CH629334A5 - Magnetic switch - Google Patents

Description

The present invention relates to a magnetic switch comprising a housing, a cover fixed to the housing, a protection against overloads and short circuits mounted in a first chamber of the housing, a magnetic contactor mounted in a second chamber of the housing and a magnetic control contained at least in part in a sub-housing which is molded in one piece with the cover.

55 In conventional electrical switches, in particular in power circuits, the contacts are exposed to air, whether of the knife type or of the magnetic type. These types of switches are not suitable for use in dusty, humid, easily explosive or combustible atmospheres. Various types of switches to avoid explosions have been developed, such as oil switches, safety switches, etc. However, because of their complex construction, these switches are not practical from a manufacturing or economic point of view. 65 The present invention therefore aims to overcome the above limitations by providing a very simple magnetic switch. To this end, the switch according to the invention is arranged as defined in claim 1.

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The present invention will be clearly understood on reading the following description given by way of example in conjunction with the attached drawings in which:

Fig. 1 is a vertical sectional view of an automatic magnetic switch according to one embodiment;

Fig. 2 is a perspective view with cutaway of a first variant of the contactor, which comprises a permanent magnet;

Fig. 3 is a vertical sectional view, taken along the line A — A ', of FIG. 2, representing the contacts in the closed state;

Fig. 4 is a sectional view taken along line B-B 'of FIG. 3, and representing magnetic metal blocks placed in the cover of the housing;

Fig. 5 is a vertical sectional view of a second variant of the contactor, which comprises an electromagnet;

Fig. 6 is a view in vertical section of a third variant of the contactor, which comprises a return spring of a contact plate;

Fig. 7 is a vertical section view of a fourth variant of the contactor, which comprises a contact plate loaded by a spring and pivoting between its ends;

Fig. 8 is a view in vertical section of a fifth variant of the contactor, which comprises a contact plate loaded by spring and provided with parallel contacts;

Fig. 9 is a sectional view taken along line C-C 'of FIG. 8 and representing the construction of the contact plate;

Fig. 10 is a vertical sectional view of a sixth variant of the contactor, which comprises a horizontally sliding contact;

Fig. 11 is a sectional view taken along line D-D 'of FIG. 10;

Fig. 12 is a sectional view of the contactor of FIG. 10 and showing a horizontal sliding contact in the closed state;

Fig. 13 is a perspective view of the protection against overloads or against short-circuits, represented in FIG. 1;

Fig. 14 is a perspective view of the electromagnetic control of the switch shown in FIG. 1;

Fig. 15 is a vertical sectional view of the switch shown in FIG. 1, the contactor being open;

Fig. 16 is a vertical sectional view of a second embodiment of a magnetic switch using an electromagnet;

Fig. 17 is a vertical sectional view of a third embodiment of a magnetic switch using a solenoid to indirectly control a magnet; and fig. 18 is a vertical sectional view of a fourth embodiment of a magnetic switch using the contactor shown in FIG. 10.

Referring to the figures, fig. 1 shows a vertical sectional view of an automatic magnetic switch 1 which comprises a housing 2 and a cover 3 fixed to the housing 2 by screws 4. The housing 2 comprises two adjacent chambers 5 and 6 for mounting a protection 7 against overloads or short circuits and a magnetic contactor 8, respectively. A sub-housing 9 is molded in one piece with the cover 3 to form a housing for the magnetic control 10.

The contactor 8 is one of the important features of this embodiment of the present invention. This contactor 8 mainly comprises a conductive plate 11 comprising an electrical contact, another conductive plate 12, rigid, comprising an electrical contact, mounted inside the housing 2 so as to be able to pivot or slide, and a magnetic member 13, such as a permanent magnet, coupled to the movable conductive plate 12 so as to urge the latter towards a contact engagement position when an external magnet 14 is approached from the housing 2.

