CS273232B1 - Membrane vacuometer connection - Google Patents

Abstract

The connection consists of the input terminals (12, 13), condensers (CK, CT), analogue multiplexer (2), multivibrators (3, 4), counters (5, 6), control blocks (7, 8), D/A converter (9), indication block (10), block (1) of parameter setting, and output terminals (14 to 18), which are mutually interconnected according to the figure. The vacuum gauge operates on the digital principle. The electrodes of the gauge are connected to the input terminals (12, 13). The vacuum gauge can be used in technological devices controlled by computer, which can substitute a part of the connection that is delineated by the thick dash line.<IMAGE>

Description

(57)

Involvement consists of input terminals / 12, 13 /, the condenser / C _K, C "/ analog multiplexer / 2 /, mulvivlBrátorů / 3

4 /, counters / 5, 6 /, blocks / 7, 8 / control,

D / přev of converter (9), block (10) of indication, block (1) of parameter input and output terminals (14 to 18), interconnected according to the drawing. The vacuum gauge works on a digital principle. The dipstick electrodes are connected to the input terminals (12, 13). The vacuum gauge can be used in computer-controlled technological devices that can replace part of the wiring, separated by a thick broken line.

IS 273232 Bl

CS 273232 Bl

The invention solves the connection of a membrane vacuum gauge in which the compensation of temperature effects, linearization and correction is performed digitally.

Membrane vacuum gauges are known using the analog method for measuring the difference in measuring and compensating capacitance of a dipstick. Then all the properties of the gauge (temperature dependence, linearity) must be typical because the production of the gauge is very demanding as well as its calibration and calibration. The accuracy and stability of the device is strongly dependent on the human factor and the quality of the analog adjusters. Also known are membrane vacuum gauges operating on the basis of digital methods, e.g. Certificate 26 O 691.

The disadvantage of this solution is that the measurement of the capacitance of the measuring and compensating electrode does not take place simultaneously, which can introduce into the measurement errors caused, for example, by self-oscillations of the membrane, interference, etc. In some cases, it also proves to be disadvantageous to connect the dipstick to the electronics with the indication block and the p / U converter using a considerable number of wires. This leads to higher wiring complexity, especially when galvanic separation of the dipstick is required.

The described drawbacks are overcome by connecting a membrane vacuum meter according to the invention. It consists of input terminals, capacitors, analog multiplexer, multivibrator, counters, control blocks, D / A converter, indication block, parameter entry block and output terminals. Its essence is that the first input terminal is connected and the first and the sixth analog multiplexer input is connected, the second input terminal is connected to the second and the fifth analog multiplexer input, between the common conductor and the third and the eighth analog multiplexer input is connected the first capacitor and a second capacitor is connected between the common conductor and the fourth and seventh analog multiplexer vatup. The first analog multiplexer output is coupled to the input of the first multivibrator whose output is coupled to the first input of the first counter, and the second analog multiplexer output is coupled to the input of the second multivibrator whose output is coupled to the first input of the second counter. The bulk first output of the first counter is coupled to the bulk first input of the first control block and the second output of the first counter is coupled to the second input of the first control block. The bulk first output of the second counter is coupled to the bulk third input of the first control block and the second output of the second counter is coupled to the fourth input of the first control block. The first output of the first control block is coupled to the second input of the first counter and simultaneously to the second input of the second counter. The second output of the first control block is connected to the ninth input of the analog multiplexer, the third output of the first control block is connected to the tenth input of the analog multiplexer, and the fourth output of the first control block is connected to the first output terminal. It is also essential that the fourth output of the first control block can be coupled to the first input of the second control block. Then, the bulk output of the parameter input block is coupled to the bulk second input of the second control block, the first output of the second control block is coupled to the second output terminal, the bulk second output of the second control block is coupled to the bulk third output terminal, with a mass input of the D / A converter whose output is coupled to the fourth output terminal, the mass fourth output of the second control block is coupled to the mass input of the indication block, and the fifth output of the second control block is coupled to the fifth output terminal. This connection uses the method of measurement according to MS. 26O 691.

