DE60003554T2 - Magnetic lifting device - Google Patents

Description

BACKGROUND OF THE INVENTION 1 , Field of the Invention

The present invention relates to a magnetic lifting device and in particular an improved one magnetic lifting device using a neodymium magnet, which prevents the neodymium magnet from oxidizing to the magnetic Performance and durability with a switchable function one Improve on / off handle.

2. Description of the stand of the technique

The magnetic lifting device will in the prior art for lifting, conveying and releasing the ferromagnetic objects used by switching the magnetization on or off.

Generally, the magnetic lifter includes Pole plates, spacers in between, side walls and an upper cover which is arranged a hook. The plate-shaped pole plates are with a permanent magnet arrangement arranged between them. Each pair of pole plates is separated by a non-magnetic medium. A rotor is arranged so that the magnetic polarity is below Using the switching handle. Such a lifting device is known from EP-A-630851.

Located in the middle of the rotor there is an axial opening, through which the axis rotates in the rotor and the polarity plates added is. One end of the axis is with the switching handle for rotating the Axis connected.

Depending on the on / off position the switching handle, the objects are lifted or released. In the raised state of the objects, a blocking element prevents that the rotor inadvertently moves in the off direction.

When turning the switching handle the polarity the magnetic line of force changed, because the directional position of the permanent magnet is switched. The magnetic force turns OFF in the event that the magnetic line of force to the opposite Pole plates separated by the non-magnetic medium, is applied. When the rotor is switched on again, the Direction of the magnetic line of force applied to the pole plates, which thereby the objects adsorb under the pole plates with a strong magnetic attraction, to raise it and to the one you want Place to move.

As a permanent magnet of the magnetic lifting device the ferrite magnet with the residual magnet density is less than 2000 gauss common.

However, in order to have a relatively large dimension of the To improve ferrite magnets, it is necessary to improve the magnetic To improve attraction.

The large size of the ferrite magnet makes it a relatively large one Dimension of the magnetic lifting body required in a magnetic lifting device, which in the Use and is disadvantageous in view of the high manufacturing costs.

The use of the neodymium magnet in the range of the residual magnetic density of 10000-13000 Gauss the Function of the magnetic body improve. However, the slight oxidation is a serious disadvantage of the neodymium magnet when the neodymium magnet is exposed to the atmosphere is, which reduces the magnetization.

To avoid the above disadvantage can have a coating on the surface of the neodymium magnet Resin or metal can be proposed. However, the use of the coated leads Neodymium magnets in the rotor to peel off the coated film, since he's inevitable turns in contact with the pole plates.

SUMMARY OF THE INVENTION

It is therefore an aim of the present Invention, Using an Improved Magnetic Hoist of the neodymium permanent magnet with high coercive force on the rotor provide an anti-oxidation device near the neodymium magnet is formed.

The other goal of the present The invention is to provide a magnetic lifting device taking the direction of the rotor easily with a minimum of force is turned on and off, which increases productivity and reliability improve.

To achieve these objects of the present invention, there is provided a magnetic lifter comprising: plate-shaped polarity plates 10 arranged at a predetermined distance with a non-magnetic medium thereon; a spacer 20 to keep the distance between the polarity plates 10 ; a top cover 30 that the spacer 20 and the polarity plates 10 covers, with a hook 31 at the top; an opposite neodymium magnet 40 with S / N polarity, between the polarity plates 10 is arranged; a rotor 50 with the neodymium magnet inserted into it 40 rotated; a switching handle 60 for switching the polarity position of the rotor 50 and the engaged neodymium magnet 40 to turn magnetic attraction on and off; and an oxidation protection device 70 to block the neodymium magnet 40 from oxygen. The magnetic lifter of the invention has a characteristic to protect the neodymium magnet from oxidation to higher Le to have life and performance.

In the present invention the switching handle is easy to switch the magnetic on and off Attractiveness to use, increasing productivity and reliability improve.

