FR2953660A1 - ELECTRIC POWER GENERATING DEVICE AND REMOTE CONTROL COMPRISING SUCH A DEVICE - Google Patents

Abstract

An electric power generating device (1) comprising a ferromagnetic yoke (3) forming two magnetic circuits provided with a common part (5), movable parts (21, 22) pivotally mounted and respectively associated with the one and the other of said magnetic circuits, permanent magnets (31, 32) integral with said moving parts, a control mechanism coupled between said moving parts and control means (45), and an electric coil (41) wound around said common part, said movable parts being coupled to a connecting piece (51) driven by drive means of said control mechanism for simultaneously moving one of said moving parts in the closed position and the other of said moving parts in the open position. A remote control (201) comprising such a generator device.

Description

TECHNICAL FIELD OF THE INVENTION The invention relates to the field of electricity generating devices and remote controls provided with such generating devices for electrically powering remote control means by the maneuvering device. an actuator of said remote control. The invention is particularly adapted to small wall remote controls, for example remote controls replacing conventional wall switches to control the opening and closing of switch means that have been deported relative to said remote control. The invention particularly relates to an electrical energy generating device comprising: a ferromagnetic yoke forming two magnetic circuits provided with a common part to said magnetic circuits and branches carrying closure ends of said magnetic circuits, respectively moving parts associated respectively at one and the other of said magnetic circuits, each movable part being movable to open or close the magnetic circuit to which said movable part is associated by cooperating with the closing ends of said magnetic circuit, permanent magnets secured to said parts mobile and biased to circulate a magnetic flux in said common part in one direction or the other depending on the position of said moving parts, a control mechanism coupled between said movable parts and control means of said device for moving said moving parts in a p opening or in a closed position, and an electric coil wound around said common part to provide electrical energy during the movement of said moving parts. The invention also relates to a remote control for remotely controlling deported means. , said remote control comprising an operating member and an electrical energy generating device for supplying said remote control. STATE OF THE ART Patent application DE 198 52 70 describes an electric energy generator comprising magnetic circuits, electric coils wound around portions of said circuits for supplying electrical energy by variation of the magnetic field in said circuits, and permanent magnets for applying magnetic fields in said circuits, said magnets being integral with a translatable axis and disposed along said axis having alternating polarities so that electric energy is generated by a change in the relative position of said magnets when moving the axis. A disadvantage of the electrical energy generator of the prior art is that it has a number of permanent magnets greater than the number of magnetic circuits. As a result, this type of generator is bulky, particularly as regards its size along the axis of movement of the magnets. DISCLOSURE OF THE INVENTION The invention aims at remedying the drawbacks of the generators of the prior art by proposing an electric energy generating device comprising: a ferromagnetic yoke forming two magnetic circuits provided with a part common to said magnetic circuits and branches carrying closure ends of said magnetic circuits, movable parts respectively associated with one and the other of said magnetic circuits, each movable part being movable to open or close the magnetic circuit to which said movable part is associated cooperating with the closing ends of said magnetic circuit, permanent magnets integral with said moving parts and biased to circulate a magnetic flux in said common part in one direction or the other depending on the position of said moving parts, a coupled control mechanism between said moving parts and means s of controlling said device for moving said movable parts in an open position or in a closed position, and an electric coil wound around said common part for supplying electrical energy when moving said moving parts, said characterized in that each movable portion is pivotally mounted to open or close the magnetic circuit to which it is associated by tilting said movable portion, said movable portions being coupled to a connecting piece driven by driving means of said mechanism control for simultaneously moving one of said moving parts in the closed position and the other of said moving parts in the open position. Preferably, the control mechanism comprises, for each mobile part, a lever pivotally mounted about an axis, said lever being provided with a first arm secured to said movable part and a second arm coupled to the piece of connection by a pivotal connection. Advantageously, the movable part comprises an abutment face intended to rest against a stopper in the closed position of said movable part. According to one embodiment, the connecting piece is coupled to the drive means by elastic means for applying a restoring force opposing a magnetic attraction force exerted on each movable part by the closing ends of the circuit. magnetic means to which said movable portion is associated, said elastic means being arranged to allow, during driving of said connecting piece, the sudden tilting of said moving parts when the attraction force exerted by an initially open mobile part becomes greater than said restoring force. Preferably, the elastic means comprise a torsion spring acting on the connecting piece to allow the sudden tilting of the moving parts.

