SU860354A1 - Device for controlling combined irradiaton - Google Patents

Description

(54) DEVICE FOR CONTROL OF COMBINED

By irradiation

The invention relates to electrical engineering and can be used to control the artificial irradiation of industrial premises when young animals and birds are grown. A device and control of combined irradiation is known, which contains a software unit, a power unit, sources of infrared and ultraviolet radiation, triac voltage regulators, control pulse generators and a light sensor 1. The other device does not allow to adjust the ratio between the fluxes of infrared and ultraviolet radiation. Closest to the proposed technical entity is a device for controlling the combined irradiation, which contains a program block connected by an output to an input of a split unit having two phase outputs connected to the inputs of the triac voltage regulator, and a zero point connected to the output for connecting sources of infrared (IR) radiation (for example, incandescent lamps; n-1 g raviolet (UV) radiation (for example, gas discharge lamps) with control gears and non-linear resistance, Equalizing electrodes of the triac voltage regulators are connected to the outputs of generators, the inputs of which are connected to the outputs of individual infrared and ultraviolet radiation intensity settings 2. Although this device makes it possible to smoothly adjust the ratio and level of infrared and ultraviolet radiation fluxes, however, it does not ensure smooth activation and stabilization the irradiation level, which leads to a decrease in the service life of the luminaires and to a disconnection of the irradiation conditions from the optimum ones. The purpose of the invention is to increase the efficiency of irradiated and improved lifetime of radiation sources. The delivered target is accomplished by the fact that the device for controlling the combined illumination, which contains the program block, is connected from the outputs to the input of the blue block, which has two phase outputs connected to the inputs of the triac voltage regulators, and a zero output connected to connecting sources of infrared radiation (e.g., incandescent lamps) and ultraviolet radiation (e.g., gas discharge lamps) with control gears, two generators, infrared radiation intensity setting device The unit and the ultraviolet intensity control unit are equipped with two separate sets of elements, each of which consists of a trigger, two AND elements, an OR element, a differential amplifier, a comparator, an additional pulse generator and a photo sensor, and another output is provided in the program block. another photocell is optically connected with sources of infrared and ultraviolet radiation respectively, the outputs of the photosensors are connected to the same inputs of the comparator and the differential amplifier, The other inputs are connected to the output of the intensity adjuster according to infrared and ultraviolet radiation, the output of each comparator is connected to the trigger input, the output of each differential amplifier is connected through a separate terminal 1 And the other generator is connected to the direct output the corresponding trigger, and the output is connected to one of the two inputs of the OR element, the output connected to the control electrode of the corresponding triac voltage regulator , another input of each element OR is connected to the output of another element AND, connected by two of its own power to the output of the corresponding generator and to the inverse output of the corresponding trigger.

The drawing shows a schematic diagram of the device.

It contains software block 1 connected to the output of power block 2, which has two phase outputs 3 and 4 and zero output 5. Phase outputs 3 and 4 are connected to the inputs of the triac regulator 6 and 7 and the zero output 5 is connected to connecting sources 8 IR radiation 1 and sources 9 UV radiation, the output of the triac regulator 6 is connected to the output of the control gear of the gas discharge lamps 9; containing the incandescent transformer 10 and the choke 11, the nonlinear resistance element 12 is connected in parallel to the gas discharge lamps 9. The receiving outputs of the flip-flops 13 and 14 are connected to the same inputs of the elements 15 and 16 And, the other inputs of which are connected to the outputs of the additional generators 17 and 18. The outputs elements 19 and 20 IL

connected to the control electrodes of the triacs 6 and 7. The outputs of the photosensors 21 and 22 are connected to the inverse inputs of the comparators 23 to 24 and the differential

amplifiers (DU) 25 and 26, direct inputs of the comparators 23 to 24 and remote control 25 and 26 are connected to the outputs of the infrared radiation intensity setting device 27 and the UV radiation intensity setting device 28, the output of each of the comparators 23 and 24

connected to the counting inputs of the trigger 13 and 14, and the output of each of the remote control 25 and 26 to the inputs of additional generators 17 and 18 pulses. The generators 29 and 30 inputs are connected to the output of software block 1, and the outputs are connected to the inputs of elements 31 and 32 And, the other inputs of which are connected to the inverse outputs of the flip-flops 13 and 14.