The scope of the present invention is clear from the detailed description given below become. However, it should be understood that the detailed description and the specific examples, although they are preferred embodiments denote the invention, given only as an example, since various changes and Modifications within the teaching of the invention to those skilled in the art this detailed description will become clear.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention is more fully understood from the detailed description given below and the accompanying Drawings given by way of example only and consequently for the present one Not limiting invention are.

1 Fig. 4 is an exploded perspective view of the preferred embodiment of the magnetic lifter according to the present invention.

2 is a sectional view showing a shaft 61 , a rotor 50 and one through the shift handle 60 turned neodymium magnets 40 shows, with a plurality of rotors 50 between the polarity plates 10 ,

3a and 3b are cross-sectional views of the 2 which an anti-oxidation device 70 show that near the rotor 50 is filled.

4 is an exploded perspective view showing the construction of the rotor 50 and its spacer 20 according to the present invention.

5 10 is an exploded perspective view of another embodiment of FIG 4 that one on the spacer 20 arranged cap 21 and shows a liquid antioxidant material used as an antioxidant 70 the cap 21 is fed.

6 is a sectional view of the 5 ,

7 is a sectional view of another embodiment of the rotor having a pair with respect to the rotor 50 opposite neodymium magnets 40 and a pair of polarity plates 10 shows.

8A . 8B and 8C are perspective views, the modifications of the liquid receiving openings 72 shows which in the interface of the neodymium magnet 40 to the rotor 50 are formed to act as an antioxidant 70 to serve.

9 Fig. 4 is an enlarged partial view taken from the interface of the neodymium magnet 40 that the fluid intake openings 72 as an anti-oxidation device 70 shows.

10 Fig. 3 is an enlarged partial view taken from the interface of the rotor 50 that the fluid intake openings 72 as an anti-oxidation device 70 shows.

11 shows another embodiment of the rotor 50 and the neodymium magnet 40 , where the neodymium magnet 40 with two split shapes a rotor 50 in a bar and forms a fluid intake space 74 on the polarity plates 10 is arranged.

12 is a perspective view of the rotor 50 the 11 ,

13 is an enlarged view of the "A" portion of FIG 11 that the fluid intake gap 74 between the neodymium magnet 40 and the polarity plate 10 shows.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

As in 1 shown, the polarity plate works 10 of the present invention in such a manner that the magnetic line of force is changed by switching the N / S polarity position, thereby holding or releasing the ferromagnetic objects to lift and move them to the desired location.

The plate-shaped polarity plate 10 is for separating the polarity on the non-magnetic medium 11 attached opposite by welding and arranged at a predetermined distance. The number of polarity plates is related to the holding capacity.

Between the polarity plates 10 are the spacers 20 arranged so that the space between the polarity plates 10 remains and the lower part is blocked.

On the polarity plates 10 and the spacers 20 is a top cover 30 arranged so that the inside is sealed.

The top cover 30 is by a plurality of bolts 32 tightly attached and is lifted and moved by a hook of the crane or hoist.

Between the polarity plates 10 is a pair of neodymium magnets 40 with S / N polarity arranged opposite, and the rotor 50 holds the neodymium magnets 40 engaged in two for a rotation.

If desired, the shift handle 60 to use the rotor 50 and the engaged neodymium magnets 40 to rotate a predetermined angle, the polarity of the neodymium magnets 40 switched to the polarity plates 10 by the non-magnetic plate 11 are oppositely divided to magnetize and unmagnetize, thereby keeping the objects in the ON state, in order to use the device, such as. B. a crane or a hoist to lift and to the desired location move.

In order to prevent contact with the oxygen in the atmosphere, the present invention provides an anti-oxidation device 70 near the neodymium magnet 40 ready. The magnetic lifter of the invention uses the neodymium magnet 40 with high flux density over 10000 gauss. Despite the higher performance of the neodymium magnet 40 it can easily be oxidized by oxygen, which leads to corrosion and low durability. The oxidation protection device 70 serves the oxidation of the neodymium magnet 40 prevent by contact with oxygen.

