DE19625657A1 - Electric lifting armature magnet - Google Patents

Abstract

The invention relates to an electric rising armature magnet (1, 101) with a magnet coil fitted on a coil body, with a lift armature (7, 107) and a return spring (14) which axially (X) loads the ligt armature (7, 107), where there is a safeguard (3, 103) against an axial shift of the lift armature (7, 107). Here, the safeguard may, for example, make use of a pivoting armature (15, 115).

Description

The invention relates to an electrical lifting magnet according to the Preamble of claim 1.

Electric lifting armature magnets with one arranged on a coil former Solenoid and a stroke slidably arranged in the solenoid Anchors are well known. The stroke is usually shifted anchors to the outside due to the force of a coaxial to the lifting anchor arranged return spring. The movement of the lifting anchor inside the Magnetic coil is made in that the magnetic attraction of the mag net coil on the lifting armature due to the magnet built up by current flow field exceeds the spring force of the return spring.

Such a lifting armature magnet is in particular from DE 40 30 514 C2 known. The lifting armature magnet described in this publication has the arrangement of coil body, solenoid, lifting armature and Return spring on. The lifting armature has a piston at its free end like thickening, the current flow completely from the longitudinal bore in Coil protrudes. Due to a mechanical play between anchor bolts  and magnetic armature enables external influence on the system force directed radially at the anchor bolt against the tilting thereof the magnet armature and the solenoid coil, provided the armature bolt is extended is. As a result of an undercut in the piston-like thickening, the remains Hang the anchor bolt on the edge of the hole in such a way that even with a sub breakage of the current flow to the solenoid of the armature bolt despite the then still existing effect of the return spring in its extended position remains. If the force is released, the anchor bolt is removed by the Restoring force of the return spring is drawn into the inside of the solenoid. This is due to the centering effect of the return spring and a hollow element seal, which is arranged outside the bore.

The disadvantage of such an arrangement is that jamming or self-locking not safely avoided. There is also an external force for the kip Pen of the anchor bolt required.

It is an object of the present invention to provide an electrical lifting armature to create ten, in which these disadvantages are surely avoided. Furthermore should the lifting armature must be vibration-proof, the lifting armature magnet in the extended position Condition should be securely locked.

This task is accomplished with a lifting magnet with the characteristics of Claim 1 solved.

The provision of a fuse increases the security against axial displacement of the lifting anchor due to external forces. Because none in a particular External force required to engage the fuse the system can be used in any way. An undesirable axial movement of the The lifting anchor as a result of external forces is secured, for example  prevented by locking the lifting anchor. A radial movement is the result the guidance of the lifting anchor is not possible.

The timing of the movement of the fuse is particularly advantageous for moving the lifting anchor. This includes a mutual one Disability.

Through one or more recesses provided in the housing, through the weakening of the magnetic flux the above temporal order ver be changed. In particular, this also locks the excitation Condition, i.e. possible with retracted lifting anchor. The electric lifting anchor magnet can therefore be used very flexibly.

It is also advantageous to design the fuse as a hinged anchor. Here the hinged anchor can be formed as part of the housing. This has the Advantage that the hinged armature conducts the magnetic flux well at the same time, which increases the magnetic field accordingly. The on the The force acting on the lifting anchor is thereby increased and the lifting anchor becomes safe held in its retracted position.

A hinged anchor that runs along is particularly insensitive to vibrations pivot an axis that runs parallel to the longitudinal axis of the lifting anchor is cash. Due to the different directions of movement, the safe unit of the locking system increased considerably.

The partial engagement of the folding anchor in an in the lifting anchor is advantageous seen recess. The recess is preferably umlau fende groove. This ensures safe engagement even when the lifting anchor is twisted for sure.

The present invention will now be described in two embodiments games explained with reference to the accompanying drawings. It demonstrate:

Fig. 1 is an electrical lifting armature magnet schematically shown with extended lifting armature and locked,

Fig. 2 shows the lifting armature of FIG. 1 in an unlocked, retracted position,

Fig. 3 shows a second embodiment in the locked position.

