DE2818898C2 - Magnetic switch - Google Patents

Description

The invention relates to a magnetic switch according to the preamble of the main claim.

Such a magnetic switch is known from DE-OS 63 660. If in the case of this magnetic switch the overcurrent protection has responded, then the one serving as the actuating element remains outside the Housing arranged magnetic part in the switched-on position, so that it cannot be seen here whether the switching contacts are open or closed.

The present invention is therefore based on the object of the magnetic switch of the aforementioned To improve genus with regard to its operational safety that it is ensured that the Actuator serving magnetic part is only in its on position when the Magnetic switch is actually switched on

To solve this problem, the features listed in the characterizing part of the main claim are provided.

In the case of the present invention, that which serves as an actuator is outside the housing arranged magnetic part in the switched-on state of the magnetic switch locked as soon as, however the overcurrent or short-circuit protection responds, the actuating element is activated via the further magnetic device unlocked and the actuator tilts into its rest position, so that it can also be seen from the outside is that the switch is off

The following is a way of carrying out the claimed invention with reference to drawings, soft partially exemplary embodiments show explained in more detail. It shows

F i g. 1 is a vertical sectional view of an automatic magnetic switch according to the present invention;

F i g. Fig. 2 is a perspective view of a generally known manual switch in use of permanent magnets, with part of the housing cut open,

F i g. 3 is a vertical sectional view of a switch along the line AA ' of FIG. 2, showing the closed state of the contacts,

F i g. 4 shows a sectional view along the line BB ' in FIG. 3, which shows magnetic metal blocks in their arrangement in a cover of the switch housing,

Fig. 5 is a vertical sectional view of a substantially known switch with a horizontal sliding contact,

6 shows a sectional view along the line DD ' of FIG. 5,

F i g. 7 is a sectional view of the switch of FIG. 5, which shows this in the closed state of the horizontal shows sliding contacts

8 shows a perspective view of the overload and short-circuit protection device known per se of the switch according to FIG. 1,

9 is a perspective view of the electromagnetic Control device in an automatic magnetic switch according to the present invention,

F i g. 10 is a vertical sectional view of the automatic magnetic switch of FIG. 1 showing the Main circuit in the switched-off state shows

F i g. 11 is a vertical sectional view of another Embodiment of an automatic magnetic switch using a coil for indirect control of the magnet and

F i g. Fig. 12 is a vertical sectional view of another embodiment of an automatic magnetic switch using a magnetically operated switch as shown in FIG. 5 is illustrated.

In Fig. 1 is a vertical sectional view of an automatic magnetic switch according to the present invention Invention shown. The automatic magnetic switch 1 includes a housing 2 and a cover 3, which is attached to the Housing 2 is fastened with screws 4. The switch housing 2 essentially contains two Adjacent chambers 5 and 6 for installing an overcurrent and short-circuit fuse 7 and one magnetically operated switch (manual magnetic switch 8). A housing 9 is integral with the Cover 3 is attached and forms a housing for the installation of a magnetic control device 10.

The manual magnetic switch 8 consists mainly of a conductive fixed contact carrier 11 with a contact A movable contact carrier 12, which is generally rigid and inflexible. and has a contact mounted thereon, is pivotably or slidably mounted inside the housing 2. A magnetic part 13, for example a permanent magnet, is attached to the movable contact carrier 12 in order to press the latter into a position in engagement with the contact when an outer magnetic part 14 is brought close to the housing 2. The manual magnetic switch 8 is detailed in various embodiments with reference to the V i g. 2 - 6.

In the F i g. 2 and 3 are a perspective view and a sectional view of a manual magnetic switch shown, which has a housing 15 made of an insulating and non-magnetic material, for example Contains wood, plastic, etc. The housing 15 has two protruding flanges 16 of a number of holes 17 to fasten the switch to a surface by means of screws. Contact surfaces 18 and 19 are integrally formed on a base plate 20 of the housing 15 and on the side walls 21 The bearing surfaces 18, 19 have a large number of recesses 22 for receiving electrically conductive ones Contact carrier 23 or a Z-shaped electrically conductive contact carrier 24, the contact carrier are attached to the support surfaces 18 and 19 by means of screws 25. On the flanges 16 are a number provided by recesses 26, which the clamping plates 27 record the electrically conductive contact carrier 23 or the Z-shaped contact carrier 24 are connected, the fastening being done with screws 28. The construction of the contact carrier 23 and the Z-shaped contact carrier 24 is for single-phase current or for three-phase high-voltage current suitable.