According to one embodiment, the drive means comprise a rod coupled to the connecting piece for translating said connecting piece parallel to a control shaft. Preferably, the control means are pivotally mounted around the control shaft, the drive means being designed to transform the pivoting of said control means in translation of the rod. Advantageously, the drive means comprise a movable piece secured to the control means and coupled to the rod for driving said rod in translation, said movable piece being pivotally mounted around the control shaft and provided with a cooperating cam surface. with a complementary cam surface of a fixed part to transform the pivoting of said control means in translation of said rod. Advantageously, the drive means comprise return means acting on the rod to keep said rod in contact with the moving part. According to one embodiment, the ferromagnetic yoke has the shape of an "H" provided with a central bar corresponding to the common part.

The invention also relates to a remote control for remotely controlling remote means, said remote control comprising an operating member and an electrical energy generating device for supplying said remote control, characterized in that the generating device is as previously described, said device having control means coupled to said actuator.

BRIEF DESCRIPTION OF THE FIGURES Other advantages and features will emerge more clearly from the following description of particular embodiments of the invention, given by way of non-limiting examples, and represented in the appended figures. Figure 1 is a perspective view of an embodiment of the generating device 25 according to the invention. FIG. 2 is an exploded view of a remote control comprising the generating device represented in FIG. 1. FIG. 3 is a perspective view of the remote control shown in FIG.

Figure 4 is a sectional view of the remote control shown in Figure 3, wherein the actuating member is in a first position. Figure 5 is a top view of the generator device of the remote control shown in Figure 4, wherein the actuator is in a first position.

