CS229531B1 - Electronic light programmer - Google Patents

Abstract

The electronic programmer is designed to control the operation of agricultural and other equipment depending on the alternation of day and night. The input element controlled by light outputs a logical signal, the value of which is determined by the intensity of the ambient lighting. Derivative circuits are connected to its direct and inverse outputs, the outputs of which can be individually or simultaneously connected to the inputs of the counter. The outputs of the counter are fed to the decoder 1 of P, the outputs of which form programming outputs. These can be interconnected with the programming inputs of the output decoder. The latter is formed either by direct connections or by logical inverters, or by NAND logic circuits. The control outputs of the output decoder are thus formed either directly by the programming outputs of the decoder 1 of P, or by their inversions, or by the outputs of NAND logic circuits, to the inputs of which programming outputs are connected. Control outputs can directly control output elements that switch on lighting, heating, fans, empty tanks, etc. The programmer is suitable for automating the operation of various devices that are temporarily without human operator.

Description

(54) Electronic light programmer

The electronic programmer is designed to control the operation of agricultural and other equipment depending on the changing of day and night. The light-controlled input provides a logic signal, the value of which is determined by the ambient light intensity. Derivative circuits are connected to its direct and inverse outputs, the outputs of which can be connected individually or simultaneously to the counter inputs. The outputs of the counter are connected to a decoder 1 of P, whose outputs form programming outputs. These can be connected to the programming inputs of the output decoder. It consists of either direct links or logic inverters or NAND logic circuits. The control outputs of the output decoder thus consist either directly of the programming outputs of the decoder 1 of P, or of their inversions, or of the outputs of the NAND logic circuits, to whose inputs the programming outputs are connected. The control outputs can directly control the output members that switch lighting, heating, fans, emptying tanks, etc. The programmer is suitable for automating the operation of various devices that are temporarily unmanned.

The invention relates to an electronic light programmer.

Previously known programmers are usually solved by an electric motor or clockwork driven by a code disc or a drum. In certain positions of this disc or drum, the contacts are switched according to the desired program to control the respective functions. These programmers are very expensive and the electromechanical principle does not allow to achieve high reliability. The electronic programmers are designed so that the respective program is written in the control memory and the reading from this memory is controlled from the clock generator. Some programmers even have a digital computer controller structure. However, for many applications, this solution is unnecessarily complex and expensive.

The above drawbacks are overcome by the wiring of the electronic light programmer according to the invention. Its essence is that the output of the light sensor, which forms the first auxiliary output, is connected to the input of the logic inverter and the input of the second derivative circuit. The output of the logic inverter, which forms the second auxiliary output, is connected to the input of the first derivative circuit. A counter with two counting inputs and a reset input has an output connected to the decoder input 1 of P, whose set of programming outputs is coupled to the counter reset input and the set of programming inputs of the output decoder. Its outputs form a set of control outputs.

The electronic programmer is very simple and inexpensive. It enables easy realization of program control of processes depending on night and day alternation, which corresponds to a period of 12 or 24 hours. It is particularly advantageous for the automation of breeding and growing facilities. However, the device can also be used for heating control, cooling etc.

The invention will now be described in detail with reference to the accompanying drawing, in which a block diagram of a programmer is shown. , The programmer has an illumination sensor 1 at its input, whose output signal T is the first auxiliary output. This is further connected to the input of the logic inverter 2 and the input of the second derivative circuit 4. The output of the logic inverter 2 which forms the second auxiliary output S is connected to the input of the first derivative circuit 3. Counter 5 with two counting inputs 51, 52 and reset input N It has an outlet 50 connected to the input of the decoder 60 of the decoder 1 P 6. Its system of programming outputs _of D to D _P is connected to the reset input of the counter 5 and the N system where programming inputs to I _N output decoder 7, the outputs of which form a plurality of control outputs Oi to O _N.

