FR2995147A1 - ELECTRICAL PLUG COMPRISING ELECTRICAL CONTROL MEANS - Google Patents

Abstract

The invention relates to an electrical socket (100) comprising two electrical connection terminals each provided with a socket for the insertion, at the front of the electrical socket, of a connection pin of a plug, as well as electrical control means. According to the invention, the electrical control means comprise, on the one hand, a sensor (600) adapted to act on an electrical control circuit for generating a control command, and, on the other hand, a pin (500). single translationally displaceable, against an elastic return means (510), along the axis of a first of the two cells, from a first rest position in which the pin emerges in said cell, up to a second actuation position in which the pin is moved backward of the electrical outlet and actuates the sensor to act on said control circuit.

Description

TECHNICAL FIELD TO WHICH THE INVENTION RELATES The invention relates generally to electrical outlets.

It relates more particularly to an electrical outlet comprising two electrical connection terminals each provided with a socket for insertion, at the front of the electrical socket, of a connection pin of a plug, as well as control means electric. The invention finds a particularly advantageous application in the realization of a secure electrical outlet whose power supply is controlled. This is for example an electrical outlet of a public charging terminal of a battery of a motor vehicle. BACKGROUND ART Documents EP0498056 and FR903614 are already known, electric sockets of the aforementioned type in which each of the cells of the connection terminals is equipped with a pusher adapted to be depressed by the pin of a plug against a return spring. All pushers simultaneously pressed by the pins of a plug connected to such an electrical outlet, are adapted to move in translation an actuator that actuates at least one switch to close a power supply circuit of the electrical outlet. Thanks to this complex arrangement, it is ensured that the electric power supply of the electrical outlet is achieved only when all the pins of the plug are inserted into the cells of the electrical connection terminals of said plug. Also known from CN102005679, an electrical socket for recharging a battery of a motor vehicle, which further comprises connecting cells of the connection pins of a plug, a conduit for inserting a pin of check provided in supplement on the card. This insertion duct 30 houses a pin adapted to be displaced in translation along the axis of the duct under the action of the control pin of the plug connected to the socket, against an elastic return means, to actuate a microswitch to open the starting circuit of a motor vehicle.

OBJECT OF THE INVENTION Compared to the prior art, the present invention provides a new secure electrical outlet simple to perform and that guarantees control of its power supply.

More precisely, the invention proposes an electrical socket as defined in the introduction, in which the electrical control means comprise, on the one hand, a sensor adapted to act on an electrical control circuit for generating a control command, and, on the other hand, a single pin movable in translation, against an elastic return means, along the axis of a first of the two cells, from a first rest position in which the pin emerges in said cell , to a second actuating position in which the pin is moved backward of the electrical socket and actuates the sensor to act on said control circuit. Thus, advantageously, in the electrical socket according to the invention, the power supply of the socket can be activated only when the electric plug is inserted. The electrical outlet is therefore secure. Thanks also to the invention, when a plug is inserted into the electrical outlet, it can generate any command order other than that which consists in activating the power supply of this electrical socket, such as for example a control of another electrical equipment separate from the electrical outlet. The power supply of this other electrical equipment can then be started or stopped depending on the insertion of the plug into the electrical outlet. In addition, this electrical outlet is simple and economical to achieve.

