FR2813688A1 - Two entry door bell having motor/coil with moving central section/outer strips with one door bell sound modification changing force frequency magnetic field applied. - Google Patents

Abstract

The two entry door bell has a motor (8) and coil (10) with a moving central section (12) and two outer strips (4,6). Each button push sounds the bell. A unit (16) modifies the frequency of the force set up by the applied magnetic field.

Description

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The present invention relates to an electromagnetic door chime with two inputs.

An electromagnetic door chime generally includes a motor acting on two separate blades. The motor has a coil in the center of which is a core which oscillates when the motor is supplied with alternating electric current. The two blades are placed on either side of the motor and are each substantially perpendicular to the direction of oscillation of the core.

When a house, or any other room, has two separate entrances, it is preferable to be able to differentiate the sound generated by the chime when a visitor arrives at one or the other of the entrance doors.

A first solution consists in using two entirely distinct chimes and generating different sounds at the two entrances. However, there are also chimes that can be actuated by two push buttons placed in different places, each of the push buttons generating a different sound. Such chimes generally comprise two motors and a stop limiting the stroke of the core of one of the motors. When the first motor is activated, its core successively hits the two blades and produces a "ding-dong". When the second motor is activated, its core strikes only one blade and is subsequently stopped by the stop. The second engine therefore produces only a "ding".

The known devices of the prior art are expensive because, although using a common housing, they require the presence of two complete motors and the installation of a stopper.

The present invention therefore aims to provide an electromagnetic door chime which can be actuated by two push buttons placed in different places, each of the push buttons generating a different sound, at a lower cost price than chimes of this type of l prior art. Advantageously, this chime uses only one motor.

To this end, the chime it offers is an electromechanical door chime with two inputs, comprising a motor having a coil and a movable core, and two blades arranged on either side of the motor, two

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 push buttons being associated with the chime.

According to the invention, one of the push buttons is connected to the chime by means of a device making it possible to modify the frequency of the force generated by the magnetic field acting on the mobile core.

In this way, it is possible to vary the frequency of the force generated by the magnetic field so that it approximates the natural mechanical frequency of oscillation of the mobile core. The excitation frequency of the nucleus then being closer to the natural frequency of the mechanical oscillating system, the amplitude of the oscillations will be greater. It then suffices to place a blade so that at each large amplitude oscillation corresponding to the modified frequency the core strikes the blade while for an amplitude corresponding to an unmodified frequency, the blade is not reached. In this way, the action on the push button associated with the device allowing the frequency to be adjusted causes a ringing sound while the action on the other push button causes a chime sound.

This solution allows the use of a single engine.

In a preferred embodiment, the device making it possible to modify the frequency of the force generated by the magnetic field comprises a diode and divides this frequency by two. This solution has the great advantage of being of a low cost price.

In the case where the device making it possible to modify the frequency of the force generated by the magnetic field influences the power of the motor, means making it possible to reduce the power of the motor when the second push button is actuated are advantageously provided in order to have a substantially identical power when you act on one or the other of the push buttons. The sound intensity of the sound generated by the chime is then the same regardless of the push button pressed. A preferred embodiment provides that the device making it possible to reduce the power of the motor comprises a resistance. This solution has the advantage of being of a low cost price.

To reduce the power of the motor, it can also be provided that the coil is a coil with two inputs, a first input making it possible to obtain

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 the maximum power of the coil being connected to the first push button while the second input allowing a reduced power to be obtained is connected to the second push button.

The description which follows will allow, with reference to the appended drawing, to better understand the aims and advantages of the invention. It is clear that this description is given only by way of example and is not limiting.

Figure 1 is a perspective view of a two-entry chime according to the invention, without cover, Figure 2 is an electrical diagram showing a first embodiment of a chime according to the invention, and Figure 3 is a corresponding diagram in the diagram of Figure 2 for an alternative embodiment.

In Figure 1 is shown a chime according to the invention. This chime comprises a base 2 in which there are two blades 4 and 6 as well as a motor 8. Conventionally, the base has a parallelepiped shape and the blades 4 and 6 are arranged on the longitudinal edges thereof. The motor 8 is located between the two blades 4, 6. This motor notably comprises a coil 10 and a core 12. In FIG. 1, for the sake of clarity, only the carcass of the coil 10 has been shown and not its winding . A spring 14 is provided to return the core 12 to its rest position. Such a structure is already known to those skilled in the art. When a current crosses the coil, a force is exerted on the core tending to move the latter longitudinally relative to the coil. The blades 4 and 6 are arranged perpendicular to the direction of movement of the core.

In Figure 1, there is also a diode 16, a resistor 18, both mounted on a printed circuit 20. Here, three connection terminals 22 are provided to allow the connection of the chime to two pushbuttons not shown. Electrical contacts 24 electrically connect the printed circuit 22 to the motor 8.

Figure 2 shows the electrical diagram of the chime shown in Figure 1. We recognize on this electrical diagram the coil 10, the resistor 18 and the diode 16. On this electrical diagram are also represented the buttons

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 pushbuttons 26 and 28. The carillon itself is shown diagrammatically by a dotted rectangle. It is supplied with electrical energy from a voltage source 30 and possibly from a transformer 32.

Note in the diagram of Figure 2 that the first push button 26 is mounted in series with the diode 16 while the second push button 28 is mounted in series with the resistor 18. The coil 10 is mounted in series with this assembly.

