DE102007035195B4 - Switchable magnetic holding system - Google Patents

Abstract

Switchable magnetic holding system which has at least one pole shoe pair (10, 20) in which at least one primary permanent magnet (1, 2) is arranged such that it cannot move, such that the pole shoe pair (10, 20) have primary polarity (N, S), and wherein the holding system has a part (40) which can be moved at right angles to the greatest magnetic flux density with respect to the pole shoe pair (10, 20), wherein at least two secondary permanent magnets (3, 4, 5) are arranged on the movable part (40), wherein the secondary permanent magnets (3, 4, 5) are arranged with their magnetic polarity (N, S) in opposite senses, and the moveable part (40) can be moved translationally at least between two definable positions with respect to the pole shoe pair (10, 20), wherein, in a first position, the pole shoe pair (10, 20) is magnetically activated by a pronounced formation of the magnetic north pole and south pole (N, S), and, in a second position, the pole shoe pair (10, 20) are magnetically deactivated by a magnetic short circuit, as well as a closing system having a switchable permanent-magnet holding system.

Description

The The invention relates to a switchable magnetic holding system, which at least one pair of pole pieces, in which at least one primary permanent magnet is immovably arranged, so that the pole shoe pair has a primary polarity and wherein the holding system is a perpendicular to the pair of pole pieces to the largest magnetic flux density having movable part, wherein on the movable part at least two secondary Permanent magnets are arranged.

Such a switchable magnetic holding system is known from the DE 30 40 582 A1 ,

Of Furthermore, the invention relates to a locking system for translationally movable and openable Components having a ferromagnetic contact part, in particular Sliding doors, sliding windows and the same.

Such holding systems, which have magnetic, in particular electromagnetic holding systems, are known. The shutdown when using permanent magnets and mechanical components is known. Magnets or pole shoes are displaced or rotated relative to each other, the Krafffeldabschaltung permanent magnetic arrangements is very expensive. For example, opposing fields are built or otherwise deflected the magnetic flux in the system so that on the surfaces and outside of the system, the force fields can be changed or even switched off. Such an arrangement is known from DE 26 47 503 A1 known. Solutions are known in which the magnetic flux of the magnet is closed, wherein no force field is generated to the outside. This is called a magnetic short circuit.

Known are also locking systems with positive locking Locking. The disadvantage here is that either play in the axial direction, this means in the sliding direction, must remain, against an elastic element must be pushed with a very high effort or one elaborate Zuspannmechanik must be installed. For electromagnetic locking systems is the appropriate electrical supply and circuit technology required, which is associated with considerable effort.

adversely in the known solutions is that apply for switching on and off partly considerable operating forces are and a considerable space is needed.

task The invention is to overcome the disadvantages described and a switchable magnetic holding system or a locking system for translational movable and openable Components, being the locking system a switchable magnetic holding system, to train such that when using low operating forces and easy operation a reliable holding system respectively locking system is created, which works reliably even in tight spaces and sufficient holding forces provides.

These The object is achieved by a Holding system according to claim 1 or through a locking system according to claim 4 solved.

Especially It is advantageous that in the switchable magnetic holding system the secondary ones Permanent magnets arranged in opposite directions with respect to their magnetic polarity are and the movable part relative to the pole piece at least is translationally movable between two definable positions, wherein in a first position the polarity of the primary permanent magnet and at least one in this position in the region of the pole shoe pair located second permanent magnet are identical, so that the Pole pair magnetically activated by a pronounced training from magnetic north and south poles on the pole shoe pair, and that in a second position, the polarity of the primary Permanent magnets and at least one in this position in the range of Polschuhpaares located second permanent magnet are in opposite directions, so that by a magnetic short circuit, the pole piece pair magnetic is disabled.

hereby It is due to a simple translational movement of the moving Part opposite the pole shoe pair possible, the magnetic switchable holding device between a maximum at magnetic flux density and accordingly at a maximum Holding force and a magnetic short circuit, in which the after Outside acting magnetic holding force is equal to zero, to switch or via different Intermediate positions of the translationally movable part different holding forces between zero and the maximum.

The pole shoe pair guides the magnetic flux. One pole piece acts as a north pole in the activated state and the other pole shoe as a south pole. In this state, that is to say with magnetic activation, the pole shoes attract a ferromagnetic counterpart. The ferromagnetic counterpart is the counter-holder, wherein the system of pole pieces and counter-holder reliably locking a translationally movable and disclosed component such as a sliding door, a sliding window or the like causes and thus a reliable closing system with a schaltba ren magnetic holding system is realized. The system of pole shoes and counter-holder can be arranged on all relative to each other relatively movable components. For example, the counter-holder can either be attached to the closure wings and the pole shoes can be seated in the frame with magnets in a stationary manner. However, it is also possible the kinematic reversal with fixed counter-holder and movable Polschuhmagnetverbund, which is equally feasible as well as the relative movement of the two parts to each other and simultaneous relative movement to a stationary frame, for example, in a double door with two mutually displaceable wing parts. In such double-wing arrangements, the anvil may be placed on one wing and the pole shoes with magnets on the other wing.