Fig. 1 shows an electric Hubankermagneten 1. The lifting armature magnet 1 has a housing 4 with a magnetic coil 5 arranged on a coil former. A lifting armature 7 is arranged in the magnet coil 5 in a recess 8 along its longitudinal axis (X direction). The guide of the lifting armature 7 is carried out on a first side 9 by means of a rod-like set 10 which protrudes through a bore 11 provided in the housing 4 . On the opposite second side 12 , the guide takes place by means of a second bore 13 provided in the housing 4 , through which the lifting armature magnet 1 partially protrudes. On the first side 9 of the lifting armature 7 of the lifting armature 7 is a return spring 14 is provided coaxially with the longitudinal axis, which biases the armature. 7 The return spring 14 is guided through the rod-like extension 10 of the lifting armature 7 , which projects through it.

The lifting magnet 1 also has a fuse 3 in the form of a Klappan core 15 which is pivotally attached to the housing 4 on one side 17 with the aid of a bolt 19 . On the side 21 opposite the side 17 , the hinged anchor 15 is angled by 90 ° and has a bore 23 , the diameter of which is somewhat larger than the diameter of the lifting anchor 7 .

In the vicinity of the angled part, the hinged anchor 15 is supported on the housing 4 by means of a compression spring 25 .

In the extended and locked position of the lifting armature 7 shown in FIG. 1, the extension takes place due to the return spring 14 which partially pushes the lifting armature 7 out of the bore 13 . Locking takes place with the aid of the hinged anchor 15 . For this purpose, the lifting armature 7 has a recess 27 on its second side 12 , which forms a circumferential groove in the exemplary embodiment. Due to the bias of the compression spring 25 of the edge of the provided in the bent part of the hinged armature 15 engages bore 23 in the recess 27 and thereby locks the lifting armature 7 in this extended position.

If the lifting armature magnet 1 is excited as a result of a current flow, the folding armature 15 is first attracted against the force of the compression spring 25 (Y direction) and releases the locking of the lifting armature 7 . Due to the yoke enlarged by the hinged armature 15 , the magnetic field is strengthened. Has a sufficiently large magnetic field built up, the lifting armature 7 is drawn in as a second stage against the bias of the return spring 14 into the recess 8 (X direction). This state is shown in Fig. 2.

According to a second exemplary embodiment, which is shown in FIG. 3, the lifting anchor 107 is locked with the aid of a lock 103 in the form of a folding anchor 115 which is pivoted about an axis which runs parallel to the longitudinal axis of the lifting anchor 107 . The required preload is built up by a compression spring 125 , which is fastened on the outside of the housing 104 between an extension 130 of the hinged anchor 115 and an angle 131 , which is attached to the housing 104 . For locking an arm 132 is provided on the Klappan ker 115 , which engages in the extended state in a running recess 127 of the lifting armature 107 .

With the aid of a recess 35 , 135 in the housing 4 , 104 and a corresponding choice of the return and compression springs 14 , 25 ; 125 and attaching arm 132 to the opposite side of the lifting anchor, the order of moving out and locking can be reversed.

Claims (7)

1. Electrical lifting armature magnet with a solenoid angeord on a coil body, with a displaceably arranged in the solenoid arranged lifting armature and with a return spring that loads the lifting armature in the axial direction, characterized in that a fuse ( 3 , 103 ) against axial displacement of the Lift anchor ( 7 , 107 ) is provided. 2. Electrical lifting magnet according to claim 1, characterized in that the fuse ( 3 , 103 ) is used at different times for the movement of the lifting armature ( 7 , 107 ). 3. Electrical lifting magnet according to claim 2, characterized in that the chronological order of the movements of the lifting armature ( 7 , 107 ) and the fuse ( 3 , 103 ) by at least one in the housing ( 4 , 104 ) provided recess ( 35 , 135 ) and the spring constant of the return spring ( 14 , 114 ) is fixed. 4. Electrical lifting armature magnet according to one of the preceding claims, characterized in that the fuse ( 3 , 103 ) is a hinged armature ( 15 , 115 ). 5. Electrical lifting armature magnet according to claim 4, characterized in that the hinged armature ( 115 ) is pivotable along an axis which runs parallel to the longitudinal axis of the lifting armature ( 107 ). 6. Electrical lifting magnet according to claim 4 or 5, characterized in that the folding armature ( 15 , 115 ) partially engages in a lifting armature ( 7 , 107 ) provided recess ( 27 , 127 ). 7. Electrical lifting armature magnet according to claim 6, characterized in that the recess ( 27 , 127 ) is a circumferential groove.