The operation of the device shown is then as follows. The chime is supplied with alternating current with a frequency of 50Hz. When the first push button 26 is actuated, the coil 10 is in series with the diode 16. The latter rectifies the sinusoidal supply signal of the coil 10 in simple alternation. The frequency of the force generated by the magnetic field which, without diode is 100Hz, is then divided by two. This generates at the core 12 a mechanical oscillation of great amplitude when the push button 26 is kept pressed. This oscillation allows the movable core 12 to periodically strike the blade 6 and thereby generate a striking effect. When the action on the push button 26 ceases, the spring 14 recalls the core in its rest position and the core then strikes once the blade 4. The sound then generated by the chime is of the "ddng-dong" type.

The presence of the diode 16 makes it possible, as indicated above, to decrease the frequency of the force generated by the magnetic field acting on the core 12. This reduction in frequency makes it possible to have a frequency of the force generated by the magnetic field more close to the natural frequency of oscillations of the core + spring system. As a result, the amplitude of movement of the core 12 increases. Of course, the blade 6 is arranged so that the core strikes the blade 6 at each oscillation. This is how the ringing effect is created.

When a user actuates the second push button 28, the coil 10 is in series with the resistor 18. The latter makes it possible to attenuate the power of the motor 8. In this way, the core 12 comes to strike a first and only time the blade 6 but remains away from it when the core 12 oscillates around its equilibrium position. When the push button 28 is pressed

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 is released, the electrical circuit is cut and the core 12 is returned to its rest position by the return spring 14. At this time, the core 12 strikes the blade 4. Thus, the sound generated by the chime when a pressure is exerted on the push button 28 is of the "ding-dong" type.

Of course, the distance between the core 12 when the latter is at rest and the blade 6 is such that a striking effect is produced when the first push button 26 is actuated and produces a chime effect when the second push button 28 is activated. This is achievable because in the first case the amplitude of oscillation of the core 12 is increased while in the second case the power of the motor is attenuated by the resistance. FIG. 3 shows an alternative embodiment of the chime represented in FIGS. 1 and 2. Here, the coil 10 is a coil with two inputs. A first input, connected to the first push button 26, makes it possible to obtain maximum power from the motor 8. Only a portion of the turns of the coil are then crossed by the electric current. The second input is connected to the second push button 28. It allows only reduced power from the motor 8. All the turns of the coil 10 are then traversed by the current. We also find here the voltage source 30 and possibly the transformer 32. The diode 16 is here also mounted in series with the first push button 26 while the second push button 28 is mounted in series with the turns of the coil 10 which are crossed by an electric current only when the second push button 28 is actuated. All of these turns bear the reference 34 in FIG. 3.

The operation of this device is identical to that of the previous device. There is also here a greater amplitude of oscillation of the core 12 when the first push button 26 is actuated. Part of the coil 10 is in series with the diode 16. The frequency of the force generated by the magnetic field is then 50 Hz. When the second push button 28 is actuated, the frequency of the force generated by the magnetic field is 100 Hz and the entire coil 10, including the turns 34, is in series with the second push button 28. The power of the motor is therefore attenuated in this second case as explained above.

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 The two embodiments described above allow with a single motor to generate two different sounds. The modifications to be made compared to a simple electromagnetic door chime generating only one sound are minor. It suffices in fact to add a diode and a resistor and possibly to adapt the distance separating the core at rest from the blades. These modifications can be easily carried out and do not entail any significant additional cost. An electromechanical door chime with two inputs is thus produced at a low cost price, comparable to the cost price of a simple chime.

The scope of the present invention is not limited to the details of the above embodiments considered by way of nonlimiting examples, but on the contrary extends to modifications within the reach of ordinary skill in the art, in the The scope of the claims below.

Thus the diode described above could be replaced by another device making it possible to vary the frequency of the force generated by the magnetic field acting on the core. Those skilled in the art indeed know electronic circuits making it possible to vary the frequency of an electric field.

The presence of an additional resistance, or a coil with two inputs, is optional. It is also possible to have both a coil with two inputs and a resistor connected in series with a push button. Other means can also be used to reduce the power of the motor when the second push button is actuated.

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Claims (5)

1. Electromechanical door chime with two inputs, comprising a motor (8) having a coil (10) and a movable core (12), and two blades (4, 6) arranged on either side of the motor, two buttons pushers (26, 28) being associated with the chime, characterized in that one of the push buttons (26) is connected to the chime by means of a device (16) making it possible to modify the frequency of the force generated by the magnetic field applied to the movable core (12). 2. Electromechanical door chime with two inputs according to claim 1, characterized in that the device making it possible to modify the frequency of the force generated by the magnetic field on the movable core (12) comprises a diode (16) and divides this frequency by two. 3. Electromechanical door chime with two inputs according to claim 1, characterized in that means (18, 34) making it possible to reduce the power of the motor when the second push button (28) is actuated are provided. 4. Electromechanical door chime with two inputs according to claim 3, characterized in that the means making it possible to reduce the power of the motor comprise a resistance (18). 5. Electromechanical door chime according to claim 3, characterized in that the coil (10) is a coil with two inputs, a first input making it possible to obtain the maximum power of the coil being connected to the first push button (26) while that the second input allowing a reduced power to be obtained is connected to the second push button (28).