To provide the oxidation protection device 70 several methods are proposed: one method is the neighborhood of the rotor 50 and the neodymium magnet 40 to evacuate; another method is to colloidal fluid, such as. B. Arrange fat so that oxygen is blocked; and the third method is to coat the vicinity of the neodymium magnet by coating a metal or a synthetic resin with a film. It is most preferred to use the colloidal fluid, e.g. B. fat, in terms of lubrication and manufacturing costs when operating the neodymium magnet 40 and the rotor 50 to use.

The colloidal fluid forms an oil film in the vicinity of the neodymium magnet 40 of high magnetic current density with a coercive force over 10000 gauss, which blocks the outside air, causing the neodymium magnet 40 protects against oxidation, and forms a magnetic path even though the distance between two polarity plates 10 is very close to maintain strong holding performance.

Consequently, the improved minimized magnetic lifting device of the invention the size and weight of a body.

With respect to the 4 and 5 are the spacers 20 formed with an open top to a circular plate-shaped rotor 50 to keep. This form is advantageous when filling the anti-oxidation material, e.g. B. the colloidal liquid, in the vicinity of the rotor 50 ,

The cap 21 on the open top of the spacers 20 is covered by bolts so that it is the rotor 50 surrounds and forms a pouring hole 22 on the cap 21 ( 5 ). At the pouring hole 22 is one by a feather 23 elastic ball 24 arranged so that it closes an opening. The colloidal fluid as an oxidation protection material is at higher pressure than the elastic spring 23 poured in so that they could be around the rotor 50 and the neodymium magnet 40 is filled around. This replenishment is often done when necessary.

The spacers 20 and the polarity plates 10 are by a plurality of pins 25 coupled that in pin holes 15 and 26 are inserted.

The neodymium magnet 40 holding rotor 50 is done by operating the switching handle 60 position switched to switch the polarity position. The stop type of the rotor 50 can be a circular plate-shaped neodymium magnet held therein 40 his ( 1 to 10 ) or a pole type with the neodymium magnet 40 ( 11 and 12 ).

Around a pair or two pairs of neodymium magnets 40 To be arranged opposite one another is preferably a magnetic receiving opening 51 educated. A square or long oval axial opening 52 is in the middle of the rotor 50 formed to a wave 61 to record for a rotation.

The shaft protrudes so that it enters the axial opening 52 of the rotor 50 and the axial opening 13 the polarity plate 10 penetrates for an intervention. A switching handle 60 is at one end of the wave 61 formed which the holding power in accordance with the position of the switching handle 60 turns on and off.

A handle locking element 90 is used to prevent the switch handle 60 slid in the unwanted direction.

The blocking process of the handling blocking element 90 takes place by means of a jack 91 and a head start 92 , In the case of the ON position of the switching handle 60 stands the jack 91 before to handle 60 between the lead 92 lock, which prevents the switch handle 60 inadvertently moved to the OFF position.

The polarity plates 10 and the spacers 20 are with side plates 80 covered to have productivity on sidewalls. Between the top cover 30 and the polarity plates 10 is a non-magnetic seal 35 inserted.

The preferred embodiments of the oxidation protection device 70 and the rotor 50 are described in detail below.

Regarding 2 are two spacers 20 between three polarity plates 10 inserted, and a cavity S between the spacers 20 and the polarity plates 10 is with the colloidal fluid 71 as an oxidation protection device 70 filled.

An end to the wave 61 penetrates through the axial opening 52 in the middle of the rotor 50 and the axial opening 13 the polarity plate 10 one to in the middle of the polarity plate 10 to be supported and the other end of the wave 61 protrudes to the outside with the shift handle 60 to be connected. Depending on the position of the switching handle 60 the magnetic lifting device is magnetized on or off.

3A and 3B are cross-sectional views of 2 , The cavity S in the vicinity of the rotor 50 is with the oxidation protection device 70 , especially with the colloid fluid 71 , filled to the neodymium magnet 40 to block the atmosphere from contact with oxygen.

In 3B is a plurality of protrusions 55 on the rotor 50 formed at a predetermined distance. Opposing bolts are with the spacers 20 engaged.

