SU1023182A1 - Infra-red heating plant - Google Patents

Abstract

INSTALLED FOR INFRARED HEATING, mainly drying varnishes, / containing an infrared lamp unit connected to a power source through a thyristor switch equipped with a control unit, a power source voltage divider whose output is connected to the first input of the control unit of the switch connected to the second input with the output the filter of the master voltage unit, and through a smoothing filter and a threshold element - to the key input connected to an additional source of stabilized voltage, which is equal to So that, in order to increase plant performance and increase lamp service life, the voltage driver unit is equipped with a photo relay, the output of which is connected to the single input of the first trigger, with zero input of the reversible counter, with the installation input to the second trigger unit and through the relay time - with the first input of the element IS-NOT, the second input of which is connected to the zero input of the first trigger connected by a single output with the first; the input of the first element I, the output of which through the first inputs of the second and third ele And is connected to the inputs of the forward and reverse C1 "of this reversible counter, the direct output of which is connected to the first input of the code-voltage converter through a controlled variable frequency generator to the second input of the first element (I) and through the decoder of the maximum code - to the zero input of the second trigger, a single input of which is connected to the inverse output of the reversible counter via a minimum code decoder, the direct output of the second trigger is connected to the second input of the second element I, and its inverse output from the second bubbled inputs of third AND and NAND. 00, the second input of the codec converter is connected to the output of the key, and | output6d - to the input of the filter of the driver voltage block,

Description

The invention relates to the heating of varnishes and paints after their naHeceHnfl for the purpose of drying and can be used, for example, in the automotive industry.

Devices for infrared heating are known that alter the luminous flux and, therefore, the heating mode depending on changes in operating conditions, such as changes in voltage and ambient light.

The disadvantage of these devices is the lack of automatic variation and alignment of the radiation spectrum with the absorption spectrum of the paint coating, which delays the drying process. The technical concept most closely related to the invention is an installation for infrared heating, preferably drying varnishes, containing a block of infrared lamps connected to the source power supply via a thyristor switch equipped with a control unit; a power supply voltage divider whose output is connected to the first input of the unit Regents of the switch associated with the second input of the output filter unit setpoint voltage and through a smoothing filter and a threshold element - to the input key stabilized voltage connected to the additional voltage source 2.

A disadvantage of the known installation is the T1-STANDING radiation spectrum that is not consistent with the optical properties of paint coatings having several areas of selective absorption. It is known that the drying process of paint coatings is not a purely thermal process and its intensity is largely due to the specific effect of infrared radiation, which must be related to the spectral characteristic of a paint coating having several absorption maxima (the effect of radiation of a certain frequency on the polymerization of molecules) . The change of the radiation spectrum is not made, which prolongs the drying process. There is an increased power consumption due to constant heating. The service life of the heating elements is limited due to their operation in one permanently selected limiting mode. The reduced drying capacity is due to the matching of the maxi; 1uma radiation of the infrared heater with only one absorption maximum of the paintwork.

The aim of the invention is to increase productivity and increase the life of the heating lamps.

The goal is achieved by the fact that in an installation for infrared heating,

Preferably, a lacquer dryer comprising an infrared lamp unit connected to a power source through a thyristor switch equipped with a control unit, a voltage divider of the power source whose output is connected to the first input of the switch control unit connected to the second input of the driver unit

5 and through a smoothing filter and a threshold element to the key input connected to an additional source of stabilized voltage, the voltage driver unit is supplied

0 master photo relay, the output of which is connected to the single input of the first trigger, with zero input of the reversible counter, with the installation input. To the unit of the second trigger and through the time relay with the first input of the NAND element, the second input of which is connected to the zero input of the first trigger; connected by a single output with the first input of the first element I, the output of which through the first inputs of the second and third elements I is connected to the input of the forward and reverse counting of a reversible counter, the direct output of which is connected to the first input of the transform OVAT, code-voltage, through a controlled variable frequency generator to the second input of the first element I and through the decoder of the maximum code to the zero input of the second trigger, the single input of which is connected to the inverse output of the reversible counter through the decoder of the minimum code, direct the output of the second trigger is connected to the second input of the second element And, and its inverse

