FR2985387A1 - DEVICE FOR CONTROLLING THE ELECTRIC POWER SUPPLY OF A LOAD, FOR EXAMPLE AN ELECTRIC LAMP - Google Patents

Abstract

This control device is intended to be connected to a deactivatable power source. It includes a load supply circuit (24) for electrically connecting the power source and the load. This circuit (24) comprises a connecting element (28) movable by means of an electromagnet (40) between two open and closed positions of this circuit. The control device further comprises mechanical means (32) for locking the connection element (28) in the open position, mechanical means (22) for deactivating these locking means (32), and means for electromagnetic means (38) for deactivating these locking means (32) comprising the electromagnet (40). The latter is provided with a plunger (44) intended to cooperate with the mechanical locking means (32) to disable them.

Description

The present invention relates to the control of the supply of an electric charge, for example an electric lamp. Usually, an electric lamp for example to be placed on a piece of furniture is provided with a power cord equipped with a lamp power control device, commonly called switch. The power cord is intended to be connected for example to a wall outlet for connection to a domestic power supply network, generally AC.

It is convenient to be able to control the plug, which is connected to the power cord of the lamp, by a wall switch that is usually located near a door access to the room in which the lamp is located. The switch arranged on the lamp power cord can generally adopt two states, namely an open state of extinguishing the lamp and a closed state of ignition of the lamp. When the switch is in its closed state, it is not possible to turn on the lamp from the wall button controlling the socket into which the lamp's power cord is plugged. It has therefore been proposed in the state of the art, in particular in US 2006/0017397 or US 2003/0146665, a device for controlling the supply of a load, in particular of an electric lamp, allowing, in the case where the lamp is plugged into a controlled socket as mentioned above, to turn on this lamp even if the switch fitted to the lamp's power cord has been left in its open state. Thus, US 2006/0017397 and US 2003/0146665 each propose a circuit for powering a load, such as an electric lamp, for electrically connecting a deactivatable power source, such as a wall switch, and the lamp. This circuit comprises a connection element with two opening and closing positions of this circuit. An electromagnet equipping a relay and electrically connected to the deactivatable power source forms means for moving the connection element between its two positions. This circuit, its two-position connection element and the relay are arranged in a switch equipping a power cord of the lamp or an electrical socket of the lamp. The switch has two pushbuttons. The actuation of a first push button is used to power the relay and thus to place the connection element in its open position of the circuit so as to isolate the lamp from the power supply. The actuation of the second push-button makes it possible to interrupt the supply of the relay and thus to replace the connection element in its closed position of the circuit allowing the supply of the lamp. The opening of the lamp supply circuit is thus ensured by maintaining the relay in the energized state. If, when the lamp supply circuit is open, a user entering the room where the lamp is placed wishes to switch on the lamp by means of the wall switch, two cases are possible. First case: the wall switch is in an isolated state the power source of the relay circuit. The relay is not powered and the switch fitted to the lamp is in a state allowing the power of the lamp. As soon as the user turns on the wall switch, the lamp comes on. Second case: the wall switch is in a state connecting the power source to the relay circuit. The relay is powered and the switch fitted to the lamp is in a state preventing the power supply of the lamp. The user first actuates the wall switch, which has the effect of changing the state and isolate the relay circuit of the power source. The power supply of the relay is thus cut off so that the switch of the lamp returns to its state allowing the power supply of the lamp. However, this lamp does not light (the power source was isolated by the first action on the wall switch), the user has the reflex to operate a second time the wall switch which has for effect of reconnecting the power source to the lamp and turning on the lamp. However, it is found that if the relay integrated in the lamp switch fails, it is no longer possible to control this lamp. Furthermore, the extinction of the lamp, namely the opening of the load supply circuit is caused by the maintenance of the relay in the powered state, which is likely to generate noise during this state, including when the relay ages. The invention is intended in particular to remedy the problem of a possible failure of the electromagnet of a control device of the type proposed in the state of the art, that is to say to allow to continue to control the power supply of the load from the switch equipping the power cord of this load despite the failure of the electromagnet. For this purpose, the subject of the invention is a device for controlling the power supply of a load, for example an electric lamp, intended to be connected to a deactivatable power supply source, of the type comprising a power supply circuit. of the charge for electrically connecting the power source - 3 - and the load, this circuit comprising a movable connection element, by means of an electromagnet, between two open and closed positions of this circuit, characterized in that it comprises: - mechanical means for locking the connection element in the open position, - mechanical means for deactivating these locking means, and - electromagnetic means for deactivating these locking means comprising: electromagnet, the latter being provided with a plunger for cooperating with the mechanical locking means to disable them.