The highest Attraction is realized when a touch between pole pieces and ferromagnetic counterpart consists. With a high surface quality as well An exact adherence to the geometry can be a high magnetic Efficiency, that is a high magnetic holding power can be achieved.

By Generation of a magnetic short circuit is the shutdown of the Force field possible, by correspondingly redirecting the magnetic flux in the pole shoes becomes. This is achieved, for example, when magnets in a suitable Way shifted against each other, so that north and south poles with in the sum of the same magnetic flux in opposite directions in one Add pole shoe pair.

Spatially adjacent can several pairs of pole pieces, each with its own magnets are assigned, be attached. It has been shown that an adjacent Wechselpolarität the force effect on the ferromagnetic counterpart optimized. Preferably, a higher Number of pole pairs instead of a single pair Use find to increase the holding power.

For example can with sliding doors and sliding the leaf or the wing a smaller thickness over the Height, so that a narrow area arises in which the shutter is arranged must become. Here can Polschuhpaare in an advantageous manner arrange in a vertical row.

advantageous Further developments of the holding system and the locking system are specified in the subclaims.

embodiments The invention are illustrated in the figures and will be explained in more detail below. It demonstrate:

1 - An embodiment of the holding system in the on state in two views

2 - The embodiment according to 1 in off state in two views

3 - A side view of an embodiment of the locking system

4 - Three variants a, b and c possible arrangements of magnetic holding systems of a locking system

5 - Three variants A, B and C of a locking system in a cross section.

1 shows an embodiment of the holding system in the on state in two views, wherein the registered polarity N-S on the in the pole pieces 10 . 20 lying magnets 1 . 2 . 3 . 4 refers.

2 shows the embodiment according to 1 in the off state, wherein the registered polarity N-S on the in the pole pieces 10 . 20 lying magnets 1 . 2 and 5 wherein, in the in 2 state shown a magnetic short in the pole pieces 10 and 20 is generated.

The embodiments are shown in two views. An activated version after 1 shows the pole shoes 10 and 20 with the magnets 1 . 2 . 3 . 4 . 5 , In the side view of 1 It can be seen that all poles of the same name N, S of the adjacent magnets 1 . 2 . 3 . 4 each on a pole piece 10 and the others on the other pole shoe 20 issue. A first pole piece 10 is north polarized in this circuit and the second pole piece 20 is south polarized, that is the pair of pole pieces 10 . 20 is magnetically activated by a pronounced north pole through a first pole piece 10 and a pronounced south pole through the second pole piece 20 is trained. Thus, a ferromagnetic object becomes 30 in the in 1 tightened circuit shown.

The switched-off variant, by moving the bar 40 , that is, by the translational movement of the moving part 40 opposite the pole shoe pair 10 . 20 the magnets 3 and 4 from the field of pole shoes 10 . 20 were moved out and magnet 5 between the pole shoes 10 . 20 was placed shows 2 , The magnetic flux of the secondary magnet 5 is equal to the sum of the magnetic fluxes of the primary magnets 1 . 2 , In the side view can be seen that now on the first pole piece 10 both north pole N of the primary magnets 1 . 2 , as well as the South Pole S of the sec dary magnets 5 abutment and the second pole piece 20 the south poles S of the primary magnets 1 . 2 as well as the north pole N of the secondary magnet 5 issue. The magnets 1 and 2 form the primary magnets, the ones on the moving part 40 arranged magnets 3 . 4 . 5 forming the secondary magnets. In the circuit according to 2 is a magnetic short circuit within the pole shoe pair 10 . 20 evoked, indicated by the closed field lines 50 in the side view according to 2 ,

The flux densities of the sum of north and south poles are equivalent as in this embodiment, so that a magnetic short circuit according to 2 in the pole shoes 10 . 20 , indicated by the closed field lines 50 , is formed so that the ferromagnetic object 30 according to the circuit 2 not being dressed anymore. That in the 1 and 2 illustrated embodiment of the magnetic holding system is thus switchable between a maximum attraction (circuit according to 1 - magnetically activated) or zero (circuit according to 2 - magnetically deactivated).

In the switching position according to 2 becomes the ferromagnetic object 30 thus not dressed anymore.