With respect to the 5 and 6 is that between the polarity plates 10 and the spacers 20 formed cavity S with the as an oxidation protection device 70 serving colloidal fluid 71 filled. A groove is preferred 73 on the non-magnetic medium 71 formed where the neodymium magnet 40 revolves around that as the antioxidant 70 serving colloidal fluid 71 fill in so that the neodymium magnet 40 with the rotor 50 turns to constant contact with the colloid fluid 71 on the surface of the neodymium magnet 40 keep upright.

Although the neodymium magnet 40 repeated using the switching handle 60 is rotated is the surface of the neodymium magnet 40 in contact with the colloidal fluid at all times 71 , which increases the performance and life of the neodymium magnet 40 are improved.

7 Figure 4 is a cross-sectional view of another embodiment of the magnetic elevator of the invention, with the rotor interface 50 and the opposite liquid intake openings 72 with the oxidation protection material, such as. B. the colloidal fluid are filled. The surface of the neodymium magnets 40 in the rotor 50 is in constant contact with the surface area of the polarity plates in this embodiment 10 when rotating the rotor 50 ,

8A . 8B and 8C are perspective views, the modifications of the liquid receiving openings 72 show that in the interface of the neodymium magnet 40 in the rotor 50 are formed to act as an antioxidant 70 to serve. The liquid intake openings 72 in the interface of the neodymium magnets 40 are with the colloidal fluid 71 than the oxidation protection device 70 filled to the contact of the neodymium magnet 40 with oxygen in the atmosphere, thereby preventing oxidation. Especially during the rotation of the rotor 50 and the neodymium magnet held in it 40 is in the liquid intake openings 72 filled colloid fluid 71 constant to the openings between the neodymium magnet 40 and the polarity plate 10 supplied to have a higher oxidation protection effect.

9 and 10 are enlarged partial views of the liquid intake openings 72 , taken at the interface of the in the rotor 50 held neodymium magnets 40 ; 9 shows the along the neodymium magnet 40 provided liquid intake openings 72 , and 10 shows the along the rotor 50 provided liquid intake openings 72 , In any case, the colloidal fluid fills 71 the liquid intake openings 72 to the anti-oxidation effect of the anti-oxidation device 70 to have.

11 and 12 show another embodiment of the rotor 50 and the neodymium magnet 40 without a hook on the top cover, the two-part neodymium magnet 40 a rotor 50 forms in a bar. The rotor 50 that is suitable for a chuck that is used to fix the objects on the table is shown in the drawings as an example. The rotor 50 is rotatable in a rod shape between the opposite polarity plates 10 assembled so that a cavity between the polarity plates 10 and spacers 20 is formed.

Between the neodymium magnets 40 and the polarity plates 10 is the fluid intake gap 74 formed the rotation of the rotor 50 by absorbing the colloidal liquid in the cavity S and the surface of the neodymium magnet 40 to coat.

The cap 21 is in the upper space between the polarity plates 10 arranged with the help of bolts so that they the rotor 50 surrounds. The pouring hole 22 is on the cap 21 formed, and at the pouring hole 22 is one by a feather 23 elastically supported ball 24 arranged to close an opening. In the event that the oxygen blocking material, e.g. B. the colloidal fluid, with higher pressure than the elastic spring 23 is poured in, the oxygen blocking material around the rotor 50 and the neodymium magnet 40 filled around. This replenishment is preferably often done when needed.

Because the magnetic flux density of the neodymium magnet 40 is larger than the ferrite magnet, in order to have a high magnetic attraction and repulsion, the rotation of the switching handle should 60 be locked. The ON state of the switching handle 60 causes repulsion and the OFF state of the switching handle 60 causes attraction. The switching handle 60 can inadvertently rotate, and the handle lock 90 is intended for this case.

It is preferred that the oxygen protection device 70 can be formed so that the cavity 70 is evacuated to prevent the neodymium magnet 40 Is exposed to oxygen.

It is further preferred that the cavity S with the colloid liquid serving as an antioxidant 71 , such as B. fat can be filled.

In the event that the colloidal fluid 71 in the liquid intake openings 72 is filled in along the in the rotor 50 held neodymium magnets 40 are provided, the oxidation protection effect is improved.