Thanks to the invention, the mechanical locking means of the connection element in the open position can be deactivated both by the mechanical means of deactivation and by the electromagnetic deactivation means. Therefore, if the electromagnetic deactivation means fail, due in particular to a degradation of the operation of the electromagnet, it remains possible to move the connection element from its open position to its closed position at the end using mechanical means for deactivating the locking means. Thus, in case of failure of the electromagnet, the connection element can be moved by mechanical means between its open and closed positions of the circuit. According to other optional features of different embodiments of the control device according to the invention: the mechanical means for locking the connection element in the open position comprise hard point means comprising complementary means respectively fixed and mobile means, the mechanical means for deactivating the locking means comprising means for crossing this hard point by relative displacement of the complementary fixed and mobile means forming a hard point, the plunger of the electromagnet being intended to urge the mobile hard point means for disable the locking means. - The mobile hard point means are integral with a control button tilting between open and closed positions of the circuit, the plunger being intended to switch this control button to disable the locking means, for example by cooperation with an arm extending the control knob, substantially transverse to a tilting axis of the control knob. The mechanical means for locking the connection element in the open position oppose an elastic return force of this connection element in the closed position. - The mechanical means for locking the connection element in the open position comprise two releasable locking complementary stops intended to cooperate with each other to maintain the connection element in the open position of the circuit, by opposing the elastic force of return of this connection element in the closed position. The connecting element is carried by a rocker resiliently biased towards the closed position of the circuit, the complementary locking stops being carried by ends respectively of the rocker and of an articulated trigger, resiliently biased in the complementary position of the stops locking, the plunger of the electromagnet being intended to urge the trigger against its elastic return force, the rocker and the trigger having complementary surfaces for cooperating with each other to retract the ends of the rocker and the trigger bearing the lock stops. - The trigger is intended to be biased towards a release position of the complementary locking stops by a control button toggling between open and closed positions of the circuit, this rocker button being preferably kinematically connected to the rocker and the trigger so that the resilient biasing force of the rocker solicits the rocker button in the open position of the circuit and the elastic force of return of the trigger urges the rocker button in the closed position of the circuit. The rocker forms a button for controlling the opening of the circuit, and in which the trigger is intended to be biased towards a position of release of the complementary locking stops by cooperation of two ramps respectively carried by the trigger and by a button. control of the closure of the circuit, movable in translation substantially perpendicularly to a rocking axis of the rocker, this control button of the closure of the circuit being resiliently biased to a rest position allowing cooperation of complementary locking stops. - The electromagnet is powered by the deactivatable power source. The deactivatable power source is an AC source, for example for domestic use. - The plunger is biased to the position of cooperation with the mechanical locking means by applying an electrical supply pulse of the electromagnet. The electromagnet is powered by a circuit connected to an alternating current source, this supply circuit comprising a triac for controlling the supply of the electromagnet and a control branch of the triac comprising a circuit RC powered by means at least partial rectification of the alternating current. The invention also relates to a power cord of an electrical equipment, characterized in that it is provided with a device as defined above for controlling the power supply of the charge formed by this electrical equipment. . The invention will be better understood on reading the following description given solely by way of example and with reference to the appended drawings in which: FIG. 1 is a schematic view of a control device of the feeding a load, according to a first embodiment of the invention; - Figures 2 to 4 are schematic views of elements of the control device according to the first embodiment of the invention, in different operating states of these elements; FIG. 5 is a schematic view of a power supply circuit of an electromagnet of the control device represented in the preceding figures; FIGS. 6 to 8 are schematic views of elements of a control device according to a second embodiment of the invention; and FIG. 9 is a schematic view of elements of a control device according to a third embodiment of the invention. There is shown in Figure 1 a device 10 for controlling the supply of a load 12, for example an electric lamp to be placed on a piece of furniture. The control device 10 is intended to be connected to a power supply source 14 formed, for example, by means connected to an AC domestic power supply network. The power supply source 14 can be deactivated, for example by isolating it with the aid of a wall switch 16 capable of adopting two states, respectively open and closed.

