DE4233376C1 - Alarm clock with inductive components - uses voltage peaks self induced in latter to light lamp or LED - Google Patents

Abstract

A periodic alarm signal is provided by an electroacoustic transducer (1) associated with a control transistor, receiving a periodic driver signal from a driver circuit (2). The voltage-sensitive components of the driver circuit and the transistor are protected against the voltage peaks occuring between the driver signal pulses, resulting from the inductive resistance component of the transducer (1), by using the voltage peaks for operation of a light source (3), directly, or via a control circuit (4, 5). Pref. the light source (3) comprises a lamp with the control circuit (4, 5) having a control stage with a diode and a charge capacitor. ADVANTAGE - Useful application of self-induction voltage peaks to provide light signal.

Description

The invention relates to an alarm clock according to the preamble of Claim 1.

Such an alarm clock is known from DE-A1 32 30 218. The electrical alarm clock described there has an electro acoustic transducer with a piezoelectric element, which is its sound-generating component. The electro acoustic transducer also has a parallel to that Piezoelectric element switched arrangement from an inductor activity and out of a resistance and is about a tax transistor on and off, its base with a Driver circuit is connected. The driver circuit in turn gives a periodic driver signal consisting of pulses with for example, a pulse frequency of 512 Hz and a be matched pulse width to the base of the control transistor. The piezoelectric element is only by the when periodically switching off the inductance through self-induction tion generated voltage peaks (flashback pulses) operated.

The pulse width of the individual pulses can be at the expense of ver permanent impulse pause for the purpose of increasing the volume of the acoustic signal emitted by the piezoelectric element be enlarged. Cause of the increase in volume an increase in the pulse width is the fact that the in the inductance stored energy with increasing pulse width also increases. To protect the driver circuit and the Control transistor before the periodic shutdown of the Kickback occurring inductance is antiparallel to Forward direction of the collector / emitter path of the control transi stors switched a diode.  

In addition to its periodicity, the driver signal is also known Alarm clock still clocked at a frequency of 1 Hz, d. that is Driver signal and thus that of the electroacoustic transducer The acoustic signal emitted has a duration of only 1/2 sec and will then be suspended for as long as this before up to the final deactivation of the alarm function repeated periodically.

While in the alarm clock known from DE 32 30 218 A1 due to the periodic switching on and off of the inductance Setback pulses that occur to generate an electro-acus table signal, it is also possible (see e.g. DE-GM 80 34 744) the piezoelectric element directly over the Operating the control transistor does not mean that it is being used the flashback pulses generated by an inductor. Also at such a direct control of the piezoelectric Elements is due to the still existing inductive Resistance components for securing the driver circuit and the Control transistor generally antiparallel to the passage direction of the collector / emitter path of the control transistor Diode switched. The same applies even more if instead of of the piezoelectric element in turn with direct control through a control transistor an electromagnetic, sound generating element is used.

In all three cases mentioned, i. that is, with direct control a piezoelectric or an electromagnetic, sound generating element or with indirect control of a piezo electrical element via an inductor the periodic activation of the recoil pulses not in a constructive way to realize another Function of the alarm clock is used, but there are switching means (Diodes) are used to largely reduce their influence to press. This results in the disadvantage that the electrical  Alarm clock has switching means, the purpose of which is solely in the suppression of usable elec trical currents.

It is therefore an object of the invention, in an alarm clock after Preamble of claim 1 which when sending a per The iodine wake-up signal creates a return pulse full use.

This task is for an alarm clock according to the generic term of Claim 1 by the in the characterizing part of this Features containing claim solved.

According to the invention, the flashback pulses that are applied to the elec tromagnetic converter of the alarm clock ent during an alarm are used to operate a light source or one Control circuit fed, which in turn for commissioning a light source. So that the setback impulses for used a beneficial purpose while otherwise unsung uses as glitches need to be suppressed. The one to be awakened Person therefore takes if the time and set wake-up time in addition to an acoustic one and an optical one Signal true, the optical signal finding the clock and thus the manual interruption of the wake-up process by pressing adjustment of switching means trained on the alarm clock relieved.

The check pulses are fed to a control circuit which controls the light source in an indirect way, so can Incandescent lamps with a relatively low output are used be, which has the advantage that larger light strengths can be realized. On the other hand, conventional Light bulbs can be replaced relatively easily.  

Further advantageous embodiments of the invention can Subclaims are taken.