Other non-limiting and advantageous features of the electrical socket according to the invention are the following: said sensor is a microswitch comprising a control member distinct from said pin and adapted to cooperate with it; said sensor is a microswitch comprising a control member constituting said pin; the sensor, the pin and the resilient return means of this pin are housed in a detection support integral with the rear face of a base of said electrical socket, outside this base; said detection support comprises an insulating housing which partially surrounds said sensor, said pin and said biasing means and comprises means for mounting on said base of the electrical socket; said mounting means comprise an orifice for the passage of a fixing screw; said means for returning the pin to its first rest position comprise a spring interposed between said pin and a rear wall of said insulating case; said means for returning the pin to its first rest position comprise a spring interposed between a microswitch element adapted to cooperate with said pin and a wall of an insulative box of said microswitch; said socket comprising a base comprising a base from which there are four side walls, a through opening is formed in the bottom of this base, opposite said first cell, so as to allow the passage of said pin to through this through opening, from the outside of the base to the inside of the base, in said first cell; said electrical control circuit comprises an electric power supply circuit of the socket, and the control command authorizes the power supply of this electrical socket; said electrical control circuit comprises an electrical circuit for powering an electrical equipment separate from said electrical socket, and said control command authorizes the power supply of this electrical equipment; said electrical control circuit comprises an electrical relay, and said control command allows the passage of an electric current in this electrical relay; and, said electrical control circuit comprises an electrical circuit for powering an electrical accessory and in which the control command stops the power supply of this electrical accessory. DETAILED DESCRIPTION OF AN EXEMPLARY EMBODIMENT The following description with reference to the accompanying drawings, given as non-limiting examples, will make it clear what the invention consists of and how it can be achieved. In the accompanying drawings: - Figure 1 is a schematic perspective view of an electrical outlet according to the invention on which a portion of the socket is shown exploded; - Figure 2 is a schematic view of the electrical socket of the figure; 1, on which the portion of the electrical outlet shown in FIG. 1 is assembled; FIG. 3 is a diagrammatic front view of the electrical socket of FIG. 1 in which an electrical plug is inserted, FIG. 4 is a diagrammatic sectional view, along the sectional plane AA of FIG. 3, of the electrical socket and the electrical plug of FIG. 3 when the electric plug is not inserted into the electrical socket, FIG. 5 is a diagrammatic sectional view similar to that of FIG. 4 when the electrical plug is inserted into the electrical socket; FIG. 6 is a diagrammatic sectional view, along the sectional plane BB of FIG. 3 and when the electrical plug is not inserted into the electrical socket, FIG. 7 is a diagrammatic sectional view similar to that of FIG. 6 when the electric plug is inserted into the electrical socket and the electrical plug of FIG. 8 is a schematic side view of the electrical socket and the electrical plug of FIG. 6; FIG. 9 is a schematic side view of the electrical socket and the electrical plug of the electrical socket; FIG. 4, and FIGS. 10 to 14 are diagrammatic views of the electrical socket of FIG. 1 and of the electrical control circuit of this electrical socket. FIGS. 1 to 14 show diagrammatically an electrical socket 100 according to the invention. In the description, the terms "front" and "rear" respectively refer to the side of the electrical equipment facing the user when this equipment is used and the opposite side. The electrical socket 100 is here adapted to be housed in a box 30 recessed or reported projecting on any wall (not shown). Alternatively, it may be an outlet type extension or a power strip. It may also be an electrical outlet integrated into a public terminal, arranged along a traffic lane or in a parking lot. The principle of the invention described here is not modified.

As shown more particularly in Figures 1 and 2, the electrical outlet 100 here comprises two parts. A main portion 200 of the electrical outlet generally and unless otherwise indicated, a conventional arrangement of components.

An auxiliary portion 300 of the electrical outlet 100 is here attached to this main portion 200. The conventional arrangement of the main portion 200 is briefly described hereinafter. This main part 200 of the electrical outlet comprises in particular a base 210 which houses various internal elements. This base 210 is closed on the front face by a hubcap 220 (Figures 1, 8 and 9). This hubcap 220 comprises a flat part 221 which covers the free edge of the base 210 and a recess forming the receiving well 222 of the electrical socket 100. This receiving well 222 (FIG. 2) is adapted to receive an electrical plug 800 (FIG. Figures 4 to 9). The base 210 is made of insulating material, for example by molding a plastic material. It has a generally parallelepipedic shape (FIGS. 1 to 9) and is open on the front face. It comprises a bottom 211 bordered by four side walls 212 which rise from the bottom 211, substantially perpendicular to it. A shoulder 217 of each side wall 212 induces expansion of the base section 210 (Figures 1, 2 and 4 to 9). This shoulder 217 is located at the boundary between a rear portion and a front portion of the base 210. As shown more particularly in Figures 1, 2 and 9, the front portion of the base 210 includes means for mounting this base in a electrical equipment mechanism support (not shown). This support is typically in the form of a frame having a central opening through which the base 210 passes. More specifically, the base 210 includes a sidewalk 215 along the edge of the front opening of the base 210 and means 'snap 216' formed in the side walls 212.

