the magnetic formwork. No special actuating device is therefore required for lowering the magnetic body. The intermittent placement usually occurs automatically when the magnetic formwork is placed on the base plate by hand. The invention also opens up the possibility of the magnetic formwork being placed in the desired position with the help of a robot, whereby the

The robot is programmed to place the magnetic formwork in one push so that the magnetic body comes into the lowered position due to its inertia and then under the influence of the magnetic force, thereby fixing the magnetic formwork.

In a further embodiment of the invention, it is provided that the leaf spring extends essentially horizontally. It can be attached flatly to the underside of the formwork housing and to the top of the magnet body.

Leaf spring packages can be used as leaf springs. However, it is simpler if the leaf spring consists of just a single sheet metal strip of the appropriate thickness. If the formwork housing is designed as an elongated cuboid with a longitudinal axis, the leaf spring should extend parallel to the longitudinal axis, preferably beyond one end of the magnet body.

To achieve a good spring effect, the leaf spring should extend beyond the other end of the magnet body.

According to a further feature of the invention, it is provided that the magnetic body is also magnetically effective in the direction of the formwork housing, which then consists of ferromagnetic material, and is held magnetically in the raised position on the inside of the formwork housing. As a result, the magnetic body is held in the raised position

Position is clearly fixed without the need for adjustment work. The magnetic force acting between the magnet body and the formwork housing in the raised position should be lower than that between the magnet body and the base plate in the lowered position. This can be achieved, for example, by placing the leaf spring between the magnet body and the formwork housing in the raised position and by making it out of non-magnetic or non-magnetizable material. In this way, the magnetic force acting can be limited so that a sudden placement of the magnet formwork on the base plate is sufficient to move the magnet body into the lowered position.

The invention is illustrated in more detail in an embodiment in the drawing. They show:

Figure 1

a side view of the magnetic formwork;

Figure 2

a plan view of the magnetic formwork according to Figure 1;

Figure 3

a longitudinal section through the magnetic formwork according to Figures 1 and 2 with the magnetic body in the raised position;

Figure 4

the longitudinal section according to Figure 3 with the magnet body in lowered position and attached eccentric lever and

Figure 5 shows the longitudinal section according to Figures 3 and 4 with rotated eccentric lever.

Figures 1 and 2 show a magnetic formwork which has a formwork housing 2 which is U-shaped in cross section and open at the bottom. The length of the formwork housing 2 can be any length. It is usually made of a steel profile or another ferromagnetic material. The formwork housing 2 rests with its lower edge 3 on a ferromagnetic base plate 4.

The formwork housing 2 has a horizontal ceiling wall 5, from which side walls 7, 8 extend vertically downwards. The heads of two countersunk head screws 9, 10 can be seen in the ceiling wall 5. Offset from this, an oval through hole 11 is formed in the side wall 8, the longitudinal axis of which is vertical.

In the longitudinal section according to Figure 3, it can be seen that a cuboid-shaped magnetic body 12 is arranged within the formwork body 2. The magnetic body 12 is suspended from a horizontally extending leaf spring 13 made of non-magnetic material. One end of the leaf spring 13 is attached to the underside of the ceiling wall 5 at a longitudinal distance from the magnetic body 12 via the two countersunk screws 9, 10. The leaf spring 13 extends over almost the entire length of the magnetic body 12 and is attached to its upper side via two further

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Countersunk screws 14, 15 connected to the magnet body 12.

In the illustration shown, the magnetic body 12 is in the raised position. The magnetic body 12 is designed in such a way that it also develops magnetic force in the direction of the formwork housing 2, so that the magnetic body 12 is held in the raised position not only by the leaf spring 13, but also by the magnetic force acting between the formwork body 2 and the magnetic body 12. However, because the non-magnetic leaf spring 13 runs between the two, the magnetic force is limited and lower than between the base plate 4 and the magnetic body 12 in its lowered position.

