RU2528432C1 - Device for thick-film resistor trimming - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: device comprises a reference voltage source (1), a comparator (2), a resistance measurer (3), an analogue-to-digital converter (ADC) (4), a multivibrator (5), a shift register (6), the first group of AND elements (7-1…7-n), a data storage unit (8), the second group of AND elements (9-1…9-n), a digital-to-analogue converter (DAC) (10), a torch discharge generator (11), a main electrode (12), a resistor being trimmed (13), a substrate holder (14), an OR element (15).

EFFECT: improved accuracy and stability of torch trimming of thick-film resistors by the discharges of different rate.

1 dwg

Description

The invention relates to microminiaturization and technology of electronic equipment and can be used in the manufacture of precision film resistors.

A device for fitting resistors is known (RF patent No. 20132936, IPC Н01С 17/22, publ. 05.15.94. Bull. No. 9), containing a substrate holder for attaching a customized resistor, a resistance meter connected to it by a signal input, a reference voltage source, block comparison, connected by the first and second inputs to the outputs of the reference voltage source and resistance meter, respectively, an analog-to-digital converter connected by a signal input to the output of the comparison unit, flare generators, AND elements, the first input to each of which is connected to the analog-to-digital converter output of the same name, and the output is connected to the input of the torch discharge generator of the same name, the control unit connected by each of the outputs to the second input of the same element And, and the clock output of the control unit is connected to the control input of the resistance meter, when this, each torch generator is equipped with a discharge working electrode having an individual installation gap between the top of the radiating cone and the surface of the resistor, and all working e electrodes are placed with a fixed gap between each other.

The disadvantages of this device are the low accuracy and stability of the fitting process associated with the need to use a group of working electrodes, each of which must have an individual installation gap between the top of the radiating cone and the surface of the resistor.

Closest to the proposed invention is a device for fitting thick-film resistors (AS No. 1827687 A1, IPC Н01С 17/22, publ. 07.15.93. Bull. No. 26), containing a substrate holder for attaching a customized resistor, a resistance meter connected to it by a signal input , a reference voltage source, a comparison device connected by the first and second inputs to the outputs of the reference voltage source and resistance meter, respectively, an analog-to-digital converter connected by a signal input to the output of the cp block avoniya, series-connected digital-to-analog converter and torch generator, elements And, the first input of each of which is connected to the same output of the analog-to-digital converter, and the output is connected to the same input of the digital-to-analog converter, multivibrator and shift register connected in series with each of its outputs with the second the input of the element of the same name And, the output of the multivibrator is also connected to the control input of the resistance meter, working electrodes having an individual the installation gap between the top of the radiating cone and the surface of the resistor, while it contains a switch, the signal input of which is connected to the output of the flare generator, each of the control inputs is connected to the output of the element And of the same name, and each of the outputs is connected to the working electrode of the same name.

The disadvantages of this device are the low accuracy and stability of the fitting process associated with the need to use a group of working electrodes, each of which must have an individual installation gap between the top of the radiating cone and the surface of the resistor.

The basis of the invention is the task of increasing the accuracy and stability of the flare fitting of film resistors using discharges of different power, using one working electrode.

This problem is solved in a device for fitting thick-film resistors, containing a substrate holder for attaching a customized resistor, a resistance meter connected to it by a signal input, a reference voltage source, a comparison device connected by the first and second inputs to the outputs of the reference voltage source and resistance meter, respectively a digital converter connected by a signal input to the output of the comparison device, series-connected digital-to-analog converter A and a flare generator equipped with a discharge working electrode installed with a gap between the top of the radiating cone and the surface of the resistor, the first group of elements And, the first input of each of which is connected to the same output of the analog-to-digital converter, multivibrator and shift register connected in series by its output with the second input of the element of the same name And the first group, the output of the multivibrator is also connected to the control input of the resistance meter, according to the invention In addition, a data storage unit is introduced into it, the input of which is connected to the output of the multivibrator, an OR element connected by each of its input to the output of the same element AND of the first group, the second group of AND elements, the first input of each of which is connected to the output of the data storage unit of the same name, and the second inputs of the AND elements of the second group are combined and connected to the output of the OR element, and each of their outputs is connected to the input of the digital-to-analog converter of the same name.