When the sidewalk 215 is supported on a front face of the support, the latching means 216 cling to the rear of the support. The support can then be applied against the wall on which the electrical outlet 100 is intended to be mounted.

The front part of base 210 (FIG. 2) also houses said receiving well 222 of electrical outlet 100. This receiving well 222 has a bottom which extends substantially parallel to the bottom of base 210 of electrical outlet 100, and a cylindrical side wall that borders the bottom. The rear part of the base 210 houses electrical contact elements for connecting the electrical network to the electrical plug 800 inserted in the electrical outlet 100. These electrical contact elements here comprise three connection terminals. There is provided here a phase connection terminal B1 and a neutral connection terminal B2 (FIGS. 4 to 7) as well as a connection terminal connected to a protection circuit, each being intended to be electrically connected to an electrical conductor the electrical network carrying the phase current, neutral or connected to the protection circuit, here to earth. Of course, it is possible to envisage other electrical distributions of the electrical connection terminals, for example with two phase connection terminals. Each phase terminal B1 and neutral B2 comprises in particular a receiving cell 251, 252 (FIG. 4 to 7) adapted to receive one of the phase and neutral pins 840 of the corresponding electrical plug 800 (FIGS. 7). When the electrical plug 800 is inserted into the receiving well 222 of the electrical outlet 100, the pins 840 of this electrical plug pass through two openings 224 formed in the bottom of the receiving well 222 and penetrate into the receiving cells of the connection terminals. phase B1 and neutral B2 (Figures 5 and 7). The connection terminal connected to the earth shown in the figures here is a terminal according to the Franco-Belgian standard. It is connected to a connection pin 223 which protrudes into the receiving well 222 of the electrical outlet 100 from the bottom of this receiving well. This pin 223 cooperates with complementary connection means of the electrical plug 800 (Figure 2). The auxiliary portion 300 of the electrical outlet 100 constitutes an actuating part of the electrical control circuit 900 of the electrical outlet 100.

It comprises a detection support which houses electrical control means of the electrical outlet 100 and includes mounting means on the base 210 of the electrical outlet. For this purpose, this detection support comprises an insulating housing 310 of generally rectangular parallelepiped shape (FIGS. 1, 2 and 4 to 9) adapted here to be attached to the base 210, outside this base. The housing 310 has a rear portion 311 partially closed at the front by a front portion 312 (Figures 1 and 2) and a cover member 319. It is preferably made by molding a plastic material. In practice, here the two rear portions 311 and 312 are made in one piece, interconnected by breakable tabs 320. The front and rear portions of the housing 310 are shown in one piece in FIG. breakable tongues 320 intact. They are shown assembled in FIGS. 2 and 4 to 9, with breakable tabs 320 broken.

Alternatively, it could be envisaged that the housing 310 is made in one piece, for example with a front portion and a rear portion connected by a hinge-film. Remarkably, the electrical control means of the electrical outlet 100 comprise, on the one hand, a sensor 600 adapted to act on an electric control circuit 900 (FIGS. 10 to 13) to generate a control command, and, d on the other hand, a single pin 500 displaceable in translation, against an elastic return means 510, along the axis of a first 252 of the two cells 251, 252, from a rest position in which the counter 500 emerges in said first cell 252, to an actuating position in which the pin 500 is moved backward of the electrical socket 100 and actuates the sensor 600 to act on said control circuit 900 (FIGS. 4-7). The control circuit 900 may comprise different components. Several examples will be described later with reference to FIGS. 10 to 14. The sensor 600 is here adapted to modify the open or closed state of the electrical control circuit 900, that is to say to move it from an open state wherein the electric current does not flow in this control circuit to a closed state in which the electric current flows, and / or vice versa. Alternatively, it can also be envisaged that the control circuit comprises several circuit parts and that the sensor 600 is adapted to modify the state of several circuit parts. In particular, the case where the control circuit has two circuit parts and where, when the sensor is actuated, it passes one of the two circuit parts from the open state to the closed state and the other circuit portion of the closed state in the open state.