The underside 16 of the magnetic body 12 runs parallel to the base plate 4 and is at such a distance from it that the magnetic forces acting there are too small to attract the magnetic body 2 to the base plate 4. The leaf spring 12 is relatively weak so that it can hold the magnetic body 12 in just the position shown. In order to maintain this position, the magnetic circuit 1 must therefore be carefully placed on the base plate 4. The magnetic formwork 1 can then be moved on the base plate 4.

Figure 4 shows the magnetic body 12 in a lowered position, i.e. with its underside 16 adhering to the base plate 4. This position is achieved by placing the magnetic formwork 1 on the base plate 4 in such a way that

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is such that a shock is created which, due to its inertia, causes the magnetic body 12 to swing downwards against the effect of the leaf spring 13, so that the magnetic force acts between the magnetic body 12 and the base plate 4 and the magnetic body 12 is pulled to the base plate 4. Due to the connection between the magnetic body 12 and the formwork housing 2 by the leaf spring 13, the entire magnetic formwork 1 is fixed in position relative to the base plate 4. It is advantageous that the leaf spring 13 guides the formwork housing 2 in the longitudinal and transverse directions, thus essentially forming a rigid connection to the magnetic body 12.

As can be seen from Figure 3, the magnet body 12 has an extension 17 at the right end. In the extension 17 there is a cross hole 18 with a horizontal axis. The cross hole 18 is aligned with the through hole 11 (Figure 1) in the side wall 8 of the formwork housing 2, and is therefore accessible from the outside. The through hole 11 is dimensioned such that the cross hole 18 is aligned with the through hole 11 in every position of the magnet body 12.

In Figure 4, an eccentric lever 19 is shown, which has a circular eccentric 20, from which an actuating lever 21 extends diagonally upwards. A horizontally extending insert bolt 22 extends from the eccentric 20 and is arranged off-center. In the position of the eccentric lever 19 shown, the insert bolt 22 is inserted through the through hole 11 and into the

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Cross hole 18. The circumference of the eccentric 20 rests on the base plate 4.

The eccentric lever 19 is only inserted into the cross hole 18 in the manner shown when the magnetic formwork 1 is to be removed from the base plate 4. It is therefore not an integral part of the magnetic formwork 1, but serves merely as a tool that can be used to lift magnetic formwork 1 of the type shown here. To lift the magnetic formwork 1, the eccentric lever 19 is turned clockwise after being inserted into the cross hole 8. As can be seen from Figure 5, this has the consequence that the magnetic body 12 is lifted on one side, i.e. in the area of the extension 17, and is thereby inclined. The magnetic body 12 then only has contact with the base plate 4 via the transverse edge at the other end. The magnetic force remaining between the magnetic body 12 and the base plate 4 is then less than the spring force exerted by the leaf spring 13, so that the magnetic body 12 is moved by the leaf spring 13 into the raised position shown in Figure 3. The eccentric lever 19 can then be removed and the magnetic formwork 1 can be removed from the base plate 4. The eccentric lever 19 can then be used to remove further magnetic formworks.

With the eccentric lever 19, very high lifting forces can be achieved, since - as with the magnetic formwork in the state of the art - the stability of the magnetic formwork 2 does not have to be taken into account.

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The shape of the eccentric 20 - a circular design is not necessary - and the length of the operating lever 21 mean that the force required by the operator can be designed in such a way that the operator is not overwhelmed even when high lifting forces are exerted on the magnetic body 12. This opens up the possibility of using magnetic bodies 12 with very high holding power, and thus achieving large formwork heights with a narrow design.

Claims (19)