FIG. 1 diagrammatically shows two electrical lines, corresponding to two current phases, connecting the load 12 to the power supply source 14. The control device 10 comprises four electrical input and output terminals. current output PE1, PE2, PS1, PS2. corresponding to the two phases of current. The control device 10 is integrated in a power supply cord 18 of the load 12. This cord 18 is connected to an electrical outlet 19 controlled by the wall switch 16. In the first embodiment of the invention, the The control device 10 comprises a casing 20 and a tilting control button 22. FIGS. 2 to 4 show this button 22 as well as other elements of the control device 10, housed inside the casing 20. More 2 to 4, elements of a load supply circuit 24 for electrically connecting the deactivatable power source 14 and the load 12 are represented. These elements are identical or common to both of them. current phases, so that, with some exceptions, these elements will be described later only with respect to only one of the current phases. In addition, when an element is said to be "fixed" subsequently, it is considered to be integral with the housing 20. The circuit 24 comprises two fixed contact elements 26, for example connected respectively to the terminals PE1 and PS1, and an element connection 28 movable between two positions, namely an open position of the circuit, as shown in Figure 2, and a closed position of the circuit 24, as shown in Figures 3 and 4. In the first mode of embodiment of the invention, the connecting element 28 forms a flip-flop whose displacements are driven by the control knob 22. In fact, this button 22 is pivotally mounted about a fixed axis 30 between an open position of the circuit 24, as shown in Figure 2, and a closed position of the circuit 24, as shown in Figures 3 and 4. The connection flip-flop 28 is lockable, both in the open position of the circuit and in closing position of the circuit, by mechanical means 32 including hard point means. These hard point means comprise complementary fixed and movable means formed for example by the cooperation of a fixed cam 34 with a movable cam 36 integral with the control knob 22. The connection rocker 28 participates in the hard point effect being interposed 35 between the fixed and movable cams 36. The connection flip-flop 28 is permanently in contact with an element 26. When the connection flip-flop 28 is in the closed position of the circuit 24, it is in contact with the second - 7 - element 26. The connection rocker 28 is moved between its open and closed positions of the circuit 24 by tilting of the control knob 22 causing a crossing of the hard point by relative displacement of the fixed cams 34 and mobile 36. The deactivation of the means locking 32 being done by tilting the control knob 22 causing a crossing of the hard point, this button 22 thus forms mechanical means for disabling the lock the connection flip-flop 28 is applied both when it is in the open position of the circuit 24 and in the closed position of this circuit 24. When the connection flip-flop 28 is in the open position, the mechanical means of locking 32 can also be deactivated by electromagnetic means 38. these means 38 comprise a conventional electromagnet 40, which has shown a winding 42 and a plunger 44 slidably mounted in translation through the winding 42. The winding 42 is electrically connected to a circuit 46 which is shown in more detail in Figure 5. The plunger 44 is movable between, on the one hand, a rest position, as shown in Figures 2 and 4, to which it is resiliently biased by a spring 48, and secondly, an active position, as shown in Figure 3, against the elastic return force of the spring 48. The plunger 44 is in the rest position lor sque electromagnet 40 is not powered. The plunger 44 is in the active position in the opposite case, that is to say when the electromagnet 40 is powered. Preferably, the plunger 44 is moved to its active position by applying an electric supply pulse of the electromagnet 40 by means which will be described below. The electromagnet 40 moves the connection flip-flop 28 from its open position of the circuit 24 to its closed position of the circuit 24 by crossing the hard point. Indeed, the plunger 44 has a free end 44E cooperating with a free end 50E of an arm 50 extending the control knob 22, substantially transverse to the pivot axis 30 of the control knob 22. Thus, the plunger 44 can move the control knob 22 from its open position of the circuit 24, as shown in Figure 2, to its closed position of the circuit 24, as shown in Figure 3. Indeed, when the latch of connection 28 is in the open position of the circuit 24, the displacement of the plunger 44 from its rest position to its active position tilts the control knob 22 and disables the locking means 32 of the connection flip-flop 28. The main aspects related to the invention of the operation of the control device 10 shown in FIGS. 1 to 4 will be described below. Initially, as shown in FIG. 2, the control button 22 and the rocker e of connection 28 are in their open position of the circuit 24. The electromagnet 40 is not powered. The button 22 and the connection rocker 28 are locked by the hard point in the open position of the circuit 24. The free end 50E of the arm 50 is in abutment with the free end 44E of the plunger, as shown in FIG. FIG. 2. Advantageously, a relative position of the plunger 44 at rest and of the arm 50 will be chosen, allowing an easy hard point crossing, in particular to limit the power of the electromagnet 40. Considering the wall switch 16 closed, the The user can control the supply of the load 12 from the control device 10 by tilting the control button 12 between its open and closed positions of the circuit 24. Considering that the circuit 24 is open in the control device 10 , the user can control the supply of the load 12 from the wall switch 16.