The rear portion 311 of the housing 310 of the auxiliary portion 300 of the electrical outlet 100 here comprises a parallelepipedal housing 313 for the sensor 600 and two adjacent cylindrical housings 314, 315 which respectively house said pin 500 and the return means 510 of a part, and a temperature sensor 700 on the other hand.

The parallelepipedal housing 313 has a main wall which extends parallel to the bottom 211 of the base 210 of the electrical outlet 100. The two cylindrical housings 314, 315 extend along a longitudinal axis perpendicular to this main wall of the housing 310 and at the bottom 211 of the base 210 of the electrical outlet 100.

The axis of a first cylindrical housing 314 which houses the pin 500 extends more particularly along the same longitudinal axis as said first cell 252 (Figures 4 to 7). The pin provided here is a single pin, which protrudes exclusively inside the first cell 252 of the electrical outlet 100, so as to cooperate with the pin 840 of the electrical plug 800 coming into the slot 252. Thus, the structure of the electrical outlet 100 is simplified. Said control means of the electrical outlet 100 are easy to implement and require little modification of the base of the electrical outlet. The sensor 600 is a sensor of the microswitch 600 type. It is a switch comprising, on the one hand, a control member 610 (FIGS. 4 and 5) and, on the other hand, three terminals 611 (FIGS. 1, 4 and 5). Inside the microswitch 600, each terminal 611 is connected to an internal contact element. Two of these internal contact elements are fixed while the third is mobile. This third contact element cooperates, on the one hand, with an internal compression spring which permanently returns it to a position of electrical contact with a first of the two other internal contact elements of the microswitch 600 and, on the other hand, with a control member 610 of the microswitch 600, which is adapted to move this third contact element to a position of electrical contact with the second internal contact element of the microswitch 600, against the action of the internal spring. The first internal contact element is said to be "normally closed" and the second internal contact element is said to be "normally open", with reference to their position relative to the third contact element in the rest position of the internal spring. The control circuit 900 is electrically connected on one side to one of the two terminals 611 connected to the first and second internal contact elements of the microswitch and the other to the terminal 611 connected to the third internal contact element of the microswitch. (Figures 11 to 14). Alternatively, it can be envisaged that the control circuit comprises a circuit portion connected to the terminals 611 connected to the first and third internal contact elements and another circuit portion connected to the terminals 611 connected to the second and third internal contact elements. The operation of the outlet is not changed. Here, the three terminals 611 and the control member 610 project from two opposite walls of a parallelepiped box 601 constituting the body of the microswitch 600 (Figures 1, 4 and 5). The three terminals 611 of the microswitch 600 are accessible through an opening 318 (FIGS. 1, 4 and 5) of the housing 310 for their electrical connection to the control circuit 900. According to the example described, the control member 610 of the microswitch 600 is a movable control pin in translation between two extreme positions. The control member 610 is permanently returned by the internal spring of the microswitch, acting on it via the third internal contact element, to a first extreme position which corresponds to the rest position of the internal spring of the microswitch. . In this first extreme position, the electrical circuit between the first and the third internal contact element of the microswitch 600 is closed and the electric current flows in this circuit. When acting on the control member 610 of the microswitch 600, it moves towards the second extreme position to bring the third internal contact element of the microswitch 600 in contact with the second internal contact element: the electrical circuit between the second and the third internal contact element of the microswitch 600 is then closed and the electric current flows in this circuit. When the action on the control member 610 ceases, it is automatically returned to its first extreme position by said internal spring of the microswitch 600. In the control circuit examples 900 shown in FIGS. 10 to 13, the The control circuit 900 is connected to the second and third internal contact elements of the microswitch 600. Thus, when no action is exerted on the control member of the microswitch 600, the control circuit 900 is open. When an action is exerted on the control member of the microswitch 600, the control circuit 900 goes into a closed state, the electric current flows in the control circuit 900, which constitutes the control signal. In the exemplary control circuit 900 of FIG. 14, the branch is inverted: the control circuit 900 is connected to the first and third internal contact elements of the microswitch 600. Thus, when no action is exerted on the control member of the microswitch 600, the control circuit 900 is closed. When an action is exerted on the control member of the microswitch, the control circuit 900 goes into an open state, the electric current no longer circulates in the control circuit 900, which constitutes the control signal. Here, in the case 310 of the auxiliary part 300 of the electrical socket 100, the microswitch 600 is arranged so that its control member 610 is adapted to cooperate with the pin 500 (FIGS. 4 and 5). More specifically, the first cylindrical housing 314 housing the pin 500 and the spring 510 opens into the parallelepipedal housing 313 housing the microswitch 600, so that the control member 610 of the microswitch 600 extends at least partially opposite this first cylindrical housing 314, in the path of the pin 500 when it is displaced in translation in the first cylindrical housing 314. The pin 500 is in the form of a rod having a first free end 501 front (Figures 1, 4 to 7) adapted to be introduced into said first cell 252, that is to say having dimensions, in particular a diameter and a length, adapted to its introduction into the first cell 252 of the electrical outlet 100. This first alveolus 252 may be indifferently one or the other of the two cells housed in the rear part of the base 210 of the main part 200 of the electrical outlet 100.

