FR2466849A1 - EM relay for coupling to semiconductor relay - receives mercury globules in trough forming contacts with halves of toroidal magnetic circuit connected static relay - Google Patents

Abstract

The relay has an associated electromagnetic relay connected in parallel to shunt current past the Triac and avoid excessive heating of the latter. The electromagnet has an energising coil formed by part of the relay load circuit and an armature (4) formed by a segment of a toroidal magnetic circuit (2) split by an electrically insulating magnetically conductive spacer diametrically opposite the armature. The opposing faces of the toroid and armature receive mercury globules in troughs forming the relay contact with the respective toroid halves electrically connected across the triac. The speed of the electromagnetic relay is such that the armature closes with the toroid halves over less than 45 degrees of the load a.c. once the triac is fired to shunt current past the latter, and opens before the load a.c. reaches its crossover point.

Description

 The present invention relates to an electromagnetic relay comprising a magnetic circuit forming a loop, excitation means and a working contact, intended to be associated with a static relay comprising a controlled conduction junction connected to two power terminals, controlling a charging circuit with alternating or corrugated current, as well as a circuit for controlling said junction.

 We know that the main performance limitation of a static relay is given by the voltage drop which appears in the semiconductor (for example of the triac type) in the on state.

This voltage drop, of the order of a volt, causes heating which imposes the presence of a bulky and expensive radiator. If there was not this heating problem, the current of the solid state relay could have been quintupled compared to the nominal current in steady state.

 The object of the present invention is to reduce the heating of a static relay by shunting the controlled junction for part of the conduction time by means of the working contact of an electromagnetic relay specially adapted for this purpose. The invention also aims to simplify the mounting of such an electromagnetic relay on a static relay as found in trade.

 The invention is characterized in ink that the means of excitation of the electromagnetic relay are constituted by the passage through the loop of the magnetic circuit of at least one turn of at least one of the conductors of the load circuit, said conductors being connected respectively to the power terminals of the static relay, in that the working contact of the electromagnetic relay has its terminals respectively connected to one of the power terminals of the static relay, in that the working contact of the electromagnetic relay is dimensioned to allow a substantially equal current to flow to that of the static relay in the best conditions of temperature, dissipation and duty cycle, in that the closing speed of the working contact of the electromagnetic relay, in response to a command to conduct the junction at the start of a alternation of the charging circuit current, is such that the working contact is closed before the instant when the current reaches its peak value, and in that the opening speed of the working contact, in response to the natural decrease in the alternation during the current, is such that the working contact is opened before 1 instant or the current reaches its value zero, so as to reduce the heat dissipation generated in the junction by the current of the load circuit, while allowing the control of this current by the control circuit of the junction.

 In a preferred embodiment of the invention, the magnetic circuit of the electromagnetic relay consists of a magnetic torus, a sector of which is sectioned from the rest of the torus by two planes intersecting along a straight line parallel to the axis of the torus and located between this axis and the inner edge of said sector; the sector is movable in translation in a direction perpendicular to the axis of the torus and a restoring force tends to bring the sector into a position opposite to that where it is in contact with the rest of the torus, so that the sector, separated from the rest of the torus by two air gaps, constitutes the armature of the relay.

 In this embodiment, the working contact being of the double break type, the fixed and mobile contacts are preferably formed by troughs dug in the airgap surfaces and each filled with a drop of mercury.

Other characteristics and provisions of the present invention will appear during the description which follows, given by way of nonlimiting example, with reference to the accompanying drawings in which
- Figure 1 shows a diagram of the association of the two types of relays.

 - Figure 2 shows the loop-shaped magnetic circuit of the electromagnetic relay.

 - Figure 3 shows contact areas wetted with mercury on the face of an air gap of the magnetic circuit.

 - Figure 4 shows an electromagnetic relay associated with a static relay of the type with screw terminal box.

 - Figure 5 shows an end view of one set of relays of Figure 4.

 - Figure 6 shows in partial section an electromagnetic relay associated with a static relay of the cylindrical housing type with fixing and connection stud.

 In Figure 1, there is shown at 1 an electromagnetic relay comprising a magnetic circuit symbolically represented by line 2, excitation means 3 and a working contact 4 of the double break type. A static relay 5 comprises a controlled conduction junction 6, here of the Triac type, connected to two power terminals Al - A2, controlling a load 7 inserted in an alternating R-S circuit. The junction can be made conductive by a control circuit (not shown) connected to the trigger G of the Xriac.

 It can be seen that the working contact 4 has its terminals connected respectively to the power terminals AI - A2 of the static relay 5 and that the excitation means 3 comprise at least one revolution of one of the conductors of the load circuit, here between the terminal A2 and a point A3.

 A command for conduction of the junction 6 from the start of alternating alternating current of the load circuit causes the excitation of the relay 1 and the closing of the contact 4. The closing speed of this contact is such that the contact is closes before the instant when the alternating current reaches its peak value, and preferably when it reaches about half of this value. In addition, the opening speed of the contact 4, thinking of the natural decrease of the alternation in the course of the alternating current, is such that this contact is opened before the instant when the alternating current reaches its zero value.

