DE19739537A1 - Device for switching an electrical load on and off - Google Patents

Abstract

The present invention relates to a device for connecting and disconnecting an electric load (6), such as a lighting fixture, according to the ambient luminosity. The device comprises a light sensor (1), an electronic estimation unit (2) mounted downstream from the light sensor (1) and comprising at least one comparator (10, 11), a switching delay stage (3) mounted downstream from said electronic estimation unit (2), and a power switch (5) mounted downstream from the electronic estimation unit (2) and the switching delay stage (3). In order to reduce the power consumption to a minimum, the electronic estimation unit (2) is made in the shape of two comparison circuits (10, 11) which are mounted in parallel and have different and adjustable switching threshold values (Lx1, Lx2) that correspond to the disconnecting and connecting ranges of the electric load (6).

Description

The invention relates to a device for switching an electrical load on and off, for. B. a lighting system, depending on the ambient brightness, consisting of a Light sensor, an evaluation electronics downstream of the light sensor with at least a comparator, a switching delay stage connected downstream of the evaluation electronics as well as one downstream of the evaluation electronics or the switching delay stage Load switch.

Such a device is e.g. B. from the published patent application DE 33 07 720 A1. At the previously known device is a time switch device for temporarily switching off the Load provided, which is designed as a counter and the control signals of the evaluation electronics as well as the switching delay stage. The timer device works here preferably with fixed times, for example 6 hours, the switching Delay level prevents the load switch from being briefly illuminated fluctuations is actuated.

The fact that. Is less advantageous in the known device due to the fixed switching intervals, no changes in brightness during the day can be taken into account so that the desired energy saving effect is not optimally achieved can be. In addition, the known device for use in particular in unsuitable for large buildings. A needs-based lighting can be without additional Time control only leads to energy losses, because at night the lights are on everywhere, without being used. The control engineering effort is infinitely variable light adjustment however, involves considerable effort.

It is therefore an object of the present invention to set up the above-mentioned device To improve the genus in that it the during the on-time of the load Monitoring of minimum brightness values especially in rooms with natural Lighting takes over and thus enables an optimal energy saving effect. In doing so  the criterion "safety precedence over austerity measures" is met.

This object is achieved in that the evaluation electronics by a Parallel connection of two comparator circuits is formed, the different, the Ab- and adjustable switching threshold values assigned to the switch-on range of the load. It is particularly advantageous if the switching delay stage by each, each Comparator circuit downstream time delay element with different Time behavior is formed.

To disturbances caused by brief incidence of light, for example caused by headlights of passing motor vehicles etc., not to be interpreted as daylight, sees one Development of the invention that the delay value of the first Comparator circuit associated time delay element is several minutes.

In order to prevent short-term darkening caused by birds flying by, Fluttering flags, etc., is to be excluded in a further version of the Subject of the invention provided that the delay value of the second Comparator circuit associated time delay element is several seconds.

In further advantageous embodiments of the subject matter of the invention Output signal of the time delay element associated with the first comparator circuit in a first AND gate with the output signal of the first comparator circuit linked, which indicates an exceeding or falling below the upper switching threshold, or the output signal of the assigned to the second comparator circuit Time delay element in a second AND gate with the output signal of the second Comparator circuit linked, the falling below or exceeding the lower Displays the switching threshold. Through these measures, a total decoupling of the two switching thresholds, d. i.e. no constant switching on / off by one Hysteresis switching point reached, the z. B. is particularly important for fluorescent lamps.  

A particularly quiet switching behavior is guaranteed when the output signals the AND gate of a memory element, e.g. B. an RS flip-flop, supplied Control signal actuated the load switch.

The function of the load to be switched is checked after another Invention feature thereby allows an OR gate to the second AND gate is connected downstream, the output signal of the second AND gate and the Output signal fed to a test button serving to check the function of the device become. In this context, it can be particularly useful if a Network monitoring circuit is provided, the output signal of the OR gate is fed. This measure ensures that the load function is checked when switching on or after a power failure.

A further increase in the operational safety of the device according to the invention is shown in another advantageous embodiment of the subject matter of the invention achieved in that a circuit for monitoring the operational readiness of the device and / or a Circuit for monitoring errors occurring in the load is provided. The the latter circuit can then switch off the load when a load error occurs. It is also particularly useful to use the load switch as a switch with electrical isolation to execute.

The invention is set forth in the description below with reference to the accompanying Drawing explained in more detail using an example. The drawing shows:

Fig. 1 is a block diagram of an embodiment of the device according to the invention, and

FIG. 2 shows a diagrammatic representation of the function of the device according to FIG. 1.