Indeed, an action on the wall switch 16 (single or double depending on the state of this wall switch) will cause the power supply of the electromagnet. By feeding the electromagnet 40 by an electrical pulse, the plunger 44E is moved to its active position and performs, during its race, the hard point crossing. At the end of this crossing, the control knob 22 and the connection rocker 28 are locked by the hard point in the closed position of the circuit 24, as shown in FIG. 3. After the electrical pulse of FIG. feeding has ceased, the plunger 44 is resiliently returned to its rest position, the control knob 22 and the connection rocker 28 remaining in the position shown in FIG. 4.

Note that if the electromagnet fails, the plunger 44 is held in its rest position by the resilient return force of the spring 48. However, the control knob 22 can be moved mechanically between its two open positions and closing the circuit 24 by tilting it in opposite directions, so that it is still possible to use the control device 10 to control the supply of the load 12. The electromagnet 40 is powered by the electrical circuit 46 preferably shown in Figure 5. Preferably, this circuit 46 is connected to the source 14, the latter providing in the example described an alternating current. The circuit 46 comprises a triac 54 for controlling the supply of the electromagnet 40 and a control branch 56 of the triac 54. This branch 56 comprises an RC circuit 58 powered by at least partial rectifying means 60 of the current alternative. The control branch 56 also comprises a load resistor R1 and preferably a signal optimization diode D1. The RC circuit comprises a capacitor C and a charge resistor R2. A resistor R3, connected in parallel with the capacitor C, allows the discharge of the latter. Finally, a diode D2 forms the means 60 for obtaining a partial rectification of the alternating current. When the circuit 46 is powered, that is to say connected to the AC source 14, the capacitor C is charged.