The output 30 of the first derivative circuit 3 may be coupled to the first counter input of the counter 5. The output 40 of the second derivative circuit 4 may be coupled to the second counter input 52 of the counter 5.

The output decoder 7 comprises at least one interconnection of any programming input lj with any control output Oj or at least one logic converter connected by its input to any programming input lj and its output to any control output Oj, or the output decoder 7 comprises at least one logical NAND circuit whose inputs are connected to any programming inputs to I _K lj and whose output is connected to any control output Oj.

During the day when the switch 1 is illuminated, the first auxiliary output T has a logical zero value and the second auxiliary output S has a logical one value.

If the output 30 of the first derivative circuit 3 is connected to the first count input 51 of the counter 5, the state of the counter changes every morning when the logical value of the second auxiliary output S changes from logical zero to logical one.

If the output 40 of the second derivative circuit 4 is connected to the second counter input 52 of the counter 5, the counter state change always occurs in the evening depending on the change of the logical value of the signal on the first auxiliary output T.

If the outputs of both derivative circuits 3, 4 are connected to both counter inputs of counter 5, the state of the counter changes in the morning and in the evening.

Programming _of the outputs D D _P P 1 from the decoder 6 are determined counter state 5. In each time has only one of these outputs logical value different from the others, for instance a logical zero.

According involvement output decoder 7 may be programming _the outputs D and D _N directly connected to the control outputs Oi to O _N.

In this case, the output members connected to the control outputs O1 to O _{N are} controlled such that each day or half-day one of these output members or one group of these members connected to the respective control output Oj is activated. «

In the same way, the output members are controlled even if inverters are connected in the output decoder 7. In this case, only the corresponding control outputs Oj have the opposite logical value.

If the output decoder 7 is a NAND logic circuit, an output member connected to the output Oj formed by the output of this logic circuit is activated depending on the activation of the programming outputs Dj to D _K connected to the inputs of the logic NAND via the programming inputs I to I _K.

For example, if the programming outputs Di, Ds, Ds are connected to the inputs of the NAND logic circuit, the respective control output and its associated output member will be activated on the first, third, and fifth days after the programmer is started.

Individual output members can, for example, switch lights, heaters, fans, drop other appliances, empty containers, drinkers, and the like. The electronic programmer according to the invention thus makes it possible to automate

Claims (6)

SUBJECT 1 of P, whose set of programming outputs (D _o to D _P ) is connected to the reset input (Nj of the counter (5) and the set of programming inputs (li to I _N ) of the output decoder (7), whose outputs form a set of control outputs (Oi to O _N j. A light-controlled electronic programmer, characterized in that the output of the light sensor (1) constituting the first auxiliary output (T) is connected to the input of the logic inverter (2) and the input of the second derivative circuit (4), 2) which forms the second auxiliary output (S) is connected to the input of the first derivative circuit (3) and the counter (5) with two counting inputs (51, 52j and the reset input (N) has the output (50) connected to the input (60) ) decoder (6) 2. The light-controlled electronic programmer according to claim 1, characterized in that the output (30) of the first derivative circuit (3) is connected to the first count input (51) of the counter (5). 3. Connection of the electronic programmer for small farms to ensure the functioning of these devices for a certain period without human presence. A light-controlled device according to Claims 1 and 2, characterized in that the output (40) of the second derivative circuit (4) is coupled to a second counter input (52) of the counter (5). 4. The light-controlled electronic programmer according to claim 1, characterized in that the output decoder (7) comprises at least one connection of any programming input (1j) to any control output (Ojj). 5. The light-controlled electronic programmer according to claim 1, characterized in that the output decoder (7) comprises at least one logic inverter connected by its input to any programming input (Ijj) and its output to any control output (Oj). 6. The electronic programmer controlling light according to claims 1-5, characterized in that the output decoder (7) comprises at least one logic NAND circuit whose inputs are connected to any programming inputs (lj-I _to I whose output is connected to any control output (Oj).