As described above, prevented the present invention that the neodymium magnet is oxidized, to improve magnetic performance and durability.

Furthermore, the improved minimized Magnetic lifting device of the invention Guaranteed size and weight of a body easy operation and improves performance and productivity.

Claims (10)

A magnetic lifter using a neodymium magnet, comprising: a plurality of polarity plates ( 10 ), which are arranged at a predetermined distance and a non-magnetic medium ( 11 ) have in the middle; a plurality of spacers ( 20 ) between the polarity plates ( 10 ) are arranged; a top cover ( 30 ), the spacer elements ( 20 ) and the polarity plates ( 10 ) with a hook ( 31 ) on the top; a plurality of opposing neodymium magnets ( 40 ) with S / N polarity between the polarity plates ( 10 ) are arranged; a plurality of rotors ( 50 ) with the neodymium magnets inserted ( 40 ) rotate; a switching handle ( 60 ) for switching the polarity position of the rotor ( 50 ) and the engaged neodymium magnet ( 40 ) to turn the magnetic attraction on and off; and one around the neodymium magnet ( 40 ) arranged around oxidation protection device ( 70 ) to prevent the neodymium magnet ( 40 ) comes into contact with oxygen. Magnetic lifting device using a neodymium magnet according to claim 1, wherein the oxidation protection device ( 70 ) is designed such that a cavity (S) in the vicinity of the neodymium magnet ( 40 ) is kept in a vacuum. Magnetic lifting device using a neodymium magnet according to claim 1, wherein the oxidation protection device ( 70 ) is designed such that the cavity (S) in the vicinity of the rotor ( 50 ) is filled with oxidation protection material in a liquid state. Magnetic lifting device using a neodymium magnet according to claim 1, wherein the oxidation protection device ( 70 ) is designed such that liquid intake openings ( 72 ) on the border to the neodymium magnet ( 40 ) in the rotor ( 50 ) are formed and the liquid intake openings ( 72 ) are filled with the oxidation protection material in a liquid state. Magnetic lifting device using a neodymium magnet according to claim 1, wherein the oxidation protection device ( 70 ) is designed such that a groove ( 73 ) on the non-magnetic medium ( 11 ) up to the rotational position of the neodymium magnet ( 40 ) is arranged and filled with the oxidation protection material in a liquid state. A magnetic lifter using a neodymium magnet according to claim 1, wherein a cap ( 21 ) on the open upper part of the spacer elements ( 20 ) is arranged by means of bolts so that it connects the rotor ( 50 ) surrounds. Magnetic lifting device using a neodymium magnet according to claim 1, wherein the rotor ( 50 ), a non-magnetic synthetic resin material, a magnetic receiving opening ( 51 ) around one or two pairs of neodymium magnets ( 40 ) to be arranged opposite one another, and an axial opening ( 52 ) in the middle of the rotor ( 50 ) is formed around a shaft ( 61 ) with the end of which a switching handle ( 60 ) and connected in an axial opening ( 12 ) of the polarizing plate ( 10 ) for an intervention. Magnetic lifting device using a neodymium magnet according to claim 1, wherein the rotor ( 50 ) in a rod shape between the polarity plates ( 10 ) for rotation is arranged so that a cavity (S) between the polarity plates ( 10 ) and the spacers ( 20 ) is formed and a liquid absorption space ( 74 ) between the neodymium magnets ( 40 ) and the polarity plates ( 10 ) is formed. Magnetic lifting device using a neodymium magnet according to one of the claims 3 to 5, wherein the antioxidant material is in a liquid state Grease, lubricating oil or colloidal fluid includes. A magnetic lifter using a neodymium magnet according to claim 6, wherein a pouring hole ( 22 ) on the cap ( 21 ) is formed such that one of a spring ( 23 ) elastically supported ball ( 24 ) is installed around the opening from the bottom of the pouring hole ( 22 ) thereby close, whereby the oxygen protection material with higher pressure than the elastic spring ( 23 ) is poured in around the rotor ( 50 ) and the neodymium magnet ( 45 ) to fill.