Details of two embodiments of the invention emerge from the following description and the drawing to which Reference is made. The drawing shows:

Fig. 1 is a block diagram of a first embodiment of the invention He,

Fig. 2 shows an embodiment of a circuit arrangement of the block diagram according to FIGS. 2 and

Fig. 3 shows a circuit of a second embodiment of the invention, in which a light emitting diode forms the light source.

Fig. 1 is a block diagram showing an electroacoustic transducer 1, which is driven by a driver circuit 2. A lamp 3, which can be used, for example, to illuminate the dial of a clock (not shown), is controlled by a driver stage 4 . The flashback pulses, which arise when the wake-up signal is delivered by the electroacoustic transducer 1 , are fed via a control stage 5 to the driver stage 4 . As a result, the flashback pulses which arise due to the self-induction on those components of the electroacoustic transducer 1 which have an inductive resistance component are not suppressed as interference pulses. They rather control the switching on of the lamp 3 .

Fig. 2 shows a detailed embodiment of a circuit arrangement for the block diagram of FIG. 1. An integrated clock circuit 17 belonging to the driver circuit 2 causes the electroacoustic transducer 1 to be switched on at the set wake-up time. The electroacoustic transducer 1 itself is driven by a transistor 13 , to which the corresponding driver signal is supplied by the circuit 17 . The alarm clock is switched to wake-up mode (switch 15 closed) by means of a switch 15 .

When the wake-up signal is sounded, the electroacoustic transducer having inductive components has 1 flashback pulses as a counter-induction voltage. The pulses charge a charging capacitor 20 via a diode 21 , both of which already belong to the control stage 5 . A zener diode 19 , which is connected in series with the diode 21 , serves to cut off the voltage pulse peaks and thus to protect the electronic components of the control stage 5 . The flashback pulses occurring at the electroacoustic transducer 1 are integrated in the charging capacitor 20 . A partial voltage derived from the charging voltage of the charging capacitor 20 is generated by means of a series circuit consisting of resistors 24 , 25 and fed to a transistor 7 , which already belongs to the driver stage 4 . A diode 22 , which is in series with the resistors 24 , 25 , causes the charging voltage on the charging capacitor 20 to rise no more than about 0.6 volts above the operating voltage applied to the "+" and "-" poles. The voltage at the tap on the resistors 24 , 25 reaches a switching threshold when it rises, from which the transistor 7 switches through. The switching on of the transistor 7 simultaneously causes the switching of a transistor 8 , with the result that the lamp 3 is turned on as a light source for illuminating the dial of the clock.

A key 14 is actuated to interrupt the acoustic wake-up signal. This causes a transistor 6 belonging to the driver stage 4 to be switched through. The switching on of the transistor 6 also results in the switching on of the transistors 7 and 8 and thus the switching on of the lamp 3 . Insofar as the lamp 3 has already been switched on via the control stage 5 , as described above, no change in the state of the lamp 3 occurs . Consequently, the lamp 3 can be put into operation both via the transistor 6 (switching path: button 14 , resistors 16 and 9 ) and via the transistor 7 (switching path: charging capacitor 20 , resistors 24 , 25 ).

The key 14 is primarily used to switch on the dial lighting when required, regardless of the acoustic alarm signal. In addition, the button 14 in cooperation with the circuit 17 can also serve as a wake-up repeat button (so-called "snooze"). If the button 14 is pressed after the acoustic alarm signal (the lamp 3 is already switched on in this case), the charging capacitor 20 is discharged via a diode 23 and the button 14 itself, which connects the charging capacitor 20 to ground. The charging capacitor 20 is thus set by pressing the button 14 in a defined Betriebszu state, which corresponds to the discharge state. If the acoustic alarm signals sound again after the wake-up repetition time has elapsed, the charging capacitor 20 is recharged, and the switch-on process for the lamp 3 is repeated as described above. The diode 23 is polarized so that the charging capacitor 20 is not supplied with the operating voltage via a resistor 16 . The resistors 9 , 10 , 11 and 12 of the driver stage 4 serve to operate the transistors 6 , 7 , 8 .

The control stage 5 can be connected to a timing element (not shown) which automatically switches the lamp 3 to "OFF" after a predetermined period of time in order to reduce the current requirement and relieve the battery, irrespective of the acoustic signal. Such a timer can e.g. B. be a monostable multivibrator. In addition to illuminating the dial, the lamp 3 can also be used to illuminate other areas of the clock.