In fig. 2 and 3, there is shown a perspective view and a sectional view of a first variant of the contactor which comprises a housing 15 of insulating and non-magnetic material such as wood, an insulating and non-plastic material, etc. The housing 15 comprises two protruding plates or flanges 16 having several holes 17 which make it possible to mount the device on a surface using screws. Seat blocks 18 and 19 are molded on a base 20 of the housing 15 and against the side walls 21. The blocks 18,19 have several recesses 22 for receiving electrically conductive plates 23 or conductive plates in the form of Z 24, plates which are fixed to the blocks 18 and 19 by screws 25. On the flanges 16 several seats 26 for conductors are provided, which allow the output of conductors 27 from the housing 15, the conductors being connected to the electrically conductive plates 23 , or to Z-shaped plates 24, by screws. The construction of the electrically conductive Z-shaped plates 23 and Z-shaped plates is suitable for single-phase or three-phase current applications.

The Z-shaped plates 24 are constructed of rigid conductive metals, electrical contacts of platinum or alloy 29 being formed thereon to form the fixed contacts. When the contact plates 23 are made of flexible conductive metals, platinum contacts 30 are formed at their ends to form movable contacts. In addition, a block 31 made of insulating and non-magnetic materials is mounted and fixed on the plate 23, by a screw 32, and a magnet 33 is mounted on the block 31. The block 31 is relatively thick, so that the magnetic field induced by the current flowing in the plate 23 does not interfere with the field of the magnet 33 to isolate it.

The housing also contains a cover 34 fixed to the side walls by screws 35. A U-shaped angle iron 36 is articulated on the cover 34 by hinges 37, at the ends of supports 38, comprising axes 39. The angle iron 36 comprises a permanent magnet 41 contained in its hollow part. The permanent magnet 41 can be placed above the magnet 33 and be brought closer to or away from that by rotation of the angle iron 36 around the axes 39, under the action of the control of the switch.

In fig. 3, when the permanent magnet 41 is close to the magnet 33, an attractive force will cause the upward displacement of the latter, and the displacement of the plate 23 and of the contact 30 towards a position of engagement and contacting the fixed contact 29, which will have the effect of closing the circuit. On the other hand, when the permanent magnet 41 is distant from the magnet 33, the restoring force of the contact plate 23 will overcome the attraction force, which will cause the downward movement of the plate 23, towards a disengagement position, which will have the effect of opening the circuit between the contact 30 and the fixed contact 29. It is not necessary to use the angle iron 36. Any device which makes it possible to adjust the force of attraction between the permanent magnets 41 and 33 can be used, for example, arrangements which call for horizontal movement or rotation of the permanent magnet 41 along the surface of the cover 34. In addition, the chamber of the housing 15 is tightly closed and filled with an inert gas or insulating oil, or evacuated, so as to reduce arcs which occur during switching.

In fig. 4 which is a sectional view taken along line B-B 'of FIG. 3, a pair of magnetic blocks 42 has been shown, which are arranged in the cover 34 of the housing, as shown, under the bar 40 and the permanent magnet 41 to connect the spaces separating the latter and the magnet 33 and to concentrate the magnetic flux and consequently to reinforce the force of attraction.

In fig. 5 which represents a vertical section view of a second variajijtedu contactor, an electromagnet 43 is fixed on the cover 34 of the housing 15 in place of the permanent magnet 41. The operation of the rest of the parts of the contact

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tor is the same as that which was for the switch of fig. 1 and 2.

In the third variant according to FIG. 6, the contact plate 44 is rigid and pivots on the seat block 45 about an axis 46. A spring 47 is connected to the plate 44 and to the base 48 of the housing, the plate 44 thus resting on a seat 49. A soft wire 50 is connected between the plate 44 and the output conductor 51. In this variant, the contact plate 44 can be made of thicker and harder metal so as to allow the passage of higher intensities and l adaptation of the switch to high power applications. In addition, the "fer-me" - "open" operation is more precise, because it is carried out using a spring.

In the fourth variant according to FIG. 7, the contact plate 52 pivots between its ends, on a seat 53 around a pivot 54. This variant comprises the same action-ing mechanism as the variant according to FIG. 6, with the exception, however, of the position of the pivot of the contact plate, this position being, in one case, at the end of the plate, and in the other, between the ends of this plate.