The pin 500 has a second free end 502 rear (Figures 1 and 4 to 7) of upper section to the section of the first free end 501. It has the shape of a hollow cylinder. The first free end 501 and the second free end 502 of the pin 500 are connected by a conical connection zone 503 in which the section of the pin 500 increases progressively (FIGS. 1 and 4 to 7). This conical connection zone 503 advantageously bears on the control member 610 to change it from a first stable state to a second stable state. The return means 510 of the pin 500 is here a helical compression spring, which is interposed between the second free end 502 of the pin 500 and a rear wall 314A of the housing 310 closing at the rear the first cylindrical housing 314 accommodating the pin 500 and the spring 510 (Figures 1 and 4 to 7). The spring 510 thus cooperates on the one hand with the free edge of this second free end 502 and on the other hand with the rear wall 314A of the first cylindrical housing 314 (FIGS. 1 and 4 to 7).

The pin 500 is adapted to slide axially in the first cylindrical housing 314 under the action of the spring 510. Thus, when the spring 510 is deployed (Figures 4 and 6), in the rest position of the pin 500, the spring 510 pushes back. the pin 500 to the front of the electrical outlet and the first end 501 of the pin 500 emerges in the first cell 252 of the electrical outlet 100. The base 210 of the main part 200 of the electrical outlet 100 has for this purpose a opening 213 adapted to the passage of the first free end 501 of the pin 500. This opening 213 of the bottom 211 of the base 210 is opposite the first cylindrical housing 314 of the housing 310 of the auxiliary portion 300 of the electrical outlet 100 and opens on said first cell 252 (Figures 4 to 7). In this rest position, the second end 502 of the pin 500 leaves part of the first cylindrical housing 314 and presses the control member 610 of the microswitch 600, which is therefore in its second extreme position. When the spring 510 is compressed (FIGS. 5 and 7), in the actuating position of the pin 500, the second end 502 of the pin 500 is housed inside the first cylindrical housing 314 and its first end 501 extends. opposite the control member 610 of the microswitch 600. This first end 501 having a smaller section than the section of the second end 502, it does not rest on the control member 610 which is brought back to its first position extreme by the action of the internal spring of the microswitch. Here, the actuation of the sensor 600 is to let the controller 610 take its first extreme position. It will be noted advantageously that, during its displacement in axial translation, the conical connection zone 503 of the pin 500 bears on the control member 610 to move or accompany the movement of this member 20 between its first and second extreme positions constituting two stable states of the control member 610. Advantageously, it should be noted that the detection medium can accommodate other sensors useful for the operation of the electrical outlet. Here, the second