5 output - with the second inputs of the third element AND and the NAND element, the second input of the code control converter is connected to the output of the key, and the output to the input of the filter of the driver voltage unit. FIG. 1 is a block diagram of the proposed installation; figure 2 timing diagrams. The source of 1 lithium is connected via a thyratron switch 2 to an infrared lamp unit 3. A control unit 4 by a switch 2 is connected by one input to the output of a block 5 of the master voltage, and the other to the output of the voltage divider 6. An additional source 7 of stabilized voltage is connected to the key 8 and through potentiometer 9 to the threshold element 10 connected via a smoothing filter 11 with a divider 6. The voltage setting unit 5 contains a photo relay .12, time relay 13, element 14 IS-NOT, trigger 15, first 16, second 17 and third 18 And elements, controlled generator 19, reversible counter 20, code-voltage converter 21, maximum 22 and minimum 23 code decoders, second count direction trigger 2k and filter 25. On time Diagrams 26-29 show variation of output GOVERNMENTAL photoelectric signals in time, timer, the second direction and the first trigger accounts respectively. Timing diagram 30 illustrates the change in frequency of a controlled oscillator over time. Diagram 31 shows a single graph, but at different scales the envelope of the driving voltage (at the output of the filter 25) and the voltage across the load. Timing diagrams 32-3 show the relative distributions of the spectral intensity of the infrared heater for emissions with a wavelength of 1.1; 2.0 and 3.0 μm, respectively. Switch 2 is made according to a well-known scheme, for example, on a triode thyristor; load 3 is a circuit of a series of connected in parallel infrared lamps of the type IKZ-220-500. The filter 25 is designed to smooth out changes in the driving voltage and is made, for example, capacitive. A smooth change in the driving voltage increases the service life of the infrared lamps due to the limitation of the dynamic loads of their helix. The voltage divider 6 is designed to reduce the voltage of the load to a level that is safe for semiconductor elements, and is made, for example, resistive. An additional power supply 7 serves to provide the DC voltage of the key element 8 with a stabilized voltage and, through potentiometer 9, creates a reference voltage on the threshold element 10. It is made according to a known scheme, for example, a DC compensating stabilizer, its output is connected directly to the circuit power supply of the key element and, through a potentiometer, to the reference input of the threshold element. Key element 8 is intended to change the conversion factor of the code-voltage converter e and its output connected to a first input of said transducer .It is, for example, on a chip with open collector type and swing K511PU1. The threshold element 10 compares the voltage at the input connected via filter 11 to the load voltage divider 6 with the reference voltage and produces a control signal at the output when the voltage at the second input exceeds the reference voltage level at the first input. The threshold element is made, for example, on the K155TL1 chip incorporated in the comparator circuit. The filter 11 is designed to smooth the pulsations of a part of the load voltage and is made, for example, capacitive. Photorelay 12 serves to determine the start of loading the working space of the drying chamber with an article. It is made according to a well-known scheme based on a photoresistor illuminated by an incandescent lamp and a relay circuit. The photorelay output is connected to the single input of the first trigger 15, the time relay input, the zero inputs of the reversible counter, and the second trigger acting as the trigger of the counting direction. Time relay 13 controls the drying time of the product. It can be 5

full digital based. The output of the time relay through the element AND is NOT connected to the zero input of the trigger 15.

The trigger 15 remembers the Start, Stop commands coming to its inputs from the photo relay 12 and the time relay 13. A single trigger output is connected to the first input of the first element 16 I, the output of which through second 17 and third 18 elements I is connected to the inputs of the forward and reverse counting of the reversible counter 20.

The forward output of the reversible counter is connected to the second input of the code-voltage converter, as well as to the input of the controlled generator 19 and through the maximum code decoder 22 to the zero input of the counting direction trigger. The inverse output of the reversible counter through a minimum code decoder is connected to a single input of a direction trigger; . accounts

The codes in the reversible counter are converted into a set voltage by means of a code-voltage converter 21, made, for example, resistive. The summing resistor is divided into two unequal parts in the ratio of 6: 1. When a voltage exceeds a certain level, a smaller part of the driving resistor is bridged by the key element 8 and the driving voltage is reduced by 2%, which prevents the infrared lamps from overvoltage.

The controlled oscillator 19 serves to change the frequency of filling the reversible counter as a function of its code. The larger the code in the reversible counter, the lower the output frequency of the controlled oscillator, which leads to an uneven change of the code in the reversible counter in time and to an uneven change in time of the driving voltage coming from the code-voltage converter 21 through the driving voltage of the driver input to the switch control unit. The output of the controlled generator is connected to the second input of the first element I.

The controlled oscillator contains, for example, three elements connected in a ring to NOT. A circuit of two connected in series is NOT connected to the input and output of the middle element26

capacitors. The middle point of the capacitor circuit is connected to the minus bus of the power source through a pnp type control transistor. A circuit of weight resistors connected to single outputs of the reversible counter is connected to the base of the transistor. When the code changes in the reersection counter, the base current of the transistor and the degree of its unlocking, i.e. his resistance. A change in the value of the transistor leads to a change in the output frequency of the controlled oscillator.

The decoders of a maximum of 22 and a minimum of 23 codes are intended to limit the code in the reversible counter between the maximum and minimum values determined from the requirements of the technological process. They are made on the elements AND-N € according to known schemes.

