CS234262B1 - Connection for switching devices depending on time and day of the week - Google Patents

Abstract

The invention solves the connection for switching devices depending on the time and day of the week, in particular lighting, security protection, heating elements, etc., which has means for time data. The purpose of the invention is to ensure the required time of switching on or off the device independently of a power outage, even on the required day. The essence of the solution is that the second output of the memory directory is connected to the input of the switching time memory and to the input of the switching time memory, the input of which is connected to the first output of the pulse source, the second output of which is connected to the input of the auxiliary time source, the first output of the memory directory being connected to the first input of the day comparator, the second input of which is connected to the output of the time comparator and the third input of which is connected to the output of the day information source, while the output of the day comparator is connected to the input of the switches.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to circuitry for switching time and day-dependent devices, in particular lighting, security devices, heaters and the like, having time data means and having a switching time memory output connected to the first input of the interval timer. the Interval Evaluator input is connected to the Trip Timer memory output, and the auxiliary time source output is connected to the second Interval Evaluator input, which is also connected to the second comparator input whose first input is connected to the Interval Evaluator output and whose third input is connected to the output real time.

At present, wiring performing a similar function is solved by mechanical switches. Mechanical switches, usually clockwork, rotate contacts that switch other devices,

For mechanical switches, which distinguish between days and times, accuracy is inadequate, often only tens of minutes. It is further disadvantageous that when the clock is powered from the mains, it reacts when the clock fails. When power is restored, they show the time reduced by the down time. Furthermore, we have to consider the low reliability of mechanical contacts, which is a major disadvantage of these devices.

The above-mentioned disadvantages are eliminated by the circuit according to the invention, characterized in that a second output of the memory directory is connected to the input of the switching time memory and the input of the tripping time memory. the input is connected to a first pulse source output, the second output of which is connected to the auxiliary time source input, the first memory directory output being connected to the first day comparator input, the second time input of the time comparator output and the third input connected to the source output the day information while the day comparator output is connected to the switch input.

The main advantage of the circuit according to the invention is that it tests whether the real time is in the interval when the device is to be switched on or

234 282 I punch it. This is advantageous in the event of a power outage, when the device does not overestimate the accuracy of the device in minutes. Due to the possibility of precise programming of wiring or shutdown, this device can provide great energy savings. It is also advantageous to use the device in conjunction with a time-controlled clock, eg OMA.

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The invention is explained in more detail below by way of example with reference to the drawing.

The block diagram of the invention is shown in FIG.

The first output of the χ pulse source is connected to the input of the memory directory 8. The first output of the memory directory 8 is connected to the first input of the day comparator 11 and its second output is connected to the switch-on time memory 1 and the switch-off time memory 2. The second output of the pulse source 6 is connected to the input of the auxiliary time source 6. The switching input memory 1 is connected to the first input of the χ interval evaluator, the output of the trip time memory 2 is connected to the third input of the χ interval evaluator and the output of the auxiliary time source £ is connected to the second input. The output of the auxiliary time source 6 is also connected to the second input of the comparator 38. The χ interval evaluator output is connected to the first input of the comparator 2. The third input of the 2-time comparator is connected to the output of the real-time '6. The second input of the day comparator H is connected to the output of the time controller 2. The output of the day information source 10 is connected to the third input of the comparator 11. The output of day comparator 11 is connected to the input of switches χ.

The pulse source 2 is an astable multivibrator, with pulses for the memory directory 8 having a frequency 3000 times smaller than the pulses for the auxiliary time source. A directory of 8 memories consists of counters that address memory 1 of switch-on time and memory 2 of switch-off time. The final three digit <memory £ 1, 2 indicates to which day the information stored in this memory address belongs. Tuesday, because the three-digit * 010 represents 2 ¹ in the binary system, the second day of the week, Tuesday · Other address numbers indicate which device should be turned on or off. If the type of memory that is erased when the supply voltage is switched off is used as a switching time memory 1 and switching off time memory 2, a permanent source separate from the diode supply must be connected to this memory.

234 262

Preferably, NiCd cells can be used. »The auxiliary time 4 source consists of counters that count from * 0000 * to 2359”. The first two digits symbolize the hours and the second minutes. Auxiliary time is counted as real time, ie after 59 arrives at minutes ”00, at hours it arrives at * 00 *. The interval evaluator 3 detects that the auxiliary time matches the time stored in the switching time memory 1. In agreement, the evaluation flip-flop that is part of the interval evaluator flips from state 2 to state * 1; that the output of this evaluation flip-flop is log 1 *. At the same time, the interval evaluator detects the auxiliary time match with the time stored in the trip time memory 2 and when the match is detected, the evaluation flip-flop returns to the 2 * state. that its output is log 0 *. This ensures that if the auxiliary time is in the interval when the device is to be switched off?, It is at the output of the evaluation flip-flop and thus at the output of the 3rd interval logger * 0 and if the auxiliary time is in the When the device is switched on, it is at the output of the evaluation flip-flop and thus the evaluator 3, interval log * 1. If the match is found, the output of the evaluation flip-flop is rewritten to the output of the output flip-flop that is part of the comparator 3 of the time, and remains there until the next auxiliary time is matched with the real time. . The output from the time equalizer 2, i.e. the output of the output flip-flop, is applied to the input of the day comparator 11. The day comparator 11 comprises switching flip-flops, and to override the output of the spinner 2 time to the outputs of the day comparator 11, i.e. to the outputs of the switching flip-flops, the following conditions must be met. The day comparator 11 detects the match of the last three digits of the memory address and the information obtained from the day information source 10. Auxiliary inputs of the flip-flop circuits are unlocked when a match is detected. This fulfills the first condition for overwriting the information from the output to ‘switching flip-flop. The day comparator 11 determines, by means of a converter, from the other memory numbers to which the respective flip-flop circuit applies a pulse which, if the first condition is met, overwrites the time comparator 2 output to the corresponding day comparator 11 output. The switches 2 are formed by power semiconductor switching elements which switch electrical power to the respective device.

Claims (1)

Wiring for switching devices depending on time and day of the week, in particular lighting, security protection, heaters, etc., which have time data means and to which the switching time memory output is connected to the first input of the interval timer, to the third input The interval timer memory output is connected to the switching time memory 1 and the auxiliary time source output is connected to the second interval timer input, which is also connected to the second input of the comparator, the first input is connected to the interval evaluator output and the third input is connected to the output A real time clock, characterized in that a second output of the memory directory (8) is connected to the memory input (1) of the switching time and the memory input (2) of the tripping time, the input of which is connected to the first output of the pulse source. it is connected to the input of the auxiliary time source (4), wherein the first in The output of the memory directory (8) is connected to the first input of the comparator (11) of the day, to the second input of which the output of the comparator (5) is connected and the third input to the output of the day information source. is connected to the switch input / 7 /.