3 shows the side view of an embodiment of a locking system, which is arranged as a sliding closure system with permanent magnetic tumbler. The system is shown in partially open position of the wing 200. , To recognize the framing 100 and the translationally movable wings 200. , which is a passive ferromagnetic backstop 300 wearing. Shown in section are the holding systems 410 . 420 . 430 an active magnetic locking unit 400 ,

4 shows in the 4a . 4b and 4c three different variants of the arrangement of Polschuhpaaren. The start bar 500 carries the active magnetic locking unit 400 with the pole shoe pairs according to the figures a and b or the pole strip according to 4c ,

5 shows three variants a, b and c of the combination of tumbler and positive shear force absorption in a sectional view with the wing stopped. You can see the start bar 500 , the passive ferromagnetic backstop 300 , the wing 200. as well as the active magnetic locking unit 400 , Overlaps or groove spring equivalents 600 . 610 and bolts 700 as well as bolt receiving bore 710 , which form a lateral overlap, so that a transverse force absorption is realized by a positive connection.

The framing 100 of the door leaf 200. includes as shown by 1 on the right side in the vertical the locking unit 400 , Will the door 200. to the right to the frame 100 pushed, creates a contact between counterpart 300 of the grand piano 200. and the locking unit 400 , If the locking unit is activated in a suitable manner, pull the pole shoes 410 the counterpart 300 on the door 200. is attached, on, causing the door 200. is closed.

The different variants of the locking unit 400 or the switchable unit 400 shows 4 with differently arranged magnetic holding systems 410 . 420 . 430 , About the change of polarity of the pole shoes or pole strips, which are in magnetically insulating material 440 , such as brass, can be placed on the ferromagnetic backstop 300 to exert an attraction.

Transverse forces acting on the door 200. be exercised, takes the positive overlap of the counter-holder 300 and frame 100 according to the variants 5 on. It can either be the frame 100 the wing 200. or the counterholder 300 according to 3a overlap or the door leaf 200. the frame 100 according to 3b overlap laterally. Another variant is in 3c shown. It forms a shear bolt 700 a positive connection by putting in a hole 710 retracts.

Claims (21)