The advantage of wiring is that the accuracy and stability of the measurements depend on a limited number of components - the first and second capacitor. The first capacitor may not be accurate, but must be stable in time and temperature. The second capacitor must be stable in time but temperature dependent as it acts as a temperature sensor. The wiring does not contain any adjusting elements nor does it require that all electrodes have a capacity of one electrode greater (or less) than the capacity of the other

CS 273232 Bi electrodes. A further advantage is that the transmission of information between the first and second control blocks is that the transmission of information between the first and second control blocks or the first output terminal is done by two conductors, both facilitating galvanic separation of the gauge and secondly distances from the evaluation and indication circuits. Finally, if a membrane vacuum gauge is used in a computer controlled technological device, it can take over the function of the second control block, D / A converter, indication block and parameter entry block and replace it, so that the entire wiring is greatly simplified.

A particular example of a diaphragm vacuum gauge of the present invention is shown in the block diagram of the attached drawing. The computer-replaceable part of the process equipment is graphically separated by a thick broken line.

The wiring consists of a first input terminal 12, a second input terminal 13, a first capacitor C1, a second capacitor Cm, an analog multiplexer 2, a first multivibrator J, a second multivibrator 4., a first counter 5, a second counter 6, a first control block 7, a second control block 8, D / A converter 9, indication block 10, parameter input block 1, first output terminals 14, second output terminals 15, bulk third output terminals 16, fourth output terminals 17, and fifth output terminals 18.

The first output terminal 12 is coupled to the first input 21 and simultaneously to the sixth input 26 of the analog multiplexer 2. The second input terminal 13 is coupled to the second input 22 and simultaneously to the fifth input 25 of the analog multiplexer 2. Between the common conductor and the third input 23 and at the same time, the eighth input 28 of the analog multiplexer 2 is coupled to the first capacitor C1. A second capacitor C1 is connected between the common conductor and the fourth input 24 and at the same time the seventh input 27 &quot; of the analog multiplexer 2. The first output 211 of the analog multiplexer 2 * is connected to the input 31 of the first multivibrator 3, whose output 32 is connected to the first input 51 of the first counter 5. The second output 212 of the analog multiplexer 2 is connected to the input 41 of the second multivibrator 4 whose output 42 is The collective first output 53 of the first counter 5 is coupled to the bulk first input 71 of the first control block 7 and the second output 54 of the first counter 5 is coupled to the second input 72 of the first control block 7. The bulk first output 63 of the second counter 6 is coupled to the bulk third input 73 of the first control block 7 and the second output 64 of the second counter 6 is coupled to the fourth input 74 of the first control block 7. The first output 75 of the first control block 2 is coupled to the second input 52 of the first counter 5 and simultaneously to the second input 62 of the second counter 6. The second output 76 of the first control block 7 is coupled to the ninth input 29 of the analog multiplexer 2. is coupled to the tenth input 210 of analog multiplexer 2. The fourth output 78 of the first control block 7 is coupled to the first output terminal 14 and simultaneously to the first input 81 of the second control block 8. The bulk output 11 of the parameter entry block 1 is coupled to the collective second input 82 of the second control block 8. The first output 83 of the second control block 8 is coupled to the second output terminal 15. The bulk second output 84 of the second control block 8 is coupled to the bulk third output terminal 16. The bulk third output 85 of the second control block 8 is coupled to the D / A converter input 91 9, whose output 52 is coupled to the fourth output terminal 17. Bulk The fourth output 86 of the second control block 8 is coupled to the bulk input 101 of the indication block 10. The fifth output of the second control block 8 is coupled to the fifth output terminal 18.