The drawing shows a block diagram of the proposed device.

The device contains a reference voltage source 1, a comparison device 2, a resistance meter 3, an analog-to-digital converter (ADC) 4, a multivibrator 5, a shift register 6, a first group of elements And 7-1 ... 7-n, a data storage unit 8, a second group elements And 9-1 ... 9-n, digital-to-analog converter (DAC) 10, flare generator 11, working electrode 12, adjustable resistor 13, substrate holder 14, element OR 15.

The device is connected in series with a adjustable resistor 13, a resistance meter 3, a comparison device 2 and ADC 4, as well as a DAC 10 and a torch discharge generator 11. The latter is equipped with a discharge working electrode 12 installed with a gap between the top of the radiating cone and the surface of the resistor 13, which is fixed on the substrate holder 14. The output of the reference voltage source 1 is connected to the first input of the comparison device 2. The first input of each of the elements And of the first group 7-1 ... 7-n is connected to the ADC output of the same name 4. The shift register input ha 6 and the control input of the resistance meter 3 are combined and connected to the output of the multivibrator 5. Each of the outputs of the shift register 6 is connected to the second input of the same element And the first group 7-1 ... 7-n.

In the device, a data storage unit 8, an OR element 15 and a second group of AND 9-1 ... 9-n elements are additionally introduced. The input of the data storage unit 8 is also connected to the output of the multivibrator 5, and each of its outputs is connected to the first input of the same element And the second group 9-1 ... 9-n. The second inputs of the AND elements of the second group 9-1 ... 9-n are combined and connected to the output of the OR element 15, each input of which is connected to the output of the same element And the first group 7-1 ... 7-n. Each of the outputs of the elements AND of the second group 9-1 ... 9-n is associated with the same input of the digital-to-analog converter 10.

The device operates in a push-pull circuit as follows.

During the first cycle of all fitting cycles, the resistance of the adjustable resistor 13 is measured using a resistance meter 3. In this case, the resistance meter 3 generates a constant voltage proportional to this resistance, which is maintained for two cycles. The command about measuring the value of the adjustable resistor and keeping the received level of the output voltage of the resistance meter 3 constant is given from the multivibrator 5. Its output signals have a rectangular shape. At "zero" levels of these pulses (the first cycle) in the device for fitting resistors, the resistance of the adjustable resistor 13 is measured and the output voltage of the meter 3 is proportional to it. Together, both of these processes occupy an insignificant part of the first cycle, so most of the first cycle and the entire second cycle (i.e., almost two cycles) at the output of the resistance meter 3, the generated constant voltage is maintained. Resistance meter 3, which generates a voltage proportional to the resistance value, can be implemented on the basis of a bridge circuit or a finished digital resistance meter.

In the comparison device 2, implemented on the basis of a voltage subtractor, the difference between the output voltages of the resistance meter 3 and the reference voltage source 1 is determined (the latter is proportional to the limit value of the resistance of the adjustable resistor 13). ADC 4 generates a digital code proportional to its input voltage (differential signal at the output of comparison device 2). ADC 4 contains n-bits, and the “weight” of each subsequent bit, starting from the second, is two times less than the previous one.

At the initial moment of operation of the device (during the first fitting cycle), a logical “1” is formed at the first output of the shift register 6 on the command from the multivibrator 5, which goes to the second input of the And element of the first group 7-1, thereby passing to the output of the And 7 element -1 signal contained in the first output of the ADC 4.