Switchable magnetic holding system, which has at least one pole shoe pair ( 10 . 20 ), wherein at least one primary permanent magnet ( 1 . 2 ) is immovable, so that the pole shoe pair ( 10 . 20 ) has a primary polarity (N, S), and wherein the holding system has a relative to the pole shoe pair ( 10 . 20 ) perpendicular to the largest magnetic flux density movable part ( 40 ), wherein on the movable part ( 40 ) at least two secondary permanent magnets ( 3 . 4 . 5 ) are arranged, characterized in that the secondary permanent magnets ( 3 . 4 . 5 ) are arranged in opposite directions in terms of their magnetic polarity (N, S) and the movable part ( 40 ) opposite the pole shoe pair ( 10 . 20 ) is translationally movable at least between two definable positions, wherein in a first position, the polarity (N, S) of the primary permanent magnet ( 1 . 2 ) and at least one in this position in the region of the pole shoe pair ( 10 . 20 ) located second permanent magnet ( 3 . 4 ) are identical, so that the pole shoe pair ( 10 . 20 ) is magnetically activated by a pronounced formation of magnetic north and south pole (N, S), and in a second position, the polarity (N, S) of the primary permanent magnet ( 1 . 2 ) and at least one in this position in the region of the pole shoe pair ( 10 . 20 ) located second Permanent magnets ( 5 ) are in opposite directions, so that by a magnetic short circuit, the pole shoe pair ( 10 . 20 ) is magnetically deactivated, wherein a second pair of pole pieces ( 10 . 20 ) adjacent to the first pair of pole pieces ( 10 . 20 ), wherein the primary permanent magnet ( 1 . 2 ) of the second pair of pole pieces ( 10 . 20 ) relative to the primary permanent magnet ( 1 . 2 ) of the first pair of pole pieces ( 10 . 20 ) is arranged in opposite polarization and wherein the movable part ( 40 ) along both pairs of pole pieces ( 10 . 20 ) is arranged so movable that the secondary magnets ( 3 . 4 . 5 ) are positionable such that both pairs of pole pieces ( 10 . 20 ) are magnetically activated or one of two pole shoe pairs ( 10 . 20 ) is magnetically activated or that both pairs of pole pieces ( 10 . 20 ) are magnetically deactivated. Holding system according to claim 1, characterized in that a plurality of pole shoe pairs ( 10 . 20 ) each having at least one primary permanent magnet ( 1 . 2 ) are arranged. Holding system according to one of the preceding claims, characterized in that each pair of pole pieces ( 10 . 20 ) a plurality of primary permanent magnets ( 1 . 2 ) and / or each movable part ( 40 ) a plurality of secondary permanent magnets ( 3 . 4 . 5 ), in particular in each case different arrangement with respect to the polarity (N, S). Locking system for translationally movable and openable components which has a ferromagnetic contact part ( 300 ), in particular sliding doors ( 200. ), Sliding windows u. Like., characterized in that the locking system is a switchable permanent magnetic holding system ( 410 . 420 . 430 ), in particular a holding system according to one of the preceding claims, wherein the holding system ( 410 . 420 . 430 ) at least one pole shoe pair ( 10 . 20 ), wherein at least one primary permanent magnet ( 1 . 2 ) is immovable, so that the pole shoe pair ( 10 . 20 ) has a primary polarity (N, S), and wherein the holding system has a relative to the pole shoe pair ( 10 . 20 ) perpendicular to the largest magnetic flux density movable part ( 40 ), wherein on the movable part ( 40 ) at least two secondary permanent magnets ( 3 . 4 . 5 ) are arranged, wherein the secondary permanent magnets ( 3 . 4 . 5 ) are arranged in opposite directions in terms of their magnetic polarity (N, S) and the movable part ( 40 ) opposite the pole shoe pair ( 10 . 20 ) is translationally movable at least between two definable positions, wherein in a first position, the polarity (N, S) of the primary permanent magnet ( 1 . 2 ) and at least one in this position in the region of the pole shoe pair ( 10 . 20 ) located second permanent magnet ( 3 . 4 ) are identical, so that the pole shoe pair ( 10 . 20 ) is magnetically activated by a pronounced formation of magnetic north and south pole (N, S), and in a second position, the polarity (N, S) of the primary permanent magnet ( 1 . 2 ) and at least one in this position in the region of the pole shoe pair ( 10 . 20 ) located second permanent magnet ( 5 ) are in opposite directions, so that by a magnetic short circuit, the pole shoe pair ( 10 . 20 ) is magnetically deactivated. Locking system according to claim 4, characterized in that a plurality of pole shoe pairs ( 10 . 20 ) each having at least one primary permanent magnet ( 1 . 2 ) are arranged. Locking system according to one of claims 4 or 5, characterized in that each pair of pole pieces ( 10 . 20 ) a plurality of primary permanent magnets ( 1 . 2 ) and / or each movable part has a plurality of secondary permanent magnets ( 3 . 4 . 5 ) having, Locking system according to claim 6, characterized in that each movable part comprises a plurality of secondary permanent magnets ( 3 . 4 . 5 ) in each case in a different arrangement with respect to the polarity (N, S). Locking system according to one of claims 4 to 7, characterized in that the locking system consists of a plurality of switchable magnetic retaining systems ( 410 . 420 . 430 ) is formed. Locking system according to one of claims 4 to 8, characterized in that the one or more switchable magnetic / n holding system (s) ( 410 . 420 . 430 ) on the fixed frame ( 100 ) of the component are arranged. Locking system according to one of claims 4 to 9, characterized in that the one or more switchable magnetic / n holding system (s) ( 410 . 420 . 430 ) on the moving part ( 200. ) of the component are arranged. locking system according to one of the claims 4 to 10, characterized in that the locking system self-locking when the component is closed. Locking system according to one of Claims 4 to 11, characterized in that the magnetic / holding system (s) ( 410 . 420 . 430 ) is deactivated in the open state of the component is / are. Locking system according to one of Claims 4 to 12, characterized in that the magnetic / holding system (s) ( 410 . 420 . 430 ) are automatically activated in a definable position of the device. Locking system according to one of claims 4 to 13, characterized in that the magnetic / n holding system / s ( 410 . 420 . 430 ) are automatically activated. locking system according to claim 14, characterized in that the activation is electrically and / or electronically and / or mechanically and / or magnetically and / or fluidically and / or mechatronically. locking system according to one of the claims 4 to 15, characterized in that perpendicular to the closing direction a positive connection takes place. Locking system according to claim 16, characterized in that perpendicular to the closing direction a form fit by lateral overlaps by bolts ( 700 ) and / or grooves ( 600 . 610 ) and / or paragraphs. locking system according to one of the claims 4 to 17, characterized in that perpendicular to the closing direction Frictional engagement occurs. Locking system according to one of claims 4 to 18, characterized in that on a double-wing arrangement at least one switchable magnetic holding system ( 410 . 420 . 430 ) is arranged on a first wing and at least one ferromagnetic counterpart ( 300 ) is arranged on the second wing, so that the holding system ( 410 . 420 . 430 ) and its counterpart ( 300 ) can work together. Locking system according to one of claims 4 to 19, characterized in that means for damping and / or deceleration of the openable component ( 200. ) are arranged. locking system according to one of the claims 4 to 17, characterized in that the movable part of the switchable Magnetic holding system can be locked, in particular lockable.