NL1035366C2 - Lifting magnet for use in ships, has frame arranged in electromagnets, and solenoid utilized for lifting load to placing unit, where placing unit is placed under load to be secured to adjustable arms along longitudinal direction - Google Patents

Abstract

The magnet (1) has a frame (3) arranged in electromagnets. A solenoid is utilized for lifting load (2) to a placing unit, where the placing unit is placed under the load to be secured to adjustable arms (6) along longitudinal direction. A pair of telescopic parts (7, 8) is arranged relative to each other and provided with slidable parts. The placing unit comprises two carrying members that are arranged opposite to each other and placed under the load. An insert part is attached to telescopic arms that are arranged with respect to the magnet that is located in a pivot axis.

Description

Short indication: Lifting magnet.

DESCRIPTION

The invention relates to a lifting magnet according to the preamble of claim 1.

Such electromagnets have been used for a long time for lifting metal objects, such as metal plates, coils wound from metal plate and the like.

If, when using lifting magnets that work with electromagnets, the power fails, there is a danger that a load hanging on the lifting magnet will fall down. Provisions have been made here for, for example, if the main current fails, energize the magnets for some time with the aid of an auxiliary current, but a complete failure of the electromagnets of lifting magnets equipped with electromagnets cannot be completely excluded. In particular, if a load is lifted over a great height with the aid of a lifting magnet, for example when unloading plates or the like from sea-going vessels, a possible fall of the load can result in considerable damage.

British patent document 1470229 A describes a construction in which a load can be lifted. The claws are suspended from a swivel mechanism with a hoist.

It is an object of the invention to provide a lifting magnet of the above-mentioned type, wherein drawbacks associated with the known lifting magnets can be avoided.

According to the invention this can be achieved in that the means to be placed under the load are attached to arms which are adjustable in their longitudinal direction.

By using the construction according to the invention, with the aid of mechanical aids a falling of a load in the event of failure of the electromagnet (s) can be prevented, because these means stop or collect the load, whereby an efficient displacement of the supporting members can be effected if the carrying members are arranged on arms which are slidable in their longitudinal direction.

An efficient construction is thereby obtained if the means comprise at least two supporting members placed substantially opposite each other and to be moved under a load.

The arms are herein preferably pivotable up and down relative to the lifting magnets to bring the supporting members from an active position into a non-active position in which they do not hinder the placing of the lifting magnet on a load to be received.

The invention will be explained in more detail below with reference to the accompanying figures.

Figure 1 shows schematically a view of a lifting magnet according to the invention, which is placed on a load to be picked up and in which a support member is in the non-operative position.

Figure 2 shows a view similar to Figure 1, in which a support member is placed in the active position.

In the figures a lifting magnet 1 is shown, which is placed on a load 2 to be picked up, for example one or more metal plates stacked on top of each other. The lifting magnet 1 will have a conventional structure and be provided with one or more electromagnets accommodated in a frame 3 of the lifting magnet 1. A support 4 is mounted on the top of the electromagnet 1 near a side of the electromagnet 1. With the aid of a pivot axis 5 which extends parallel to the bottom surface of the lifting magnet 1 to be received on a load 2, an arm 6 is pivotally connected. The arm 6 herein comprises two parts 7 and 8 telescopically slidable with respect to each other. A nut 9 is attached to the inner end of the inner telescopic part 8. A screw rod 10 extending into the interior of the telescopic part extends through this nut and is screwed through the nut 9. The end of the threaded rod 9 facing the pivot axis 5 is coupled via a coupling 11 to a shaft 12 mounted in the arm 6. On the end of the shaft 12 remote from the coupling 11 a gear wheel 13 is attached, which is engaged. with a gear wheel 14, which is attached to the output shaft 15 of an electric motor 16 received in the arm 6.