cylindrical housing 315 of the rear portion 311 of the housing 310 is open at the back. It houses for example the temperature sensor 700. It is connected to an electrical cable that leaves the housing 310 at the rear (Figure 1). The front portion 312 of the housing 310 covers the microswitch 600. It leaves free the front opening of the first and second cylindrical housing 314, 315. A cover member 319 is attached to the front face of the two cylindrical housings 314, 315 (FIG. 2). This cover member 319 at least partially closes the front opening of the second cylindrical housing 315 accommodating the temperature sensor 700, but leaves free the front opening of the first cylindrical housing 314 accommodating the pin 500, so as to allow the sliding of the pin 500 through this cover member 319 of the housing 310. The joining of the rear and front parts 311, 312 of the housing 310 further forms a receiving hole 316 of a fixing screw 400 allowing the attachment of the housing 310 on the face external base 211 of the base 210 of the main part 200 of the electrical outlet 100 (Figures 1 and 2). The bottom 211 of the base 210 of the main part 200 of the electrical socket 100 has for this purpose a threaded orifice 214 adapted to accommodate the fixing screw 400. The electrical plug 800 (Figures 4 to 9) conventionally comprises a generally cylindrical body 810 closed on one side by a plate 380 from which the connecting pins 840 emerge, and on the other side, by a connecting part through which enters into the body 810 of the electrical plug an electrical cable 820 connecting the electrical plug to an electrical appliance. In practice, as shown in Figures 4 and 6, when the pins 840 of the electrical plug 800 complementary to the electrical outlet 100 are not engaged in the cells 251, 252 terminals B1, B2 of the electrical outlet 100, through the openings 224 of the bottom of the receiving well 222 of this electrical outlet 100, the pin 500 is pushed towards the front of the electrical outlet 100 by the spring 510 and is then in its rest position.

As explained above, the first end 501 of the pin 500 then passes through the opening 213 of the bottom of the base 210 of the main portion 200 of the electrical outlet 100 and penetrates into said first cell 252 of the electrical outlet 100 (FIGS. 4 and 6) . In this rest position of the pin 500, the second end 502 of the larger section pin 500 rests on the control member 610 of the microswitch 600 which is in its second extreme position. The control circuit 900 of the electrical outlet 100 is then in an initial electrical state open (Figures 10 to 13) or closed (Figure 14). By blocking the control member 610 of the microswitch 600, the pin 500 then prevents the microswitch 600 from acting on said control circuit 900, that is to say, to change state. In other words, if the control circuit 900 is in the initial closed electrical state, the pin 500 prevents it from going into the open state, and if it was in the initial open state, the pin 500 prevents it from going into the closed state.