During the charging of the capacitor C, the current flowing in the control branch 56 makes the triac 54 passing. This has the effect of feeding the electromagnet 40 and thus moving the plunger 44 to its active position as shown in Figure 3. After charging the capacitor C, the current becomes negligible in the control branch 56, so that the triac 54 is no longer passing and cuts off the supply of the electromagnet 40. When the supply circuit 46 is isolated from the source 14, the resistor R3 allows the discharge of the capacitor C. The value of the resistor R3 is adapted so that the discharge of the capacitor C is fast enough that a user can, if necessary, very quickly after the emission of an electrical supply pulse of the electromagnet 40, cause a new charge of the capacitor C and thus generate a new electrical supply pulse of the electromagnet 40. Moreover, it will be noted that an appropriate value of the reactance of the capacitor C limits the current flowing in the circui t RC 58 and thus to well control the current in the 56 branch control of the triac. FIGS. 6 to 8 show a control device 10 according to a second embodiment of the invention. In these Figures 6 to 8, the elements similar to those of the preceding figures are designated by identical references. In this second embodiment of the invention, the mechanical locking means 32 of the connection element 28 oppose an elastic force of -repusing this connection element 28 in the closed position of the circuit 24. Unlike the first embodiment of the invention, in this second embodiment of the invention, the connection element 28 is carried by one end of a rocker 62 pivotally mounted about a fixed axis 64. A spring 66, connecting the housing 20 to the end of the rocker 62 carrying the connecting element 28 elastically recalls this latch 62 and the connecting element 28 to the closed position of the circuit 24. The mechanical locking means 32 of the connection element 28 in the open position of the circuit 24 comprise, in this second embodiment of the invention, two releasable complementary locking stops 68, 70, carried by, on the one hand, an end of the b ascule 62 opposite to that carrying the connecting element 28 and, secondly, an end of a trigger 72 articulated about a fixed axis 74. A spring 76, connecting the housing 20 to the end of the trigger 72 bearing the stop 70 elastically recalls this trigger 72 to a position for the cooperation of these complementary stops 68, 70, as shown in Figure 6. When the locking abutments 68, 70 cooperate with each other, they hold the element of connection 28 in the open position of the circuit 24 by opposing the resilient return force of the spring 76. Note that the pivoting stroke of the trigger 72 about its axis 74 is limited by two end stops B1 , B2 (see Figures 6 and 7). The end 44E of the plunger 44 is intended to cooperate with one end of the trigger 72 opposite to that bearing the locking abutment 70 so as to urge this trigger 72 against the elastic return force of the spring 76, as this is shown in Figure 8. Note that the ends of the latch 62 and the trigger 72 bearing the locking abutments 68 and 70 have complementary surfaces 68R 70R, for example rounded, intended to cooperate with each other to retract the ends of the rocker 62 and the trigger 72 carrying the stops 68 and 70. In the second embodiment of the invention, the rocker button 22 is intended to bias the trigger 72 to a release position of the locking stops 68, 70 as this is shown in FIG. 7. For this purpose, the tilting knob 22 is kinematically connected to the trigger 72, for example by means of two arms 76, 78 integral with each other. respectively of the control knob 22 and one end of the trigger 72 opposite that carrying the locking stop 70. The two arms 76, 78 are intended to cooperate with each other so that the movement of the control knob 22 to its position closing the circuit 24 causes the release of the locking abutments 68, 70. Preferably, the tilting button 22 is kinematically connected to the trigger 72 so that the elastic return force of the rocker 62 by spring 66 solicits the control button 22 in the open position of the circuit 24 (see Figure 6) and the elastic return force of the trigger 72 by the spring 76 biased control knob 22 in the closed position of the circuit 24 (see Figures 7 and 8). When the plunger 44 moves from its rest position to its active position, the end 44E of the plunger 44 cooperates with the end of the trigger 72 opposite to that bearing the locking abutment 70, so as to move this trigger 72, against the elastic return force of the spring 76, towards its release position of the locking abutments 68, 70, as shown in FIG. 8.

Thus, the displacement of the plunger 44 from its rest position to its active position deactivates the locking means 32 of the connection flip-flop 28. The following will describe the main aspects related to the invention of the operation of the control device 10 shown. 6 to 8. Initially, as shown in FIG. 6, the control knob 22 and the connecting element 28 are in their open position of the circuit 24. The complementary locking abutments 68, 70 cooperate with each other. between them. By considering the wall switch 16 closed, the user can control the supply of the load 12 from the control device 10 by tilting the control knob 22 so as to urge the trigger 72 to a release position of the stops of locking 68, 70, this against the return force of the spring 76, as shown in Figure 7. The latch 62 is then biased by the spring 66 to its position in which the connecting member 28 closes the circuit 24. The user has thus achieved a deactivation of the locking means of the connection element 28 in the open position of the circuit 24 by mechanical means. This deactivation of the locking means 32 may also be obtained using electromagnetic means 38 comprising the electromagnet 40 in accordance with the operation of this electromagnet described with respect to the first embodiment of the invention.