In the embodiment shown in Fig. 3, an electroacoustic transducer 1 is again provided, which, in addition to other resistance components, in turn has an inductive resistance component, so that in the intermittent actuation of an electronic switch 13, kickback pulses occur in the pulse pauses. The counterinduction voltage causing the flashback pulses is in the opposite direction to the direction of the DC voltage source supplying the alarm clock given by the polarities + and -. While an antiparallel to the electroacoustic transducer LED 18 in the event that the electronic switch 13 is closed, has a very large resistance, since voltage is applied to it only in the reverse direction, when the electronic switch 13 is open, voltage is in its forward direction.

The light-emitting diode 18 is therefore in the pulse pauses of the intermittent driver signal from the return pulses flowing through and therefore - if the return pulses are from sufficient electrical energy - emits light. The amount of light emitted by the light-emitting diode 18 also depends, among other things, on how the pulse / pause ratio of the periodic driver signal is selected. The larger the pulse width at the expense of the pulse pause, the more magnetic energy is stored in the components of the electroacoustic transducer 1 which have an inductive resistance component in order to feed a kickback pulse.

In addition to the protective function as a freewheeling diode for the transistor 13, the light-emitting diode 18 thus illuminates the digit sheet. The energy of the kickback pulses is used in a meaningful way to illuminate the dial.

In practice, it has been found that when using a light-emitting diode without limiting resistor of the type CL-50-CD from Citizen and an electronic converter of the type F-QMB-III from Star at an operating voltage of 1.5 volts, a good luminous efficacy is achieved by using a driver signal with a frequency of 2 kHz and a pulse width of 0.25 millisecond. As an electronic switch, it is then sufficient to use a DC 848 B small signal transistor. A driver signal of this type is emitted, for example, by the IC of type e 1446 from Eurosil, this IC additionally clocking the driver signal with a repetition frequency of 8 Hz with a pause duration of 62.5 milliseconds. This means that the acoustic signal with a frequency of 2 kHz sounds periodically 62.5 milliseconds and is then suspended for an approximately equally long pause. The light emitting diode 18 therefore emits light, which is also clocked at a frequency of 8 Hz.

Claims (9)

1. Alarm clock with a periodic wake-up signal emitting electroacoustic transducer, which on the one hand has components with inductive resistance and on the other hand is controlled by a driver circuit emitting a periodic driver signal via an electronic switch connected in series with the electroacoustic transducer, whereby in the pulse pauses Periodic driver signal caused by the inductive voltage peaks caused by inductive components of the electroacoustic transducer (flashback pulses), characterized in that the flashback pulses are used to operate a light source ( 3 , 18 ) either directly or indirectly via a control circuit ( 4 , 5 ) . 2. Alarm clock according to claim 1, characterized in that a lamp ( 3 ) is used as the light source and that the control circuit ( 4 , 5 ) acts as a charging circuit control stage ( 5 ) with a diode ( 21 ) and a charging capacitor ( 20 ) having. 3. Alarm clock according to claim 2, characterized in that the control stage ( 5 ) has a protective zener diode ( 19 ) which is connected in series with the diode ( 21 ). 4. Alarm clock according to claim 2, characterized in that the charging capacitor ( 20 ) is a series circuit - be standing from a via a further diode ( 22 ) connected to the positive pole of a DC voltage source resistor ( 24 ) and a resistor connected to ground ( 25 ) - Is connected in parallel, the charging capacitor ( 20 ) being connected between the further diode ( 22 ) and the resistor ( 24 ) and a connection between the resistors ( 24 , 25 ) forming a tap for a driver stage ( 4 ), which in turn controls the lamp ( 3 ). 5. Alarm clock according to claim 4, characterized in that a discharge diode ( 23 ) is connected to the charging capacitor ( 20 ), which is connected to its cathode connection with a button ( 14 ) which connects the charging capacitor ( 20 ) to ground when it is closed . 6. Alarm clock according to claim 5, characterized in that the button ( 14 ) serves simultaneously as a wake-up repeat switch and as a switch for manually switching on the lamp ( 3 ). 7. Alarm clock according to claim 4, characterized in that the lamp ( 3 ) has a timing element, in particular a mono stable multivibrator, connected upstream. 8. Alarm clock according to claim 1, characterized in that an antiparallel to the electroacoustic transducer ( 1 ) light-emitting diode ( 18 ) is used as the light source. 9. Alarm clock according to claim 8, characterized in that the electronic switch is a small signal transistor ( 13 ) and that a light-emitting diode ( 18 ) is used without limitation resistance.