As shown in FIGS. 5 and 7, when the pins 840 of the electrical plug 800 complementary to the electrical socket 100 are engaged in the cells 251, 252 of the terminals B1, B2 of the electrical socket 100, the pin 500 is moved back to the rear of the electrical outlet 100 by one of the pins 840 of the electrical plug 800. The spring 510 is compressed and the pin 500 is then in its actuated position of the sensor 600. The first end 501 of the pin 500 crosses always the opening 213 of the bottom of the base 210 of the main part 200 of the electrical outlet 100 but it no longer emerges inside the first cell 252 (Figure 5) of the electrical outlet 100. In this position d ' actuation of the pin 500, it does not interact with the control member 610 of the microswitch 600 which is free to take its first extreme position under the action of the internal spring of the microswitch 600. The control circuit 900 of the socket electric 1 00 then changes electrical state. It goes into a closed state (Figure 10 to 13) or open (Figure 14). A control signal is thus generated. Finally, if the electrical plug 800 is removed from the electrical outlet 100, the spring 510 pushes the pin 500 forward of the electrical outlet 100 and the first end 501 of the pin 500 emerges again in the first cell 252. The pin 500 then forces the control member 610 of the microswitch 600 to move from its first extreme position to its second extreme position. The control circuit returns to its initial electrical state. During the passage of the pin 500 from its rest position to its actuating position, and vice versa, the control member 610 of the microswitch 600 slides on the conical connection zone of the pin 500. The control member thus passes easily. from its first extreme position to its second extreme position, and vice versa. Several examples of control circuit 900 are shown in FIGS. 10 to 14. In these diagrammatic views, the pin 500 is schematized by a triangle, like a mechanical actuator. The sensor 600 is schematically represented by a switch and the action of the pins 840 of the electrical plug 800 on the sensor 600 through the pin 500 is shown in dashed lines.

In Fig. 10, the control circuit 900 includes a device programmed to control an automated process. This is for example a charging station of an electric vehicle. When the pins of the electrical plug 800 are inserted into the electrical outlet 100 according to the invention, thanks to the arrangement described above, the electrical outlet 100 detects this insertion and the sensor 600 sends a control signal corresponding to the passage of the current in the control circuit 900. This control signal is taken into account as an input signal of the device programmed to control the charge of the electric battery of the vehicle.

It is thus possible to trigger a charging process of the battery automatically when the plug connected to this battery is inserted into the electrical socket according to the invention. In FIG. 11, the control circuit 900 comprises a relay 910 arranged to control the closing of contacts 920 arranged on the supply circuit of the electrical outlet 100. When the pins of the electrical plug 800 are inserted into the electrical outlet 100 according to the invention, thanks to the arrangement described above, the electrical socket detects this insertion and the sensor 600 sends a control signal corresponding to the passage of the current in the control circuit 900. The passage of the current in the relay 910 causes the closure of the contacts 920 and therefore allows the power supply of the electrical outlet 100. It is thus possible to limit the supply of the electrical outlet only when the electrical plug 800 is inserted into the electrical outlet 100 according to the invention.

FIGS. 12 and 13 show control circuits making it possible to associate the power supply of an electrical appliance with the insertion of the pins 840 of the electrical plug 800 into the electrical socket 100. In FIG. 12, the control circuit 900 comprises a 950 indicator light. This illuminates only when the control signal indicates that the control circuit is closed. The powering on of the indicator light is here directly linked to the insertion of the pins of the electric plug into the socket. In FIG. 13, the control circuit comprises a relay 910 and a contact 940 actuated by this relay 910 and controlling the supply of a circuit comprising an electrical apparatus, here for example a 950 indicator light.

When the pins of the electrical plug 800 are inserted into the electrical outlet, the current flows through the relay, which controls the closing of the contact 940 and the indicator lights up. The lighting of the indicator light 950 is here indirectly related to the introduction of the pins 840 of the electrical plug 800 into the electrical outlet 100 via the relay 910. FIGS. 12 and 13 show diagrammatically a light indicator, but we can obviously consider controlling the power of any electrical device such as a motor, a fan 960 or a sound alarm 970 for example, as shown on the side of Figures 12 and 13.