The dipstick electrodes are connected to the first input terminal 12 and the second input terminal 13 The dipstick diaphragm is connected to a common conductor (ground). The first capacitor C _K is designed for autocalibration of the device, the second capacitor C _T is used for temperature measurement. The upstream input 29 and the tenth input 210 of the analog multiplexer 2 ~ are address inputs. The logic signals can be used to create four combinations: first, the first gauge measuring electrode 2 can be connected to the first output 211 of the analogue multiplexer 2, while the second gauge measuring electrode can be connected to the second output 212 of the analogue multiplexer 2, or

CS 273232 B1 second, it is possible to connect the second dipstick measuring electrode to the first output 211 of the analog multiplexer 2 and at the same time connect the first dipstick measuring electrode to the second output 212 of the analog multiplexer 2, or and also to a second output 212 of the analog multiplexer 2 to connect terminal second capacitor C _T, and finally, fourthly, it is possible to first output 211 of the analog multiplexer 2 to connect terminal second capacitor C _T, while the second output 212 of the analog multiplexer 2 to connect terminal of the first ^- the capacitor C _R . The frequency at the output 32 of the first multivibrator 2 and the frequency at the output 42 of the second multivibrator 4 are proportional to the connected capacity.

The measurement takes place in three or four phases. In the first phase, the frequency of the first multivibrator 3 is determined by the capacity of the first dipstick measuring electrode, the frequency of the second multivibrator 4 is determined by the capacity of the second dipstick measuring electrode. In a second phase, the frequency of the first multivibrator 2 is determined by the capacity of the second gauge measuring electrode, the frequency of the second multivibrator 4 is determined by the capacity of the first gauge measuring electrode. This phase can be omitted depending on the control algorithm. In the third phase, the frequency of the first multivibrator 3 determines the first capacitor Cg, the frequency of the second multivibrator 4 determines the second capacitor C ^. In the fourth phase, the fraction of the first multivibrator 2 determines the second capacitor Cg, the frequency of the second multivibrator 4 determines the first capacitor Cg. The sequence of phases can be arbitrary and is determined by the logic signals on the ninth and tenth port 29.

210 analog multiplexer 2.

The pulses from the first multivibrator 2 are applied to the first input 51 of the first counter 5, the pulses from the second multivibrator 4 are applied to the first input 61 of the second counter 6. The first counter 5 and the second counter 6 operate as a frequency divider. Therefore, at the second output 54 of the first counter 5, the frequency is n times lower than at its first input 51, and similarly to the second counter 6,

The operation of the individual elements during each phase is identical. The value of δ t (the time during which the first and second counters 5, 6 count pulses) may vary for each phase in general, but it is desirable that this value be the same for the first and second phases and also for the third and fourth phases.

At the beginning of the phase, the pulse input to the first and second counters 5, 6 is blocked by a signal at their second input 52, 62. The first block 7 of the control of the combination of logic signals at its second and third outputs 76, 77 determines the phase. By its collective first input 71, the first control block 7 reads the state of the first counter 5, reads the state of the second counter 6 by its collective third input 73. Subsequently, the first control block 7 with its first output 75 for 4t unlocks the first and second counters 5, 6 and at their second outputs 54, 64 will generate higher order transmissions. The first control block 7 counts the number of pulses from the first and second counters 5, 6 at its second and fourth inputs 72, 74. After the time has elapsed, the first control block 7 again blocks its pulse input to the first and second counters 5,6 and its it reads the status via its bulk first and third inputs 71, 73. ~ This completes the phase. The first and second counters 5, 6 serve to enable the first and second multivibrator 2, 4 to operate at a higher frequency than the first control block 7 is able to process at its second and fourth inputs 72, 74. This increases the speed or accuracy of the measurement.