The schematically illustrated in FIG. 1 device of the invention essentially consists of a light sensor 1, a light sensor 1 downstream evaluation 2, one of the transmitter 2 downstream switching delay stage 3, a signal link member 4 and a signal link member 4 downstream load switch 5 for turning on and off a Load 6 , for example a lighting system connected to a suitable energy source 7 , e.g. B. a 230 V voltage network is connected. A circuit which is only indicated schematically and which is provided with the reference symbol 18 serves to monitor the load state. The evaluation electronics 2 in turn consist of two comparator circuits 10 , 11 connected in parallel, which have different switching threshold values Lx ₁ , Lx ₂ , while the switching delay stage 3 is formed by a respective delay element 12 , 13 assigned to the comparator circuits 10 , 11 . The first comparator circuit 10 is preferably assigned to the switch-off process and is excited to generate output signals Lx ₁ by brightness values which are significantly above a minimum illuminance (Lx ₂ ). The preferably binary output signal Lx _{1 of} the first comparator circuit 10 is supplied on the one hand to the assigned delay element 12 and on the other hand to a first AND gate 14 forming part of the signal logic element 4 , to which the output signal Lx ₁ v of the first delay element 12 is also made available, its time delay t ₁ z. B. is a few minutes. The output signal OFF of the AND gate 14 is fed to a memory element 16 , for example a first (set) input of an RS flip-flop, by means of the output variable ACT of which the aforementioned load switch 5 is controlled. The use of the first delay element 12 ensures that the load 6 is switched on at least in the time t ₁ .

The second comparator circuit 11 , on the other hand, is assigned to the switch-on process and is excited to generate output signals Lx ₂ by holiness values which are below a minimum brightness value. The output signal Lx ₂ ("0" - "1") of the second comparator circuit 11 is supplied on the one hand to the assigned second delay element 13 and on the other hand to a second AND gate 15 which is also assigned to the signal logic element 4 and which also has the output signal Lx ₂ v of the second delay element 13 is provided, the time delay t ₂ z. B. is a few seconds. The output signal ON of the second AND gate 15 is supplied to the aforementioned memory element 16 , for example a second (reset) input of the RS flip-flop. The use of the second delay element 13 ensures that the load 6 is switched off at most for the period t ₂ .

Fig. 1 is set out further in that an OR gate 17 is connected between the second AND gate 15 and the memory element 16, which as input signals of a power monitor circuit 8, and a test key 9 can be supplied, which serves a function check of the entire device . The mains voltage monitoring circuit 8 generates a signal when the energy source 7 is switched on, for example in the morning when the lighting system is first switched on or after a power failure. In this case, the load 6 remains switched on for a maximum of t ₁ even with sufficient brightness (<Lx ₁ ). The same state occurs when the test button 9 is pressed, e.g. B. for the purpose of checking the function of the load after changing a lighting fixture with sufficient brightness. In order to monitor the operational readiness of the device according to the invention, a circuit 19 can preferably be provided which interacts with the previously mentioned network saving monitoring circuit 8 .

The function of the device according to the invention will now be explained in connection with the diagrammatic representation according to FIG. 2, reference character I indicating the time profile of the brightness signal supplied by light sensor 1 , while reference characters II and III indicate the time profiles of the signals of time delay elements 13 and 12 and with the reference symbol IV the time profile of the signal representing the switching state of the load 6 are provided. It is assumed that the switching threshold value of the first comparator circuit 10 Lx ₁ ≈ 500 Lx, the switching threshold value of the second comparator circuit 11 Lx ₂ ≈ 350 Lx, the time delay of the first time delay element 12 t ₁ = approx. 10 minutes and the time delay of the second time delay element 13 t ₂ = approx. 10 seconds.

As can be seen in particular from time course IV, the load was switched on at time T _0, for example by a time switch. If the light sensor 1 detects a brightness value at time T ₁ (point A on curve I) which corresponds to the switching threshold value Lx _{1 of} the first comparator circuit 10 , this generates a status signal with which the first time delay element 12 is started, the time delay of which as mentioned before, is about 10 minutes. At the end of this time interval, that is, at time T ₂ , the load 6 is switched off, a brief change in brightness at time T ₃ causing e.g. B. by an extraneous light disturbance, although a generation of the mentioned status signals Lx ₁ , Lx _{1V results} , but does not affect the switching process of the load 6 . At time T ₄ (point B on curve I), the brightness value detected by light sensor 1 corresponds to switching threshold value Lx ₂ of second comparator circuit 11 , which generates a (switch-on) status signal with which second time delay element 13 is started, the time delay of which is approx. Is 10 seconds. At the end of this time interval, that is, at time T ₅ , the load 6 shifts. A second brief increase in brightness at time T ₆ starts the first time delay element 12 again , but has no effect on the switching state of the load 6 , since the brightness value determined by the light sensor 1 has fallen below the switching threshold value Lx _{2 of} the second comparator circuit 11 again after a very short time . The load 6 therefore remains in the switched-on state even after the delay in the first time delay element 12 has expired.