In Figures 8 and 9, there is shown a fifth variant actuated by a spring. A pair of contact plates 55 is fixed to the block 56 at the inlet and outlet sides. A movable contact plate 57 slides in a slot 58 of a vertical bar 59, and is biased by a spring 60. The plate 57 with its contacts 61 moves upward so as to close the circuit during the establishment of 'a force of attraction between the magnets 62 and 63. FIG. 9 is a sectional view taken along the line CC ”of FIG. 8 and represents the construction of the movable contact plate 57 and of the slot 58.

In FIGS. 10 and 11, which are a vertical section view of a sixth variant of the contactor, a lever 64 pivots on a support 65 around an axis 66, and comprises a fork arm 67 which cooperates with a shoe 68 of a horizontally sliding contact 69. The sliding contact 69 is also biased by a spring 70 and can move to the right or to the left depending on the force of attraction acting between the magnets 71 and 72, thanks to the lever mechanism. FIG. 12 represents the state in which the horizontally sliding contact is in contact with the fixed contact 73.

The overload or short-circuit protection 7 mounted in the chamber 5 of the switch box 2 is best represented in FIG. 13. This protection 7 is conventional and comprises a current conducting plate 74, bi-metal

75, and a short-circuit protection electromagnet

76. In connection with FIGS. 13, as well as with FIG. 1, the current conducting plate 74 can be fixed to the switch housing 2 by screws. The bi-metal 75 will take a certain camber when the power circuit is traversed by an overload current, and the temperature of the current conducting plate 74 will increase. If two phases of a three-phase power circuit are short-circuited, the large variation of the current in the current conducting plate 74 will cause an induced magnetic flux in the electromagnet 76, and therefore the downward attraction of the movable part 77 of the electromagnet 76.

In FIG. 14, which is a perspective view of the magnetic control 10, this control includes a T-shaped lever 78 which pivots on a support extending from a side wall, a first magnet 79, being mounted on one end of the arm transverse lever 80. In the sub-housing 9, a mount 81 extends from the cover 3, and a control lever 82 pivots on this mount 81 about an axis 83. The control lever 82 comprises a transverse arm lower 84 on which is mounted a second magnet 85; a coupling arm 86 comprising a first control part 87 which pivots about an axis 88 and a second control part 89 slidably mounted on the adjacent end by a bolt

90; and a spring 91 which connects the coupling arm 86 to the housing cover 3. The second control part 89 has a vertical slot 92 in which is engaged the bolt 90 and a pair of lug parts 93 constituting a stop means opposing the action of the spring 94 which normally has the effect of resting the bolt 90 on the lowest part of the vertical slot 92. The first part 87 and the second part 89 both have an inclined surface at their upper part and protrude through the wall 95. The sub-housing 9 also has slots 96 and 97, which contain a control rod 98 comprising a first abutment recess 99 and a second abutment recess 100. The rod 98 is connected to the external magnet 14 which is screwed to a non-magnetic plate 101, a spring 102 connecting the latter to the sub-housing 9. The magnetic control 10 also includes a manual switch-off mechanism 103 who has a b tool whose face is in the form of an arc 104, a fork body part 105 and a push plate 106 mounted between the wall 95 and the wing parts 93 of the second control part 89.

The operation of the automatic magnetic switch shown will now be described in conjunction with FIGS. 1, 14 and 15. When the power circuit is normal, the external magnet 14 attracts the magnet 13, which closes the contacts of the plates. current conductors 11 and 12, and the second control part 89 is locked in the second recess forming a stop 100 of the control rod 98, as shown in FIGS. 1 and 14. In the event of an overload of the power circuit, or short-circuit, the bi-metal 75 or the protective electromagnet 30 operate and the T-lever 78 begins to rotate, which causes the first magnet 79 to attract the second magnet 85. Like the second magnet 85 is attracted to the first magnet 79 of the lever 78, the control lever 82 begins to rotate clockwise, and the coupling arm 86 drives the second control portion 89 to drive it down and out of the second recess 100. The control rod 98 now moves to the right as a result of the return force of the spring 102 and drives the external magnet 14 to move it away from the cover 3. The control rod 40 98 will finally be locked by the first control part 87 and the magnet 13 falls to disengage. the contacts of the conductive plates of the current 11 and 12, as shown in FIG. 15.