Figure 6 is a sectional view of the remote control shown in Figure 3, wherein the actuator is in a second position. Figure 7 is a top view of the generator device of the remote control shown in Figure 6, wherein the actuator is in a second position. DETAILED DESCRIPTION OF AN EMBODIMENT With reference to FIGS. 1 and 2, the electrical energy generating device 1 comprises a base 2 on which is disposed a ferromagnetic yoke 3 having the shape of an "H" provided with a bar central 5. In the ferromagnetic yoke 3 are formed two magnetic circuits having a common portion corresponding to the central bar 5. A first magnetic circuit is formed by the common part 5 and the branches 11, 12 respectively carrying closing ends 13, 14 said magnetic circuit. A second magnetic circuit is formed by the common part 5 and the branches 15, 16 respectively carrying closure ends 17, 18 of said magnetic circuit. The generator device 1 comprises a first movable portion 21 and a second movable portion 22 respectively associated with the first magnetic circuit 5, 11, 12 and the second magnetic circuit 5, 15, 16 described above. Each movable portion 21, 22 is movable to close the magnetic circuit with which it is associated by cooperating with the closing ends 13, 14, 17, 18 of said magnetic circuit. In this case, the first and second movable parts 21, 22 are pivotally mounted about an axis of rotation respectively referenced 25, 26 respectively to open or close the first magnetic circuit 5, 11, 12 and the second magnetic circuit 5 , 15, 16. The generating device 1 comprises permanent magnets 31, 32 integral with said moving parts 21, 22. These magnets are polarized to circulate a magnetic flux in the common part 5, in one direction or the other, according to the position of said moving parts. More specifically, each movable portion 21, 22 comprises a first air gap face 34, 38 and a second air gap face 33, 37 cooperating respectively with a first complementary air gap face 84, 88 of the closure ends 14, 18 of the first magnetic circuit 5, 11, 12 and a second complementary gap face 83, 87 of the closing ends 13, 17 of the second magnetic circuit 5, 15, 16. The permanent magnets 31, 32 are polarized so as to generate, when either of the movable parts 21, 22 is in a closed position, a magnetic field inside the magnetic circuit to which said moving part is associated. Depending on the direction of polarization of the magnets, the magnetic flux flowing in the common part 5 is oriented in one direction or the other. In this case, the permanent magnets 31, 32 are oriented to circulate a magnetic flux in the common part 5 in one direction, when a movable part 21, 22 is in a closed position, and in an opposite direction, when the other movable part 22, 21 is in a closed position. The generation of electrical energy is provided by an electric coil 41 wound around said common part 5 of the magnetic circuits. When the moving parts 21, 22 are moved from one position to the other, the magnetic flux generated in said common part changes direction, and the resulting variation in magnetic flux makes it possible to generate an electric current in the coil 41. moving the movable parts 21, 22 from their open position to their closed position, in one direction or the other, the generating device comprises a control mechanism coupled between said moving parts and control means of said device, in the occurrence of a tab 45 pivotally mounted about an axis 46. In the embodiment shown in Figures 1 and 2, the movable portions 21, 22 are coupled to a connecting piece 51 driven by drive means of said control mechanism. This connecting piece 51 makes it possible to simultaneously move a mobile part 21, 22 in the closed position and the other mobile part 22, 21 in the open position or vice versa. In this way, only one of the magnetic circuits is closed, and the opening of this magnetic circuit is accompanied by the closing of the other magnetic circuit with an inversion of the magnetic flux flowing in the common part 5 of said magnetic circuits. In this configuration, only one permanent magnet is associated with each magnetic circuit which reduces the size of the generating device, in particular with respect to generators of the prior art using a number of permanent magnets greater than the number of magnetic circuits. the prior art, this configuration also increases the distance between each magnet, which limits any disturbance of the magnetic flux generated by a portion of the magnets by the other part of said magnets. This configuration also makes it possible to improve the guidance of the magnetic materials with respect to the guidance obtained in the generators of the prior art, which often requires control of the parallelism of the gap surfaces and the obtaining of minimum gap distances. . As can be seen in FIGS. 1 and 2, the control mechanism comprises, for each movable portion 21, 22, a lever 61, 62 pivotally mounted about the axis 25, 26, said lever being provided with a first arm 63, 64 secured to said movable portion and a second arm 67, 68 coupled to the connecting piece 51 by pivotal connections 69. The permanent magnet 31, 32 of each movable portion 21, 22 is fixed in a formed insert in the first arm 63, 64 of the lever 61, 62. The displacement of each movable part 21, 22 is limited, in the closed position of said movable part, by a stopper 75, 76 disposed on the base 2, said stopper being intended to cooperate with an abutment face formed on the magnet 31, 32 of said movable part. The abutment faces of the moving parts 21, 22 being distinct from the first and second gap faces 33, 34, 37, 38, the wear of said gap faces is limited. As can be seen in FIGS. 1 and 2, the second air gap face 33, 37 of the closing ends and the second complementary air gap face 83, 87 of the moving parts 21, 22 have complementary profiles allowing closure of said mobile part without direct contact between said gap faces. In this way, the second gap face 33, 37 and the second complementary gap face 83, 87 do not undergo wear, and the distance between said gap faces is kept constant. It follows that the distances between the gap between, on one side, the first and the second air gap face 33, 34, 37, 38 of each movable part 21, 22 and, on the other side, the first and the second complementary gap face 83, 84, 87, 88 of the closing ends of the magnetic circuits are kept constant, which gives the generator device a good reliability. As can be seen in FIGS. 1 and 2, the drive means comprise a rod 101 slidably mounted on the base 2, said rod being coupled to the connecting piece 51.