 In this way, the heat dissipation generated in the junction 6 by the alternating current of the load circuit is reduced in a proportion all the greater as the relay 1 has a fast operation.

 The control by full alternations or by phase delay can of course be carried out by trigger G.

 The magnetic circuit shown in Figure 2 consists of a torus 8 of material - preferably laminated. A sector 9 of this torus is sectioned from the rest of the torus by two intersecting planes 10, it intersecting along a straight line 12 parallel to the axis 13 of the torus. The straight line 12 is located between the axis 13 and the inner edge of the sector 9. The sector 9 is movable in translation in a direction perpendicular to the axis 13 of the torus and a restoring force F tends to lead the sector 9 in a posit-ion opposite to that where it is in contact with the rest of the torus. In this position, the sector 9 is separated from the rest of the torus by two equal air gaps. Sector 9 constitutes the frame of the relay.

 Preferably, the angle between the two planes 10 and 11 is close to 900 (for example between 80 and 1200) and the distance which separates the two horns 14-15 from the rest of the torus is between 3 and 6 times the distance between the two faces of an open air gap.

 In this way, the area of an air gap is larger than the cross section of the torus and the mass of sector 9 is as small as possible, while avoiding creating a leakage flow not passing through sector 9.

 The excitation of this magnetic circuit must be carried out by the passage through the toroid of at least one revolution of one of the conductors of the charging circuit. If the passage of a single turn two single conductor does not give enough amperes, taking into account the nominal intensity of the charging circuit, it is of course possible to pass several turns of the same conductor through the toroid, or turns of opposite direction of each of the two conductors -: - s.

 In Figure 2, we also see that a seal 16 separates the rest of the torus into two parts 17-18 The seal 16 has a weak magnetic reluctance and good electrical insulation. It can be constituted for example by an insulating sheet, the two parts 1718 being held one against the other by an overmolding 19. The fixed and mobile contacts of the double-break working contact can thus be placed in the air gaps of the magnetic circuit, the parts 17, 18 being each provided with an electrical connection member.

 To accommodate the contacts in the air gaps, it is planned to dig troughs in the air gap surfaces, as shown in FIG. 3, and to deposit in each trough a drop of mercury 20. The troughs must have a surface condition wettable with mercury, the rest of the airgap surface not being wettable with mercury. To allow a large current to pass, each air gap surface must be provided with several troughs, as for example is shown in patent FR 2 402 941.

 To protect the wet mercury contacts, a glass envelope is provided surrounding the frame and the air gaps and comprising a spring generating the return force F, as will be seen below.

 In FIGS. 4 and 5, there is shown at 21 a housing of a static relay of the type with power terminals Al - A2 with screws 22-23 arranged symmetrically at one end of the housing, the other end comprising terminals 24 of control of the junction control circuit.

The electromagnetic relay 1 is located near the terminals
AI - A2. The glass envelope 25 mentioned above is visible in Figures 4 and 5. The part opposite to the axis 13 of this envelope contains a housing for a prestressed blade 26, perpendicular to the direction of movement of the sector 9. Folded legs of the blade 26 fix the sector 9 to the center of the blade (see Figure 5).

 It can be seen that the terminals 27 and 28 of the working contact have a spacing and connection areas which adapt to the power terminals of the static relay. In addition, the terminal 27 is arranged substantially along the axis 13 of the torus 8 while the terminal 28 is disposed outside of the torus. On the other hand, the terminals 27 and 28 are fixed to the parts 17 and 18 of the torus, for example by folded and welded tabs.

 Conductors 29 and 30 of the load circuit (see Figure 4) are connected to the static relay 5 at the same time as the terminals 27 and 28.

 The conductor 29 crosses the torus. It can therefore be seen that the fixing of the electromagnetic relay 1 to the static relay 5 is provided by the operation of connecting the conductors 29 and 30 of the charging circuit. The static relay 5 also has its own fixing means, which for example consist of two holes in a base plate.

 It would also have been possible to loop the conductor 29 to pass it a second time through the torus and / or to pass the conductor 30 through the torus but in the other direction, so as to double or triple the amperes of relay 1.

 In FIG. 6, the static relay is of the cylindrical case type 31 comprising at a first end a threaded stud 32 serving for connection and fixing, and at the second end, a power terminal 33 as well as a trigger G. A terminal 27 of the working contact is provided to receive the stud 32 and is arranged along the axis 13 of the torus whose inner diameter is greater than that of the cylindrical housing 31. The other terminal 28 of the working contact is provided to be connected to the terminal of power 33.

 In this arrangement, the fixing of the electromagnetic relay is provided by the operation of fixing and connecting the static relay. These static relays often have standardized dimensions.

 Instead of having a Triac semiconductor, it is possible to have two thyristor semiconductors connected head to tail in parallel. By associating an electromagnetic relay with each thyristor before putting in parallel; each relay is allowed to work only one alternation out of two, which facilitates switching. The mounting of an electromagnetic relay on a thyristor can be the same as in the case of a Triac.