The Z-shaped contact carriers 24 are made of rigid conductive metals, contacts 29 being made from Platinum or alloys are formed as fixed contacts on it. When the contact carrier 23 is off flexible conductive metals are made, platinum contacts are at their ends as movable contacts 30 educated. In addition, there is a block 31 made of an insulating and non-magnetic material is mounted on the contact carrier 23 by means of screws 32, with a magnet 33 on the block 31 is mounted. The block 31 is made relatively thick in its dimensions, so that the flow in the Contact carrier 23 induced magnetic field does not interfere with the field of magnet 33.

The switch housing 15 also contains a cover 34, which by means of screws 35 on the side walls 21 of the housing is an actuatable device in the form of a -shaped frame structure 36 is pivotable in a hinge-like manner on the cover 34 by means of a hinge 37 at the ends of Holders 38 attached by pins 39. The -shaped frame structure 36 also includes a cross member 40 with a permanent magnet 41 which is contained in its hollow part. The permanent magnet 41 can be arranged above the magnet 33 in such a way that it is removed from it or is close when the -shaped frame structure 36 is pivoted about the pins 39.

As in Fig. 3 is shown when the permanent magnet 41 is arranged near the magnet 33, an attractive force cause the latter upwards is moved and the contact 30 is moved into a closed position with the stationary contact 29 and thus On the other hand, when the permanent magnet 41 is moved away from the magnet 33, the circuit closes becomes, the elastic restoring force of the contact carrier 23 becomes the attractive force of the magnets Overcome, so that the contact carrier 23 is moved down into the disengaged Siellung and

in the circuit between contact 30 and the fixed contact 29 is interrupted. It is not strictly necessary to do the above -shaped frame construction to use. Further

the chamber in the housing 15 is preferably hermetically sealed and filled with an inert gas or Insulation oil is filled or a vacuum is maintained in order to minimize arcing, which generated during switching.

The Fig.4, which is a sectional view along the line

2 " B-B '" in FIG and hence the attraction force, to increase The path of the magnetic flux is illustrated by an arrow and a dashed line.

In the F i g. 5,6 and 7 is a vertical sectional view another magnetically operated switch is shown.

in one on a bearing 65 by means of a pin 66 pivotably mounted lever 64 has a fork arm 67, which for cooperation with a slider 68 of a horizontally aligned sliding contact 69 is formed. The sliding contact 69 is also pretensioned by means of a spring 70 and can according to the force of attraction between the Magnets 71 and 72 are moved to the right or left via the lever mechanism. The closed one The state of the horizontal sliding contact with the fixed contact 73 is shown in FIG. 12 illustrates. In Fig. 8 the overcurrent or short-circuit fuse 7, which is installed in the chamber 5 of the housing 2 shown in Fig. 1, illustrates. This device 7 is of conventional design and contains a current-carrying plate 74, a bi-metal 75 and a short-circuit protection electromagnet 76.

Referring to Figure 8 in conjunction with 1 it can be seen that the conductive plate 74 can be fixed to the housing 2 by means of screws. That Bi-metal 75 will bend to a certain extent if the circuit has an overcurrent and the current-carrying plate 74 increases in temperature. If two phases of the three-phase krait current one Have short circuit, the large change in current in the current-carrying plate 74 generates an induced, magnetic flux in the electromagnet 76, which thus the movable portion 77 of the electromagnet 76 pulls down.

9 is a perspective view of the magnetic control device 10 according to the present invention Invention shown. The magnetic control device 10 includes a T-shaped lever 78, which is pivotably mounted on a bearing which extends from the side wall, with a first magnet 79 on one end of the cross arm 80 of the lever 79 is mounted. In the add-on housing 9, a support 81 goes from Cover 3 is off and a control lever 82 can be pivoted on the support 81 by means of a pin 83. Of the

Control lever has a lower cross arm 84 with a second magnet 85 mounted thereon. Furthermore, the control lever 82 has a coupling arm 86 with a first locking bar 87 articulated thereon by means of a pin 88 and a second locking bar 89 which is slidably mounted on the adjacent end by means of a bolt 90. A spring 91 is clamped between the coupling arm 86 and the housing cover 3. The second locking bar 89 has a vertical slot 92 engaging in the bolt 90 and a pair of ear-shaped projections 93 which serve as a stop for the spring 94 which, in the normal state, brings the bolt 90 to bear against the lower end of the vertical slot 92. The first locking bar 87 and the second locking bar 89 both have an inclined surface at the upper end and protrude through the wall 95. The add-on housing 9 contains slots 96 and 97 for receiving a control rod 98 which has a first recess 99 serving as a stop and a second recess 100 serving as a stop. The control rod 98 is connected to the outer magnetic part 14, which is screwed onto a non-magnetic plate 101 , a spring 102 connecting the plate to the add-on housing 9. The magnetic control device 10 also has a manual shut-off device 103 which contains a spherical switch button 104, a forked body section 105 and a push plate 106 which is arranged between the wall 95 and the ear-shaped projections 93 of the second locking bar 89.