Thus, considering that the circuit 24 is open in the control device 10, the user can control the supply of the load 12 from the wall switch 16. Indeed, an action on the wall switch will cause the supplying the electromagnet 40. Of course, when the control knob 22 is in the closed position of the circuit 24 as shown in FIGS. 7 and 8, the trigger 72 is biased by the spring 76 bearing against the abutment B1, the locking abutments 68, 70 remaining separated according to a configuration not shown. However, as soon as a user again switches the control knob 22 to its open position of the circuit 24, the flip-flop 62 is moved against the restoring force of the spring 66. Moreover, the surfaces of FIG. retraction 68R, 70R, carried by the rocker 62 and the trigger 72 cooperate with each other to first retract the ends of the rocker 62 and the trigger 72 bearing these retraction surfaces 68R, 70R, then allow, under the effect of the elastic return of the spring 76, again the cooperation of the locking abutments 68, 70 so as to maintain the connection element 28 in the open position of the circuit 24, against the return force of the spring 66 FIG. 9 shows a control device 10 according to a third embodiment of the invention. In this figure 9, elements similar to those of the preceding figures are designated by identical references.

In this case, unlike the second embodiment of the invention, the trigger 72 is intended to be biased towards a release position of the locking abutments 68, 70 by cooperation of two complementary ramps 80, 82. Moreover, in this third embodiment of the invention, the locking abutment 68 is directly formed in a release of the rocking control button 22, the latter being resiliently biased by a spring 84 connecting the housing 20 to the control knob 22. In this third embodiment of the invention, the flip-flop 62 of the second embodiment of the invention is formed by the control knob 22.

The tilting knob and the trigger 72 comprise complementary surfaces 70R, 22R intended to cooperate with each other to retract the ends of the tilting knob 22 and the trigger 72 bearing the locking abutments 68, 70. A first ramp 80 is carried by the trigger 72. The second ramp 82 is carried by an additional control knob 84. In fact, in the third embodiment of the invention, the rocking control button 22 is intended to control the opening of the circuit 24 and the control button. The additional control 84 is intended to control the closing of the circuit 24. The additional control knob 84 is displaceable in translation substantially perpendicular to the axis of tilting of the control knob 22.

Furthermore, the additional control knob 84 is resiliently biased, by a spring 86, to a rest position allowing cooperation of the complementary locking stops 68, 70. In FIG. 9, the control knob 22 and the locking element connection 28 are in their open position of the circuit 24. The complementary locking stops 68, 70 cooperate with each other. When a user wishes to feed the load 12, he solicits the auxiliary control button 84 against the elastic return force of the spring 86, which has the effect of cooperating the ramps 80, 82 between them and to solicit the trigger 72 to a release position of the locking abutments 68, 70. Thus, under the effect of the spring return force of the spring 84, the control knob 22 and the connecting element 28 are recalled in their position of closure of the circuit 24. The closing of the circuit 24 can be obtained by the electromagnetic means comprising the electromagnet 40 in a manner similar to that described with respect to the two previous embodiments of the invention.