It should be noted that the return force of the spring 102 must be greater than the magnetic attraction force exerted between the magnets 13 and 14, and that the magnetic attraction force exerted between the first magnet 79 and the second magnet 85 must be greater than the return force of the spring 91. In addition, after automatic cut-off of the power circuit, the first 50 and second magnets 79 and 85 will remain attracted and the first control part 87 will remain locked in the first recess 99 of the control rod 98. The external magnet 14 cannot recover its initial state unless the lower transverse arm 84 of the control lever 82 55 is manually raised so as to cause the sliding of the first control part 87 outside the first recess 99 of the control rod 98. Consequently, the lower transverse arm 84 serves as a safety control member of the automatic switch. On the other hand, the manual cut-off device 103 can be pushed down via the button 104 so as to cut the circuit manually in an emergency.

In the side wall of the sub-housing 9, a screw 116 is provided for adjusting the position of the lower transverse arm 84. „The sensitivity of the automatic magnetic switch can be adjusted by adjusting the screw 116. Plus the transverse arm 84 the lower the sensitivity of the switch.

In FIG. 16, which represents a second embodiment of the switch, an electromagnet 107 is used and a

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Contact system 108 is mounted in the switch housing. A drive arm 109 is formed at the right end of the transverse lever arm 80 of the lever 78. A rod 110 comprising a second magnet 111 is mounted in the sub-housing, so as to serve as a safety control member of the automatic magnetic switch. When the power circuit is traversed by an overload current or is short-circuited, the lever 78 will be caused to rotate by the bi-metal 75 or by the protective electromagnet 76. The drive arm 109 will cut the contacts of the contact means 108 to cut the current of the electromagnet 107. And the magnet 13 will descend to cut the entire power circuit.

In FIG. 17, which represents a third embodiment of the automatic magnetic switch, the construction is similar to that which is represented in FIG. 16 except however that this switch uses in solenoid 112 to indirectly control the external magnet 113 When the power circuit is traversed by an overload current, or is short-circuited, the current of the solenoid 112 will be cut, the magnet 113 will rotate around a shaft 114 to move away from the cover as a result of the effect of the return force of a spring 115. In addition, the rod 110 and the second magnet 111 serve as the safety control of the automatic magnetic switch. This embodiment has the advantage that a low-power solé-5 may cut a power circuit. In addition, it avoids the disadvantages of a conventional magnetic switch, that is to say that it will prevent the fall of scrap metal dust in the switch.

The fourth embodiment, according to FIG. 18, uses the contactor according to FIG. 10.

It should also be noted that the magnets 42 of FIG. 4 can also be applied to the cover between the first magnet 79 and the second magnet 85 or between the external magnet 14 15 and the magnet 13 to concentrate the magnetic flux and thus reinforce the force of attraction.

The design of the switch shown makes it possible to obtain a new, safe, simple, economical and practical magnetic switch, which is particularly suitable for high power switching applications.

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Claims (19)