At time T ₇ (point C on curve I) the switching threshold Lx _{1 of} the first comparator circuit 10 is reached and the first time delay element 12 is started. Since the brightness value determined by the light sensor 1 at the time T ₈ , ie after the delay t _{1 of} the first time delay element 12 has expired, is clearly above the switching threshold value Lx _{1 of} the first comparator circuit 10 , the load 6 is switched off at this time.

At time T ₉ (point D on curve I) the switching threshold Lx _{2 of} the second comparator circuit 11 is finally reached and the second time delay element 13 is started. The brightness value determined by the light sensor 1 at the time T ₁₀ , ie after the delay t _{2 of} the second time delay element 13 has expired, is below the switching threshold value Lx _{2 of} the second comparator circuit 11 , and the load 6 is switched on at this time, which then occurs at time T ₁ t, for example by means of the aforementioned timer, is turned off.

Claims (15)

1. Device for switching an electrical load ( 6 ), for. B. a lighting system, depending on the ambient brightness, consisting of a light sensor ( 1 ), evaluation electronics ( 2 ) connected downstream of the light sensor ( 1 ) with at least one comparator ( 10 , 11 ), switching delay stage ( 3 ) connected downstream of the evaluation electronics ( 2 ) ) and one of the evaluation electronics ( 2 ) or the switching delay stage ( 3 ) downstream load switch ( 5 ), characterized in that the evaluation electronics ( 2 ) is formed by a parallel connection of two comparator circuits ( 10 , 11 ), the different, the off and have adjustable switching threshold values (Lx ₁ , Lx ₂ ) assigned to the switch-on range of the load ( 6 ). 2. Device according to claim 1, characterized in that the switching delay stage ( 3 ) is formed by each time comparator circuit ( 10 , 11 ) downstream time delay element ( 12 , 13 ) with different timing. 3. Device according to claim 2, characterized in that the delay value of the time comparator ( 12 ) assigned to the first comparator circuit ( 10 ) is several minutes. 4. Device according to claim 2, characterized in that the delay value of the time delay element ( 13 ) assigned to the second comparator circuit ( 11 ) is several seconds. 5. Device according to claim 3, characterized in that the output signal (Lx _1V ) of the first comparator circuit ( 10 ) associated time delay element ( 12 ) in a first AND gate ( 14 ) with the output signal (Lx ₁ ) of the first comparator circuit ( 10 ) is linked, which indicates that the upper switching threshold value is exceeded or fallen below. 6. Device according to claim 3, characterized in that the output signal (Lx ₂ v) of the second comparator circuit ( 11 ) associated time delay element ( 13 ) in a second AND gate ( 15 ) with the output signal (Lx ₂ ) of the second comparator circuit ( 11 ) is linked, which indicates that the lower switching threshold value is exceeded or fallen short of. 7. Device according to claim 4 and 5, characterized in that the output signals (OFF, ON) of the AND gate ( 14 , 15 ) are supplied to a memory element ( 16 ), the control signal (ACT) actuates the load switch ( 5 ). 8. The device according to claim 7, characterized in that the memory element ( 16 ) is formed by an RS flip-flop, the set input (S) with the output of the first AND gate ( 14 ) and the reset input (R) with the output of the second AND gate ( 15 ) is connected. 9. Device according to one of claims 5 to 8, characterized in that the second AND gate ( 15 ) is followed by an OR gate ( 17 ) to which the output signal (ON) of the second AND gate ( 15 ) and the output signal one of the function test of the device serving test button ( 9 ) are fed. 10. Device according to one of the preceding claims, characterized in that a network monitoring circuit ( 8 ) is provided. 11. The device according to claim 9 and 10, characterized in that the output signal of the network monitoring circuit ( 8 ) is supplied to the OR gate ( 17 ). 12. Device according to one of the preceding claims, characterized in that a circuit ( 19 ) is provided for monitoring the operational readiness of the device. 13. Device according to one of the preceding claims, characterized in that a circuit ( 18 ) is provided for monitoring the load state. 14. The device according to claim 13, characterized in that the load ( 6 ) is formed by at least one fluorescent lamp, which is switched off when a faulty condition is detected. 15. Device according to one of the preceding claims, characterized in that the load switch ( 5 ) is designed as a switch with electrical isolation.