This rod 101 makes it possible to translate the connecting piece 51 in translation parallel to a control axis corresponding to the axis of translation of the rod. The coupling between the connecting piece 51 and the rod 101 is made by elastic means, in this case a torsion spring 103. This spring 103 acts on the connecting piece 51 to allow its movement parallel to the control axis . More specifically, the spring 103 is arranged to apply a restoring force opposing a magnetic attraction force exerted on each movable part 21, 22 by the closing ends 13, 14, 17, 18 of the magnetic circuit to which said part mobile is associated. The spring 103 thus allows, during the driving of the connecting piece 51 by means of the rod 101, to obtain a sudden displacement of said connecting piece 51 with respect to said rod, when the force of attraction exerted on the moving part initially opened becomes greater than the restoring force. This sudden displacement of the connecting piece 51 relative to the rod 101 is accompanied by a sudden tilting of the moving parts 21, 22 to obtain a rapid inversion of the magnetic flux in the common part 5 of the magnetic circuits. It results from this rapid variation of the magnetic flux, the generation of an electric current in the coil 41 whose intensity is all the more important that the speed of variation of said flow is large. The generator device 1 thus makes it possible to generate a greater electrical energy than the generators of the prior art. In the embodiment shown in FIGS. 1 and 2, the drive means comprise a mobile part 111 rotatably mounted about the axis 46, said movable part being integral with the control means, that is to say the rotary lug 45. The drive means further comprise a fixed part 113 comprising a cam surface cooperating with a complementary cam surface of the movable part 111 to transform the pivoting of said mobile rotating part in translation parallel to the axis. 46 or the axis of translation of the rod 101. The movable part 111 is supported on one end of the rod 101, which allows to drive it in translation. The axis 46 can be called a control axis. Return means, in this case a spring 115, act on the other end of the rod 101 to maintain said rod in contact with the moving part 111. With reference to FIGS. 2 and 3, the remote control 201 makes it possible to control distance means not shown deportees, in this case means having two control states, such as a switch having an open position and a closed position. The remote control 201 corresponds to a wall remote control for remote switch means, said remote control having a relatively flat shape. The remote control 201 comprises an operating member 203 for remote actuation of the remote switch means in one or the other of the control states.

In order to supply the remote control means with electrical energy, the remote control 201 comprises a generator device 1 as described above, said device being disposed below the operating member 203. As has been described above, the generating device 1 comprises control means consisting essentially of the tab 45 rotatably mounted about the axis 46. The actuating member 203 is, in turn, pivotally mounted on the pins 207, 209 and cooperates with the tab 45 to make it pivoting about the control axis 46. In the embodiment shown, the control means 45 of the generating device are coupled to the operating member 203 by a protuberance 205 secured to said operating member and whose end is in pressing on the tab 45 to rotate it during the operation of said member.

The operation of the remote control 201 and the generator device 1 is detailed in the following with reference to FIGS. 4 to 7. In order to visualize the state of the elements of the generator device 1, the operating member 203 has been deleted in the figures 5 and 7. Initially, the remote control 201 is in the first position shown in FIGS. 4 and 5. In this first position, the operating member 203 has not been tilted about the axes 207, 209, and the tab 45 is held in an initial position corresponding to a position of the rod 101 and the connecting piece 51 towards the right part of FIG. 5. In this position of the connecting piece 51, the lever 62 is positioned to hold the moving part 22 in a closed position of the magnetic circuit with which it is associated, that is to say the magnetic circuit consisting essentially of the common part 5 and the branches 15, 16 of the ferromagnetic yoke. Meanwhile, in this position of the connecting piece 51, the lever 61 is positioned to maintain the movable portion 21 in an open position of the magnetic circuit with which it is associated, that is to say the magnetic circuit consisting essentially of the common part 5 and the branches 11, 12 of the ferromagnetic yoke. In this position of the moving parts 21, 22, a magnetic flux flows in the magnetic circuit 5, 15, 14, and in particular in the common part 5 in a first direction. As a result, a magnetic attraction force is exerted on the movable portion 22 by the closing ends 17, 18 of the branches 15, 16. The spring 103 exerts, for its part, a restoring force opposing this magnetic attraction force, but this restoring force is not sufficient to move the movable portion 22 to its open position. During the operation of the operating member 203 between the first position shown in Figure 4 and the second position shown in Figure 6, the tilting of said actuator is accompanied by pivoting of the tab 45 and a displacement in translation of the rod 101 and the connecting piece 51 towards the left part of FIG.