The operation of the automatic magnetic switch according to the present invention will now be described with reference to Figs. When the circuit is normal, the outer magnetic part 14 attracts the magnetic part 13 and thereby closes the contacts on the current-carrying contact carriers 11 and 12. The second locking bar 89 engages like a bolt in the second stop of the control rod 98 , which is designed as a recess 100, as shown in FIGS. 1 and 9 is illustrated. Should an overload or short circuit occur in the circuit, the bi-metal 75 or the protective electromagnets work and the T-shaped lever 78 begins to rotate, whereby the first magnet 79 attracts the second magnet 85. Since the second magnet 85 is attracted by the first magnet 79 of the T-shaped lever 78, the control lever 82 begins to rotate clockwise so that the coupling arm 86 drives the second locking bar 89 downwards and out of the second, as a recess 100 The control rod 98 now moves to the right due to the restoring force of the spring 102 and pulls the outer magnetic part 14 away from the cover 3. The control rod 98 finally reaches a position where it is locked by the first locking bar 87 and the magnetic part 13 falls down in order to switch off the contacts of the current-carrying contact carriers II and 12, as shown in FIG.

It should be emphasized that the restoring force of the spring 102 must be greater than the magnetic attraction force between the magnetic parts 13 and 14. The magnetic attraction force between the first magnet 79 and the second magnet 85 must be greater than that

ίο restoring force of the spring 91. After the circuit is automatically switched off, however, the first and second magnets 79 and 85 remain attracted and the first locking bar 87 remains locked in the first stop recess 99 of the sleu rod 98. The outer magnetic part 14 cannot return to its original state unless the lower cross arm 84 of the control lever 82 is lifted by hand so that the first locking bar 87 can slide out of the first recess 99 of the control rod 98. Thus, the lower cross arm 84 serves as a protective device for the automatic switch. On the other hand, the manually operated disconnection device 103 can be pushed down using the switch button 104 in order to manually disconnect the circuit in the event of an emergency or other alarm conditions.

A screw 116 is provided in the side wall of the add-on housing 9 in order to adjust the position of the lower transverse arm 84. The sensitivity of the automatic magnetic switch can be adjusted by adjusting the screw 116. The further down the cross arm 84 is, the higher the sensitivity of the switch.

In Fig. 11 there is shown another embodiment of the automatic magnetic switch according to the present invention. The construction of the switch according to FIG. U uses a coil 112 to drive the outer magnetic part 113 indirectly. If the circuit is under overload or short circuit, the current of the coil 112 is switched off, the magnet 113 then rotates away from the cover about an axis 114 due to the restoring force of a spring 115 . Again, the rod 110 and the second magnet U1 serve as a protective device for the automatic magnetic switch. This embodiment of the switch has particular advantages, since a low-energy coil is sufficient to switch a power circuit.

The switch can be designed according to FIG. 12 which the magnetically operated switch according to FIG. 5 used

It should also be noted that the one shown in FIG. 4 illustrated bypass solenoid 42 in the Lid between the first magnet 79 and the second magnet 85 or the outer magnet 14 and the magnet 13 can be used to concentrate the magnetic flux and thereby the between to reinforce this prevailing attraction.

For this purpose 4 sheets of drawings

Claims (3)

Patent claims: 1. Magnetic switch with an airtight housing, at least two in the housing leading electrical lines, each with one, each carrying a contact, electrically-conduct the contact carriers are connected, which are housed in a first chamber of the housing, one of the conductive contact carriers being movable via magnetic devices, the Magnetic devices consisting of a magnetic part connected to the movable contact carrier and a second movable magnetic disposed outside of the airtight housing Part consists, the distance between the two magnetic parts for actuating the magnetic switch can be changed, and with an overcurrent switch that can be actuated via another magnetic device or short-circuit protection, which opens the switching contacts in the event of an overcurrent and which in a second Chamber of the housing is housed, g e k e η η records by a locking device (locking strips 87, 89, control rod 98), the Can be unlocked via a control lever (82) through the further magnetic device (magnets 79, 85), wherein the outside of the housing arranged magnetic part (14) in its the magnetic switch switched on holding position is held locked by the locking device when the another magnet device (magnets 79, 85) is in its rest position. 2. Magnetic switch according to claim 1, characterized in that the locking device includes: a first and a second locking bar (87 and 89) attached to a Coupling arm (86) of the control lever (82) are pivotably mounted, one with the first, outside the Housing located magnetic part (14) connected control rod (98), the zivei in the distance located recesses (99, 100), one of which each with one of the locking strips (87.89) is engaged. 3. Magnetic switch according to claims 1 or 2, characterized in that the further magnetic device has magnets (79, 85) separated from one another by a wall (cover 3), the Distance of one magnet (85) to the wall (cover 3) by means of a screw (116) is adjustable.