At the same time, also at the command of the multivibrator 5, a digital code is generated at the outputs of the data storage unit 8, which carries information about the energy of the first (most powerful) flare discharge. The signal from each of the outputs of the data storage unit 8 is fed to the first input of the element of the same name And the second group 9-1 ... 9-n.

If the output signal of the AND element of the first group 7-1 is logical “1” (it goes to the first input of the OR element 15), then during the second clock, the logical “1” is maintained at the output of the OR element 15. It arrives at the second inputs of the AND elements of the second group 9-1 ... 9-n, thereby passing to the output of each of these elements the signal contained in the output of the data storage unit of the same name 8.

The output signal of each of the And elements of the second group 9-1 ... 9-n is supplied to the DAC 10 input of the same name. Thus, during the second cycle, a constant voltage proportional to the energy of the first flare discharge is maintained at the output of the DAC 10. It arrives at the input of the torch discharge generator 11. Between the top of the emitting cone of the working electrode 12 and the adjustable resistor 13, a torch discharge occurs, which leads to the evaporation of the resistor material and an increase in its resistance.

If the output signal of the AND 7-1 element is a logical “0” (it goes to the first input of the OR element 15), then during the second clock cycle, the logical “0” is maintained at the output of the OR element 15. It arrives at the second inputs of the AND elements of the second group 9-1 ... 9-n, forming a logical “0” at their outputs. At the output of the DAC 10, a zero voltage value is formed. With this inclusion of the torch generator 11 is not performed.

During the second cycle of fitting on command from the multivibrator 5, a logical “1” is formed at the second output of the shift register 6, which is fed to the second input of the And element of the first group 7-2, thereby passing the signal contained in the second to the output of the And 7-2 element ADC output 4.

At the same time, also upon a command from the multivibrator 5, a digital code is generated at the outputs of the data storage unit 8, which carries information about the energy of the second flare discharge.

In general, the operation of the device during the second fitting cycle occurs similarly to the previously described.

If there is a logical “1” in the second bit of the ADC 4, the flare discharge of the second cycle leads to an increment of resistance half as much as in the first fit cycle.

In the future, the resistance control loop of the adjustable resistor 13 and the burning out of a part of its layer are repeated many times, each time compared with the previous cycle, a smaller (twice) increment in resistance is provided in the presence of a logical “1” in the corresponding bit of the ADC 4.

The advantages of the device compared to the prototype are increased accuracy and stability of the flare fitting of film resistors. This is achieved by introducing a data storage unit 8, a second group of AND 9-1 ... 9-n elements and an OR element, as well as using one working electrode 12 for all fitting cycles. In this case, there is no need to accurately set a large number of gaps between the radiating cones of the workers electrodes and resistor surface. Codes for each fitting cycle, allowing the use of one working electrode, are stored in the data storage unit 8 and are generated automatically at its outputs upon command from the multivibrator 5.

Claims (1)

A device for fitting thick-film resistors, comprising a substrate holder for attaching a customized resistor, a resistance meter connected to it by a signal input, a reference voltage source, a comparison device connected by the first and second inputs to the outputs of the reference voltage source and resistance meter, an analog-to-digital converter connected signal input to the output of the comparison device, a series-connected digital-to-analog converter and a torch generator about the discharge, equipped with a discharge working electrode installed with a gap between the top of the radiating cone and the surface of the resistor, the first group of elements And, the first input of each of which is connected to the same output of the analog-to-digital converter, a multivibrator and a shift register connected in series with each output the second input of the element of the same name And the first group, the output of the multivibrator is also connected to the control input of the resistance meter, characterized in that it additionally a data storage unit has been introduced, the input of which is connected to the output of the multivibrator, an OR element connected with each of its input to the output of the same element And the first group, the second group of elements AND, the first input of each of which is connected to the same output of the data storage unit, and the second inputs of the elements the second group are combined and connected to the output of the OR element, and each of their outputs is connected to the input of the digital-to-analog converter of the same name.