 One can also consider the use of a single thyristor associated with an electromagnetic relay, for example to control a load in monoalternance, or even in ripple or direct current.

In the latter case, however, successive conduction commands must not take place at too high a rate and a separate device must be provided to cut the load.

 It is noted that the working contact of the electromagnetic relay has only to establish a current which is not very high if there is no phase delay, to let pass a large current and to cut a low current at a recovery voltage of only one volt, the voltage only rising later than the mains value. The lifespan of the electromagnetic relay can therefore be long, especially with mercury contacts.

 Of course, the invention is not limited to the embodiments which have just been described. It includes all the technical equivalents of the means involved if they are in the context of the claims which follow.

Claims (7)

 1. Electromagnetic relay comprising a magnetic circuit form a loop, excitation means and a working contact, intended to be associated with a static relay comprising a controlled conduction junction connected to two power terminals, controlling a charging circuit with alternating or corrugated current, as well as a control circuit for said junction, characterized in that the excitation means (3) of the electromagnetic relay (1) are constituted by the passage in the loop of the magnetic circuit of at least one turn of at least one of the conductors (29, 30) of the charging circuit, said conductors being connected respectively to the power terminals (A1, A2) of the static relay (5), in that the working contact (4) of the electromagnetic relay (1) has its terminals respectively connected to one of the power terminals (Aî, A2) of the static relay (5), in that the working contact (4) of the electromagnetic relay (1) is dimensioned to allow a current awareness slightly equal to that of the static relay under the best conditions of temperature, dissipation and r.arche factor, in that the closing-speed of the working contact (4) of the electromagnetic relay (1), in response to a command conduction of the junction from the start of alternating current of the load circuit, is such that the working contact is closed before the instant when the current reaches its peak value, and in that the opening speed of the working contact, in response to the natural decrease in the alternation during the current, is such that the working contact is opened before the instant when the current reaches its zero value, so as to reduce the heat dissipation generated in the junction (6) by the load circuit current, while allowing control of this current by the junction control circuit.  2. electromagnetic relay according to claim 1, characterized in that the magnetic circuit is constituted by a magnetic toroid (8) of which a sector (9) is sectioned from the rest of the torus by two intersecting planes (10, 11) intersecting according to ur .e straight (12) parallel to the axis (13) of the torus and located between this axis- and the inner edge of said sector (9), in that said sector (9) is movable in translation in a direction perpendicular to 1 'axis (13) of the torus (8) and in that a restoring force (F) tends to bring the sector (9) in a position opposite to that where it is in contact with the rest of the torus, so that the sector (9), separated from the rest of the torus by two air gaps, constitutes the frame of the relay (1).  3. Electromagnetic relay according to claim 2, characterized in that the angle between the two intersecting planes (10, 11) is between 80 and 1200 and in that the rest of the torus forms two horns (14, 15) separated by a distance between 3 and 6 times the distance between the two faces of an open air gap.  4. An electromagnetic relay according to claim 2 or 3, in which the magnetic toroid has good electrical conductivity and in which the working contact is of the double break type, comprising fixed contacts and movable contacts, -characterized in that the contacts fixed and mobile are constituted by troughs dug in the faces of the air gaps, said troughs having a wettable surface state with mercury and each being filled with a drop of mercury (20), in that the rest of the torus is separated into two parts (17, 18) by a seal (16) having a low magnetic reluctance and good electrical insulation, in that each of the parts (17, 18) of the rest of the toroid is provided with an electrical connection member (27, 28 ) serving as terminals of the working contact (4) and in that a glass envelope (25) surrounds and protects the armature and the air gaps.  5. An electromagnetic relay according to claim 4, in which the associated static relay is of the type with screw power terminals, arranged symmetrically at one end of a housing, characterized in that the terminals (27, 28) of the contact working (4) have a spacing and connection pads suitable for the screws (22, 23) of the power terminals (Aî, A2) of the static relay (5) and in that one terminal (27) of the working contact (4 ) is arranged substantially along the axis (13) of the torus (8) while the other terminal (28) is arranged outside the torus so that the fixing of the electromagnetic relay is provided by the operation of connection of the conductors (29, 30) of the charging circuit and so that the toroid (8) is crossed at least once by at least one of the conductors of the charging circuit.  6. An electromagnetic relay according to claim 4, in which the associated static relay is of the cylindrical case type comprising at a first end a threaded connection and fixing stud and at the second end a power terminal, characterized in that a terminal (27) of the working contact (4) is designed to receive the threaded stud (32) and is arranged along the axis (13) of the torus whose internal diameter is greater than that of the cylindrical housing (31) of the static relay ( 5), and in that the other terminal (28) of the working contact (4) is designed to be connected to the power terminal (33) of the second end of the cylindrical housing (31)  7. electromagnetic relay according to any one of the preceding claims, the associated static relay being constituted by two tliyristcrs connected head to tail in parallel, characterized in that an electromagnetic relay (1) is associated with each thyristor before the thyristors are connected in parallel , so that each electromagnetic relay works only one alternation out of two.