In FIG. 14, the control circuit 900 comprises an electric lock 980. The supply of this electric lock 980 is here cut off when the electric plug 800 is inserted into the electrical socket 100 according to the invention. The electrical socket according to the invention made according to the embodiment described above has the advantage of a high stability of operation and therefore of maximum safety. Activation of the microswitch control member is here performed only when the plug is inserted into the electrical outlet. According to a simplified embodiment of the electrical socket, it can however be envisaged that the control member of the microswitch also plays the role of the pin described above. The internal spring of the microswitch then acts as the means for returning the pin to its rest position in which it emerges in the cell of the socket. The actuation of the sensor here consists of a displacement of the control member of the microswitch, which acts directly on the state of the control circuit. Indeed, it suffices for this to position the microswitch in the auxiliary part of the electrical socket so that the control member, which is here a control pin, extends in the axis of the cell of the electrical outlet. The electrical outlet is thus simplified and simply carried out economically. The overall operation of the electrical outlet is not changed. However, compared with the description made above, it will be noted that the control signal generated by the depression of the electrical plug is reversed: the control member is then in its first extreme position when the electric plug is not inserted. in the socket and in its second extreme position when the plug is inserted into the socket. It is then possible to modify the connection of the control circuit by modifying the terminals used of the microswitch to obtain the same operation as previously.5

Claims (13)

REVENDICATIONSI. Electrical socket (100) having two electrical connection terminals (B1, B2) each provided with a socket (251, 252) for insertion, at the front of the electrical socket (100), of a connection pin (840) of an electrical plug (800), as well as electrical control means, characterized in that the electrical control means comprise, on the one hand, a sensor (600) adapted to act on an electrical control circuit (900) for generating a control command, and, secondly, a single pin (500) displaceable in translation, against an elastic return means (510), along the axis of a first (252) of the two cells, from a first rest position in which the pin (500) emerges in said cell (252), to a second actuating position in which the pin (500) is moved backwards from the electrical outlet (100) and actuates the sensor (600) to act on said control circuit (900). 2. Electrical socket (100) according to claim 1, wherein said sensor (600) is a microswitch comprising a control member (610) separate from said pin (500) and adapted to cooperate therewith. An electrical socket according to claim 1, wherein said sensor is a microswitch comprising a controller constituting said pin. 4. Electrical socket (100) according to one of the preceding claims, wherein the sensor (600), the pin (500) and the elastic return means (510) of the pin (500) are housed in a detection medium secured to the rear face of a base (210) of said electrical outlet (100), outside of this base (210). 25 An electrical receptacle (100) according to claim 4, wherein said detection medium comprises an insulating housing (310) which partially surrounds said sensor (600), said pin (500) and said biasing means (510) and includes mounting means (316) on said base (210) of the electrical outlet (100). The electrical socket (100) of claim 5, wherein said mounting means includes an orifice (316) for passage of a fixing screw (400). The electrical socket (100) according to claim 2, wherein said means (510) for returning the pin (500) to its first rest position comprises a spring (510) interposed between said pin (500) and a rear wall ( 314A) of said housing (310) insulator. 8. Electrical outlet according to claim 3, wherein said means for returning the pin to its first rest position comprises a spring interposed between a microswitch element adapted to cooperate with said pin and a wall of an insulating box of said microswitch. 9. Electrical socket (100) according to one of the preceding claims, wherein said socket (100) having a base (210) comprising a bottom (21) from which rises four side walls (212), an opening through (213) is formed in the bottom (211) of this base (210), vis-à-vis said first cell (252), so as to allow the passage of a portion of said pin (500) through this through opening (213), from the outside of the base (211) to the inside of the base, in said first cell (252). 10. Electrical socket (100) according to one of the preceding claims, wherein said electrical control circuit (900) comprises an electrical supply circuit of the electrical outlet (100), and wherein the control command authorizes the power supply of this electrical outlet (100). An electrical socket (100) according to one of the preceding claims, wherein said electrical control circuit (900) comprises an electrical supply circuit of an electrical apparatus (950) separate from said electrical outlet (100), and wherein said control command allows the power supply of this electrical equipment (950). 12. Electrical socket (100) according to one of the preceding claims, wherein said electrical control circuit (900) comprises an electrical relay (910), and wherein said control command allows the passage of an electric current in it. electrical relay (910). 13. Electrical socket according to one of the preceding claims, wherein said electrical control circuit comprises an electrical circuit for power supply of an electrical accessory and wherein the control command stops the power supply of this electrical accessory.