629,334 1. Magnetic switch comprising a housing (2), a cover (3) fixed to the housing, a protection (7) against overloads and short-circuits mounted in a first chamber (5) of the housing, a magnetic contactor (8) mounted in a second chamber (6) of the housing and a magnetic control (10) contained at least in part in a sub-housing (9) which is molded in one piece with the cover (3), characterized in that the contactor (8) comprises a first electrically conductive plate (11) fixed inside the housing, a first electrical contact on this first plate (11), a second electrically conductive plate (12) mounted on the inside of the housing (3) for moving between engagement and disengagement positions, a second electrical contact on the second plate (12), elastic means for urging the second plate towards an engagement or disengagement position, a magnetic member (13) mounted on the second plate (12), and in that the control (10) comprises a second magnetic member (14,107,113) disposed on the other side of a wall relative to the second plate (12), and cooperating with the first magnetic member (13) so that its actuation moves the second plate (12) towards the other from the engagement and disengagement positions. 2. Switch according to claim 1, characterized in that the housing (2) is hermetically closed. 2 3. Switch according to claim 1, characterized in that the second chamber (6) of the housing is filled with an insulating oil. 4. Switch according to claim 1, characterized in that the housing (2) is maintained under vacuum. 5. Switch according to claim 1, characterized in that the housing (2) is filled with an inert gas. 6. Switch according to claim 1, characterized in that the magnetic members are constituted by magnets (13,14), mounted respectively on the second plate (12) and on an actuatable member (101), which moving towards said wall, moves the second plate (12) toward the other from the engagement and disengagement positions. 7. Switch according to claim 6, characterized in that the magnetic member (13) mounted on the second plate (12) comprises a permanent magnet (13), and a non-magnetic block interposed between the second plate and said permanent magnet for space and at least partially isolate it magnetically. 8. Switch according to claim 1, characterized in that it further comprises magnetic blocks (42), placed in the accessible wall (34) and arranged so as to join part of the space between the second plate and the operable member so as to strengthen the magnetic field near the actuatable member. 9. Switch according to claim 1 or 6, characterized in that the second plate is mounted so as to pivot inside the housing (fig. 6). 10. Switch according to claim 1 or 6, characterized in that the second plate is slidably mounted to be driven by transverse displacements (fig. 8). 11. Switch according to claim 1 or 6, characterized in that the second plate comprises a sliding rod (69) and a pivoting lever (67) cooperating with one end of the rod to slide it when the lever is actuated, whereby the rod only moves between engagement and disengagement positions along its length (fig. 10,11,12). 12. Switch according to claim 1 or 6, characterized in that the magnetic control (10) comprises a T-lever (78) pivoting on the side wall of the housing, a magnet mounted on a transverse lever arm (80) of that here, a control lever (82), a first control part (87) and a second control part (89) pivoting on a coupling arm of the control lever (82) and a control rod (98) comprising two stop notches (99,100) for coupling with the actuatable member (101) carrying a magnet (14), the magnetic control being arranged so as to be actuated by the overload protection and (7) short circuits to cut the contactor (8). 13. Switch according to claim 12, characterized in that the second control part (89) comprises a pair of ears (93) to stop the action of a spring (94), an io slot (92) being formed in the second control part and a bolt (90) passing through the slot, the spring urging the bolt to make it rest at the bottom of the slot. 14. Switch according to claim 13, characterized in that the magnetic control (10) comprises a cover member 15 pure manual (103) having a button with a raised head (104), a part of the fork body (105) and a push plate (106) disposed between the wall (95) of the sub-housing and the ears (93) of . the second control part (89) to allow manual switching off of the contactor (8). 2o 15. Switch according to claim 1, characterized in that the magnetic control (10) comprises a set of contacts (108) fixed in the housing (2) to cut the circuit of an external electromagnet (107,112). 16. Switch according to claim 15, characterized in that 25 that the magnetic control (10) further comprises a drive arm (109) connected to a T-lever (78) for cutting the contacts of the contact assembly when the lever T is action- ~ born by the protection against overloads and short circuits. 17. Switch according to claim 1, characterized in that 30 that the magnetic control (10) comprises a solenoid (112) fixed to the sub-housing, a set of contacts (108) fixed in the housing to cut the solenoid circuit, and an external magnet (113) connected to a spring (115) making it rotate and moving it away from the cover of the housing when the current in the 35 solenoid is cut off. 18. Switch according to claim 1 or 6, characterized in that it comprises magnets forming a bridge in the cover in a position located between the two magnets (13,14) so as to concentrate the magnetic flux and to reinforce the force d 'attrac- 40 tion. 19. Switch according to claim 1 or 6, characterized in that the magnetic control (10) comprises an adjustment screw (116) for adjusting the position of an arm (84) of a control lever (82), and adjust the sensitivity of the switch.