During this displacement in translation of the connecting piece 51, the lever 62 is tilted so as to move the movable portion 22 from its initial closed position to an open position of the magnetic circuit 5, 15, 16 with which it is associated. Meanwhile, the lever 61 is tilted so as to move the movable portion 21 from its initial open position to a closed position of the magnetic circuit 5, 11, 12 with which it is associated.

During the movement of the moving parts 21, 22, the magnetic attraction force exerted on the movable portion 22 decreases while the magnetic attraction force exerted on the movable portion 21 increases. When the value of the magnetic attraction force exerted on the movable part 21 becomes equal to the restoring force exerted by the spring 103 on said moving part, a dead point is reached. Beyond this dead point, the connecting bar 51 moves abruptly in translation towards the left part of FIGS. 5 and 7 with respect to the rod 101, which makes it possible to accelerate the tilting of the moving parts 21, 22. the end of the operation of the operating member 203, the remote control 201 is in the second position shown in Figures 6 and 7. In this second position, the operating member 203 has been tilted about the axes 207, 209. The rod 101 and the connecting piece 51 have been moved towards the left part of FIG. 5. The lever 62 has been tilted so as to keep the mobile part 22 in an open position of the magnetic circuit 5, 15, 16 to which it is associated, and the lever 61 has been tilted so as to maintain the movable portion 21 in a closed position of the magnetic circuit 5, 11, 12 with which it is associated. In this position, the magnetic flux flowing in the magnetic circuit 5, 15, 14, and in particular in the common part 5, has been reversed in a second direction opposite to the first direction of said flow. This inversion of the magnetic flux during the maneuvering of the operating member 203 between the first and the second position has thus made it possible to generate an electric current in the coil. Moreover, the sudden acceleration of the tilting of the moving parts 21, 22 during the maneuvering of the operating member 203 between the first and the second position has made it possible to obtain a faster variation of the magnetic flux, which is therefore accompanied by an increase in the electrical energy generated in the coil. At the end of the maneuver of the operating member 203, the magnetic attraction force exerted on the movable portion 21 by the closing ends 13, 14 of the branches 11, 12 is maximum. The spring 103 exerts, for its part, a restoring force opposing this magnetic attraction force, but this restoring force is not sufficient to move the movable part 21 in an open position. Maneuvering the operating member 203 between the second position and the first position makes it possible to move the mobile part 21 from its closed position to its open position and the movable part 22 from its open position to its position of closing.

This operation to move from the second position to the first position is substantially identical. The acceleration of the tilting of the moving parts 21, 22 is done by the passage of a dead point, beyond which the magnetic attraction force exerted on the movable part 22 becomes greater than the restoring force exerted by the spring 103. Thus, the generating device 1 is reversible, that is to say that it allows the generation of the same amount of energy when controlling the control means 45 in one direction or the other. In the operation presented above, it is indicated that the operating member 203 can be tilted between the first and the second position, in one direction or the other. The operating member 203 may be coupled to not shown return means 30 for returning said member to its first position, as soon as the user releases said member. In other words, the first position of the operating member 203 and the elements of the generating device 1 shown in FIGS. 4 and 5 correspond to a stable position, and the second position of the operating member 203 and said elements. of the generating device 1 shown in Figures 6 and 7 corresponds to an unstable position.