1. Magnetic formwork ( 1 ) for placement on a base plate ( 4 ) with a formwork housing ( 2 ) and a magnetic body ( 12 ) suspended therein, which can be moved between a raised position and a lowered position magnetically adhering to the base plate ( 4 ), wherein a lifting lever ( 19 ) is provided for lifting the magnetic body ( 12 ) from the lowered position, characterized in that the magnetic body ( 12 ) or an extension ( 17 ) thereof has a shape forming a recess ( 18 ) which is accessible from outside the formwork housing ( 2 ) and from the side thereof for the lifting lever ( 19 ), which is designed with an extension ( 22 ) which can be inserted into the recess ( 18 ) and has a support element ( 20 ) which can be inserted into the recess (18). 18 ) when the lifting lever ( 19 ) is inserted, rests on the base plate ( 4 ). 2. Magnetic formwork according to claim 1, characterized in that a side wall ( 8 ) of the formwork housing ( 2 ) has an opening in the region of the recess ( 18 ) through which the extension ( 22 ) can be inserted into the recess ( 18 ). 3. Magnetic formwork according to claim 1 or 2, characterized in that the support element is designed as an eccentric ( 20 ) from which the extension ( 22 ) extends and which can be rotated about a horizontal axis via a lever arm ( 21 ). 4. Magnetic formwork according to claim 3, characterized in that the eccentric ( 20 ) rests with its circumference on the base plate ( 4 ) in the inserted state. 5. Magnetic formwork according to claim 3 or 4, characterized in that the eccentric ( 20 ) is circular and the extension ( 22 ) extends off-center from the eccentric ( 20 ). 6. Magnetic formwork according to one of claims 1 to 5, characterized in that the lifting lever ( 19 ) has a lever arm ( 21 ) via which the lifting lever ( 19 ) can be rotated about a horizontal axis. 7. Magnetic formwork according to one of claims 1 to 6, characterized in that the recess ( 18 ) is arranged at one end of the magnetic body ( 12 ). 8. Magnetic formwork according to one of claims 1 to 7, characterized in that the magnetic body ( 12 ) is suspended from a spring device ( 13 ) fastened to the inside of the formwork housing ( 2 ) in such a way that it is held in the raised position by the spring device ( 13 ) and can be lowered against the action of the spring device ( 13 ), the spring device being designed as a leaf spring ( 13 ). 9. Magnetic formwork according to claim 8, characterized in that the spring force of the leaf spring ( 13 ) is so small that the magnetic body ( 12 ) is pressed onto the base plate ( 4 ) by intermittent placement of the magnetic formwork ( 1 ) on the base plate. 10. Magnetic formwork according to claim 8 or 9, characterized in that the leaf spring ( 13 ) extends substantially horizontally. 11. Magnetic formwork according to one of claims 8 to 10, characterized in that the leaf spring ( 13 ) is attached flat to the underside of the formwork housing ( 2 ). 12. Magnetic formwork according to one of claims 8 to 11, characterized in that the leaf spring ( 13 ) is attached flat to the upper side of the magnetic body ( 12 ). 13. Magnetic formwork according to one of claims 8 to 12, characterized in that the leaf spring ( 13 ) consists of a single sheet metal strip. 14. Magnetic formwork according to one of claims 8 to 13, characterized in that the formwork housing ( 2 ) is designed as an elongated cuboid with a longitudinal axis and that the leaf spring ( 13 ) extends parallel to the longitudinal axis. 15. Magnetic formwork according to one of claims 8 to 14, characterized in that the magnetic body ( 12 ) can be lifted by means of the lifting lever ( 19 ) to such an extent that the magnetic body ( 12 ) is moved further into the lifted position under the action of the leaf spring ( 13 ). 16. Magnetic formwork according to one of claims 8 to 15, characterized in that the leaf spring ( 13 ) extends beyond the other end of the magnetic body. 17. Magnetic formwork according to one of claims 1 to 16, characterized in that the magnetic body ( 12 ) is also magnetically effective in the direction of the formwork housing ( 2 ) and is held magnetically in the raised position on the inside of the formwork housing ( 2 ). 18. Magnetic formwork according to claim 17, characterized in that the magnetic force acting between the magnetic body ( 12 ) and the formwork housing ( 2 ) in the raised position is lower than that between the magnetic body ( 12 ) and the base plate ( 4 ) in the lowered position. 19. Magnetic formwork according to at least claims 8 and 17 or 18, characterized in that the leaf spring ( 13 ) in the raised position lies between the magnetic body ( 12 ) and the formwork housing ( 2 ) and consists of non-magnetic or non-magnetizable material.