The trigger 2 serves to control the counting direction of the reversible counter (summation, subtraction) and control the end of the drying cycle. The direct and inverse outputs of the named trigger are connected respectively to the second input of the second element AND and the second inputs of the element NAND and the third element I.

In the device for controlling the infrared heating mode, all the digital elements are received in the K5P series, with the exception of the threshold element 10 (the K155TL1 series).

The device automatically changes the radiation spectrum of the infrared heater by acting on the voltage of the heater and stabilizing the desired voltage. The transition from one level of voltage to the filament of an infrared heater to another occurs smoothly, not abruptly. For a considerable part of the drying time, the heaters operate with reduced voltage, which causes energy savings, extends the service life of the heaters and increases the reliability of their operation. Improving the reliability of heaters also contributes to a smooth change in the voltage of their heat.

The device works as follows.

After the object to be dried enters the drying chamber through the conveyor into the drying chamber, the photo relay 12 is activated and generates a start-cycle signal. la drying. This signal triggers the time relay 12, the trigger | 5 and the trigger 2k are set to one, the counter 20 is set to the zero state. Positive pulses from the controlled generator 19 through the elements 16 and 17 I go to the input of the direct count reversible counter 20. The code in the counter begins to increase. The output voltage of the code-voltage converter increases, which, through the filter S of the driver voltage, is fed to the left input of the crossover / center control unit 4. The thyristor switch 2 under the influence of the control pulses produced by the control unit of the switch is partially turned off. Through the load 3 current begins to flow. The voltage on the load is stabilized at a given level by means of a negative feedback circuit containing a divider 6 of the load voltage, the output voltage of which is fed to the second input of the switch control unit (time / diagrams 30 and 31). Gradually, the code in the reversible counter 20 increases, the voltage increases at the inputs of the code converter, and the voltage of the master voltage filter 25, the voltage across the load increases. The filament current increases, and the infrared radiation spectrum shifts gradually to a shorter wavelength region (32-3 h diagrams). When the code reaches its maximum value in the reversible counter, the 2k trigger switches to the zero state. The pulses from the controlled generator through the third element 18 And begin to arrive at the input of the subtraction of the reversible counter. The code in the reversible counter starts to decrease smoothly. Decreases the voltage and filament voltage of the infrared heater. The infrared spectrum shifts to a longer wavelength region. When the code reaches its minimum value in the reversible counter, trigger 2k switches to one state. The cycle of change of the radiation spectrum of the infrared heater is repeated as described. After working through several cycles of changing the emission spectrum, the time relay generates a Stop signal (timing diagram 27 / arriving through element 14 of NAND to the zero input of trigger 15. The process of heating the part ends. The conveyor is turned on and the part is removed from the drying chamber. The chamber is ready for reception (Well, the next part. Thus, in the proposed device, there is a smooth change in the voltage of the infrared heater and a change in the spectrum of its radiation in a certain range. A periodic co-current occurs. The radiation spectrum of the heater with areas of their high absorption creates a heat dissipation and accelerates the heating of paint coatings. When drying multicomponent dispersion coatings, the individual components of which have different absorption spectra, it is possible to dry individual components at a lower temperature. selectively absorbing radiation in several bands of paint coatings enhances the process of the effect of radiation on the polymerization of molecules, thereby accelerating the process physicochemical transformations. The service life of the heating elements increases as the average value of the voltage at which they operate decreases and the voltage changes smoothly.

Claims (1)

INSTALLATION FOR INFRARED HAFPEBA, mainly for varnishing, containing an infrared lamp unit connected to a power source through a thyristor switch equipped with a control unit, a voltage divider for the power source, the output of which is connected to the first input of the switch control unit, connected to the second input with the output of the filter of the master unit voltage, and through a smoothing filter and a threshold element - to the key input connected to an additional stabilized voltage source, such that oh, in order to increase the installation performance and increase the service life of the lamps, the set voltage unit is equipped with a set photo-relay, the output of which is connected to a single input of the first trigger, with a zero input of the reverse counter, with the installation input to the unit of the second trigger and through the time relay with the first the input of the AND gate, the second input of which is connected to the zero input of the first trigger connected by a single output. with the first: the input of the first AND gate, the output of which through the first inputs of the second and third AND elements is connected to the forward and reverse counting moves of a reversible counter, the direct output of which is connected to the first input of the code-voltage converter q through a variable frequency controlled oscillator'- to the second input of the first element And and through the decoder of the maximum code - to the zero input of the second trigger, the single input of which is connected to the inverse output of the reverse counter through the minimum code decoder, the direct output of the second trigger is connected to the second input of the second element And, and its inverse output is connected to the second inputs of the third element And the AND-NOT element ^ the second input of the code-voltage converter is connected to the key output, and (the output is to the filter input of the set voltage unit ,; SU „1023182