Thus, by pressing the operating member 203 once, the inversion of the magnetic flux in the common part 5 of the magnetic circuits occurs twice in succession. The amount of electrical energy is multiplied by two. The generating device according to the invention has the advantage of being bulky, which allows its implementation in remotes thin. The generator device is therefore quite suitable for installation in a wall-mounted remote control having a flat shape. The use of a control mechanism making it possible to obtain a sudden displacement of the moving parts and permanent magnets integral with said moving parts makes it possible to increase the speed of variation of the magnetic flux generated in the common part of the magnetic circuits, and electrical energy generated by variation of said flow is all the more increased.

Claims (11)

REVENDICATIONS1. Electric energy generating device (1) comprising: a ferromagnetic yoke (3) forming two magnetic circuits provided with a common part (5) to said magnetic circuits and branches (11, 12, 15, 16) carrying ends closure (13, 14, 17, 18) of said magnetic circuits, moving parts (21, 22) respectively associated with one and the other of said magnetic circuits, each movable portion being movable to open or close the magnetic circuit to which said moving part is associated cooperating with the closing ends of said magnetic circuit, permanent magnets (31, 32) integral with said movable and polarized parts to circulate a magnetic flux in said common part in one direction or the other in function of the position of said moving parts, a control mechanism coupled between said movable parts and control means (45) of said device for moving said movable parts; movable in an open position or in a closed position, and an electric coil (41) wound around said common part to provide electrical energy during the displacement of said moving parts, characterized in that each moving part is pivotally mounted to open or close the magnetic circuit to which it is associated by tilting said movable part, said movable parts being coupled to a connecting piece (51) driven by driving means of said control mechanism to simultaneously move the one of said moving parts in the closed position and the other of said moving parts in the open position. 2. Device according to claim 1, characterized in that the control mechanism comprises, for each movable part (21, 22), a lever (61, 62) pivotally mounted about an axis (25, 26), said lever being provided with a first arm (63, 64) secured to said movable portion and a second arm (67, 68) coupled to the connecting piece (51) by a pivotal connection (69). 1330 3. Device according to claim 2, characterized in that the movable part (21, 22) comprises an abutment face intended to rest against a stopper (75, 76) in the closed position of said movable part. 4. Device according to any one of claims 1 to 3, characterized in that the connecting piece (51) is coupled to the drive means by elastic means (103) for applying a restoring force opposing a magnetic attraction force exerted on each movable portion (21, 22) by the closing ends (13, 14, 17, 18) of the magnetic circuit to which said moving part is associated, said elastic means being arranged to allow, during the driving said connecting piece, the sudden tilting of said moving parts when the attraction force exerted by an initially open movable portion becomes greater than said restoring force. 5. Device according to claim 4, characterized in that the elastic means comprise a torsion spring (103) acting on the connecting piece (51) to allow the sudden tilting of the movable parts (21, 22). 6. Device according to any one of claims 1 to 5, characterized in that the drive means comprises a rod (101) coupled to the connecting piece (51) for translating said connecting piece parallel to an axis. control (46). 7. Device according to claim 6, characterized in that the control means (45) are pivotally mounted around the control shaft (46), the drive means being designed to transform the pivoting of said control means (45). ) in translation of the rod (101). 8. Device according to claim 7, characterized in that the drive means comprise a movable part (111) integral with the control means (45) and coupled to the rod (101) for driving said rod in translation, said moving part (111) being pivotally mounted about the control shaft (46) and provided with a cam surface cooperating with a complementary cam surface of a fixed part (113) to transform the pivoting of said control means in translation of said rod. 9. Device according to claim 8, characterized in that the drive means comprise return means (115) acting on the rod to maintain said rod in contact with the movable part (111). 10. Device according to any one of claims 1 to 9, characterized in that the ferromagnetic yoke has the shape of an "H" provided with a central bar corresponding to the common part. 11. Remote control (201) for remotely controlling remote means, said remote control comprising an operating member (203) and an electric power generating device (1) for supplying said remote control, characterized in that the generating device is in accordance with FIG. any of the preceding claims, said device having control means (45) coupled to said actuator (203).