At the end of the inner telescopic part 8 remote from the nut 9, a further arm 17 extending perpendicularly to this part is attached. Attached to the end of the arm 17 is a support member 18 protruding outside the arm, which member extends in the direction of the lifting magnet 1 from the lower end of the arm 17.

3

Furthermore, a further support 19 is attached to the frame 3 of the lifting magnet on the side remote from the support 4, into which a mechanism is accommodated by means of which the arm 6 with the parts connected therewith can be pivoted about the pivot axis 5, said mechanism for instance can be formed in a manner known per se by an adjusting cylinder, a screw spindle or the like.

For receiving a load, such as, for example, one or more metal plates, the lifting magnet 1 can be placed on the top of the load to be picked up, while the arm 6 with the parts connected thereto are in the upwardly pivoted position shown in Figure 1. is located.

After the load has been moved upwards over a certain distance, the inner telescopic part 8 of the arm 6 can be extended from the outer telescopic part 7 of the arm 6 to a position in which it is taken from the position shown in Figure 1 by rotating the screw spindle 10. As shown in Figure 1, the arm 6 can move the support member 17 beyond the right-hand side of the received load 2 shown in Figure 1. After the arm 6 has been pivoted in a position in which the support member 18 is situated lower than the underside of the load to be received, the inner arm part 8 can be moved by turning the screw spindle 10 to a position in which the support member 18 is under the load 2 will be located.

In the figures, only a single pivotable arm 6 is shown, but it will be clear that a second pivotable arm 6 will be mounted on the lifting magnet 1, such that this second arm 6 is positioned in a position relative to that shown in the figures. arm 6 with the associated parts in a position rotated through 180 ° will be connected to the lifting magnet 1, all such that the support member 18 associated with this second arm 6, seen in the figures below the left end of the received load 2 can be shifted.

It will further be clear that in the event of a failure of the current energizing the electromagnets of the lifting magnet 1, the received load 2 will be collected by the means 18 formed under the load 2, so that the load 2 falls down. will be prevented.

It will further be clear to those skilled in the art that, within the spirit and scope of the invention, modifications may be made to the exemplary embodiment depicted in the figures and described above.

For example, the parts 7 and 8 of the arm 6 which are telescopically displaceable relative to each other can be displaced relative to each other instead of by a screw spindle with the aid of a pneumatic or hydraulic adjusting cylinder or the like.

Furthermore, it will be possible for the further arm to be telescopic for adapting to the height of a load to be lifted.

Instead of a pivotable arm 6, the arm with the parts connected thereto could be arranged on the lifting magnet, for example adjustable in height.

Instead of using a telescopic arm, it could, for example, also be slidably arranged on the lifting magnet parallel to the bottom surface of the lifting magnet.

15 1035366

Claims (7)

1. Lifting magnet provided with a frame, with one or more electromagnets arranged in the frame, and with means to be placed under a load lifted with the lifting magnet 5, which are designed such that they fall out of the load in the event of a possible failure. of an electromagnet (s), characterized in that the means to be placed under the load are attached to arms which are adjustable in their longitudinal direction. 2. Lifting magnet as claimed in claim 1, characterized in that an arm 10 comprises two parts that can be moved telescopically with respect to each other. 3. Lifting magnet as claimed in claim 1 or 2, characterized in that the means to be placed under the load are displaceable in height relative to the frame of the lifting magnet. 4. Lifting magnet as claimed in any of the foregoing claims, characterized in that the means to be placed under the load can be moved at least substantially parallel to the bottom surface of the lifting magnet. 5. Lifting magnet as claimed in any of the foregoing claims, characterized in that the means comprise at least two bearing members which are placed substantially opposite each other and can be moved under the load. 6. Lifting magnet as claimed in any of the foregoing claims, characterized in that means to be placed under the load are fixed to the arms up and down with respect to the lifting magnet. 7. Lifting magnet according to claim 6, characterized in that the arms are pivotable about pivot axes located near opposite sides of the lifting magnet. 1035366