The device works as follows. The software unit 1 generates a comaid pulse from the output to the power unit 2, and the supply voltage is supplied to the triac controls 6 and 7. Using the setting device 27, the IR radiation intensity sets the required

5 level of illumination of the irradiators 8. At the same time, 1 corresponding voltage value is supplied to the direct inputs of the comparator 23 and the differential, amplifier 25, the voltage inputs of which are energized

OTcjrrcTBHH irradiation from sources 8 at the input of the comparator 23 forms the potential O, which enters the counting input of the trigger 13, which is preset to O through its direct input. From its inverse output, potential 1 arrives at the first input of element 31 I, the second input of which receives pulses from generator 29. Thus, the possibility of passing pulses from generator 29 through element 19 OR to the control electrode of the triac controller 6 is prepared. At the output of the differential the amplifier 25, a voltage is applied to the input of the 17 llotulse generator, where a field-effect transistor may be used as the driver time, switched on in an alternating resistance mode. The magnitude of its resistance, and accordingly the latency angle to open the triac, produced by generator 17, depends on the magnitude of the voltage coming from the output of the differential amplifier 25. Because the forward output of the trigger 13 has a potential O, then the pulses produced by the generator 17 and postunay on one of the element inputs

Claims (2)

5 15 And, its output is not passed. At the output of software block 1, a sequence of pulses is formed, which is fed to the input of generator 29, and at its output are pulses that determine the latency angle of opening of the simistor 6 within the maximum value corresponding to the minimum level radiation of sources, up to the value corresponding to the maximum value of radiation during 1 interval of time 30–60 s. Since a potential 1 is formed at the inverse output of the flip-flop 13, the pulse sequence from the generator 29 through element 31 AND element 19 OR goes to the auxiliary electrode of the simulator regulator 6. At the same time, the voltage at the output of the triac regulator 6 and, accordingly, the radiation level of the sources 8. In accordance with the increase in the irradiation level, there is a change in the voltage supplied from the photo sensor 21 to the inverse inputs of the comparator 23 and the differential amplifier 25. The change in voltage on you ode of the latter leads to a change in the delay angle of the opening of the triac 6. In this way, the generator 17 synchronously changes the value of the opening angle of the triac 6 from the maximum value to the set setting 27. When the irradiance level set by the setting 17 is reached, the photosensor 21 produces a voltage whose mask becomes equal to the value of the voltage applied to the direct input of the differential amplifier 25 and the comparator 23. At the output of the comparator, a voltage pulse of 1 is generated, which The second is fed to the trigger input of the trigger 13. From its inverse output, the loss O comes to the element 31 AND, prohibits the passage of pulses from the generator 29 through the element 19 OR to the control electrode of the triac controller 6. This allows the passage of pulses through the element 15 And element 19 OR on the triac controller 6 from the pulse generator 17, which at this moment produces pulses corresponding to a given irradiation level. Subsequently, when the supply voltage changes or the irradiation level changes due to the dusting of the luminaires 8, a change in the irradiation level above will alter the signal of the photosensor 21 and, accordingly, the voltage at the output of the differential receiver 25. The irradiation level of the sources 8 in accordance with the disturbing effect. The operation of the control elements of the UV sources of radiation similar to that described above. Using the proposed device will allow stabilization of the flux of IR and UV irradiation at a given level, as well as increase the service life of the irradiation sources. Claims An apparatus for controlling a combined irradiation comprising a software unit connected by an output to an input of a power unit having two phase outputs connected to the inputs of the triac knobs 1, and a zero output connected to an infrared source (for example, glow lamps). ) and ultraviolet radiation (for example, gas discharge lamps) with control gears, two generators, an infrared radiation intensity indicator and an intensity indicator and ultraviolet radiation, characterized in that, in order to increase the efficiency of irradiation and increase the service life, it is equipped with two, separate sets of elements, each of which consists of a trigger, two elements AND, element OR, differential force1, KONUiapaTopa, pulse generator-and a photo sensor, and in the program block a separate output is provided, one photo sensor is optically connected with an infrared source, and the other with ultraviolet radiation, the output of each photo sensor is connected to one of the inputs the comparator and one of the inputs of the differential amplifier, the other inputs of which are connected to the output of the intensity intensity indicator corresponding to infrared and ultraviolet radiation, the output of each comparator is connected to the reporting trigger input, the output of each differential amplifier is connected to one of the inputs of one of the And elements whose input connected to the forward output of the trigger of the corresponding set of elements, and the output is connected to one of the two inputs of the OR element, which is connected to the output a control electrode of the triac corresponding toranapr voltage regulator, the other input of each OR gate connected to the output of the AND drztogo connected its two inputs to the output of the generator and to the output 1shversnomu Tpinrepa corresponding array element. Sources of information received in BmiMaiffle in the examination of 1.L11stov P.I. Apply electrical energy in agricultural production. Directory. M., Energie, 1974, p. 530; 2. USSR author's certificate for application number 2730545/07, cl. H 05 V 41/39, 28.02.79. S tm