Claims (13)

REVENDICATIONS1. Device for controlling the power supply of a load (12), for example an electric lamp, intended to be connected to a deactivatable power source (14), of the type comprising a power supply circuit (24) the load (12) for electrically connecting the power source (14) and the load (12), said circuit (24) comprising a movable connecting element (28), by means of an electromagnet (40), between two open and closed positions of this circuit, characterized in that it comprises: - mechanical means (32) for locking the connection element (28) in the open position, - mechanical means (22) 84) of deactivation of these locking means (32), and - electromagnetic means (38) for deactivating these locking means (32) comprising the electromagnet (40), the latter being provided with a plunger ( 44) for cooperating with the mechanical locking means (32) for the d Disable. 2. Device according to claim 1, wherein the mechanical means (32) for locking the connecting element (28) in the open position comprises hard point means comprising complementary means respectively fixed (34) and movable ( 36), the mechanical means (22) for deactivating the locking means (32) comprising means for crossing this hard point by relative displacement of the fixed complementary means (34) and mobile means (36) forming a hard point, the plunger (44). ) of the electromagnet (40) being adapted to urge the hard point moving means (36) to deactivate the locking means (32). 3. Device according to claim 2, wherein the movable means (36) of hard point are integral with a control button (22) tilting between opening and closing positions of the circuit (24), the plunger (44). ) being intended to switch this control button to disable the locking means (32), for example by cooperation with an arm (50) extending the control button (22), substantially transverse to a pivot axis (30) of the control button (22). 4. Device according to claim 1, wherein the mechanical means (32) for locking the connection element (28) in the open position oppose an elastic force of return of this connection element ( 28) in the closed position. 5. Device according to claim 4, wherein the mechanical means (32) for locking the connecting element (28) in the open position comprise two releasable locking complementary stops (68, 70) intended to cooperate with each other for maintaining the connection element (28) in the open position of the circuit (24), by opposing the elastic return force of this connection element (28) in the closed position. 6. Device according to claim 5, wherein the connecting element (28) is carried by a rocker (62) resiliently biased towards the closed position of the circuit (24), the complementary locking stops (68, 70) being carried by ends respectively of the rocker (62; 22) and of an articulated trigger (72) resiliently biased into the complementary locking stops (68, 70), the plunger (44) of the electromagnet ( 40) being intended to urge the trigger (72) against its elastic return force, the rocker (62; 22) and the trigger (72) having complementary surfaces (68R, 70R, 22R) intended to cooperate between they to retract the ends of the rocker (62; 22) and the trigger (72) bearing the locking stops (68, 70). 7. Device according to claim 6, wherein the trigger (72) is intended to be biased towards a release position of the complementary locking stops (68, 70) by a control button (22) tilting between open positions. and closing the circuit (24), this rocker button (22) being preferably kinematically connected to the rocker (62) and the trigger (72) so that the elastic return force of the rocker (62) solicits the button tilting (22) in the open position of the circuit (24) and the elastic force of the trigger (72) urges the rocker button (22) in the closed position of the circuit (24). 8. Device according to claim 6, wherein the latch forms a button (22) for controlling the opening of the circuit (24), and wherein the trigger (72) is intended to be biased to a position of release stops complementary locking (68, 70) by cooperation of two ramps (80, 82) carried respectively by the trigger (72) and by a button (84) for closing the control circuit (24), movable in translation substantially perpendicular to an axis (30) for tilting the rocker (22), this button (84) for closing the circuit (24) being resiliently biased towards a rest position allowing the cooperation of the complementary locking stops (68). , 70). 9. Device according to any one of the preceding claims, wherein the electromagnet (40) is powered by the deactivatable power source (14). 10. Device according to claim 9, wherein the deactivatable power source (14) is an AC source, for example for domestic use. 11. Device according to any one of the preceding claims, wherein the plunger (44) is biased in the position of cooperation with the mechanical locking means (32) by applying an electrical supply pulse of the electromagnet (40). ). 12. Device according to claim 11, wherein the electromagnet (40) is fed by a circuit (46) connected to an alternating current source (14), this supply circuit (46) comprising a triac (54) of controlling the power supply of the electromagnet (40) and a triac control branch (56) (54) comprising an RC circuit powered by means (60) for at least partial rectification of the alternating current. 13. Power cord of an electrical equipment, characterized in that it is provided with a device (10), according to any one of the preceding claims, for controlling the supply of the load (12). ) formed by the electrical equipment.