The resultant counts of the pulses are stored in the memory of the first control block 7 after the completion of all four measurement phases:

c ^ - corresponding to the capacity * first measuring electrode dipstick multivibrator 2 ^»C 12" rápovíúaJíoí capacity of the first measuring electrode dipstick multivibrator 4 ^C 21 "° ůpovíčající capacity of the second measuring electrode gauge as measured by the first measurement with the second measurement with the first

EN 273 232 Bl multivibrator 3, ^C 22 'corresponding · capacity of the second measuring electrode gauge as measured by the second multivibrator 4, ^C K1 ~ ^0l3 P ^{0 V} I ^D ající capacity of the vibrator 2, ^C K2 "° dp ° ⁱⁿ íůající capacity of vibrator 4, c , ^ - corresponding to the vibrator capacity 2. θ ° T2 “corresponding to the vibrator capacity 4.

first capacitor C ^, first capacitor C ^, second capacitor C ^, second capacitor C _T , measured 3 using the first multi · measured with the second multi measured with the help of the first multi measured with the second multi

The first control block 7 transmits this information at its fourth output 78 to the first output terminal 14 and at the same time to the first input 81 of the second control block 8. The second control block 8 'then calculates the actual pressure value by correcting the measured pressure as a function of the measured temperature and the measured calibration value. It uses the stored calibration values c1 and _k2 obtained during the initial calibration of the vacuum gauge. With the help of -c KL: c _Tfl and _K2 : c _{K2, it} divides the respective measured values of temperature and pressure, thus correcting the change of the alignment parameters (aging of the resistors, change of supply voltages, etc.). The calculated temperature and pressure values are compared with the temperature and pressure table obtained during the initial calibration of the vacuum gauge and the pressure calculation is performed. The measured value of pressure and temperature respectively of the limit and emergency states is transmitted by the second control block 8 by its first output 83 to the second output terminal 15 in the form of a serial signal and by its collective second output 84 to the collective third output terminal 16 in the form of parallel signal. It sends the measured pressure value to the second control block 8 with its collective third output 85 to the common input 91 of the D / A converter 9, which then generates at its output 92 an analogue signal proportional to the fourth output terminal 17. the fourth output 86 signals for controlling the indication block 10 and also transmits to it the measured values of pressure and temperature respectively and the occurrence of emergency conditions (pressure out of range, temperature out of range etc.).

Parameter input block 1 is used to transmit operator information such as upper allowable pressure limit, lower allowable pressure limit, serial transfer rate at second output terminal 15, unit selection (torr, Pa, mm Hg) and the like. The information is transmitted via the bulk output II to the bulk second input 82 of the second control block 8.

The fifth output 87 of the second control block 8 operates as a level switch whose limits are determined by the upper allowable pressure limit and the lower allowable pressure limit.

Claims (2)

SUBJECT OF THE INVENTION 1, Diaphragm vacuum gauge wiring consisting of input terminals, capacitors, analog multiplexer, multivibrator, counters, control blocks, D / Λ converter, indication block, parameter input block and output terminals, characterized in that the first input terminal (12) is connected to the first input (21) and simultaneously to the sixth input (26) of the analog multiplexer (2), the second input terminal (13) being coupled to the second input (22) and the fifth input (25) of the analog multiplexer (2) between the common conductor and the third input (23) and the eighth input (28) of the analog multiplexer (2) are connected to the first capacitor (C ^) between the common conductor and the fourth input (24) and the seventh input (27) of the analog multiplexer (2) a second capacitor (C ^) is connected first CS 273232 B1 output (211) of the analog multiplexer (2) is connected to input (31) of the first multivibrator (3), whose output (32) is connected to the first input (51) of the first counter (5), the second output (212) of the analog the multiplexer (2) is connected to the input (41) of the second multivibrator (4), whose output (42) is connected to the first input (61) of the second counter (6), the collective first output (53) of the first counter (5) is connected to the collective first input (71) of the first control block (7), the second output (54) of the first counter (5) is connected by 3 second input (72) of the first control block (7), the collective first output (63) of the second counter (6) is connected to the collective third input (73) of the first control block (7), the second output of the second counter (6) is coupled to the fourth input (74) of the first control block (7), the first output (75) of the first control block (7) is coupled with a second input (52) of the first counter (5) and simultaneously with a second input (62) of the second counter (6), the second output (76) of the first control block (7) is connected to the ninth input (29) of the analog multiplexer (2), the third output (77) of the first control block (7) is connected to the tenth input (210) of the analog multiplexer (2) and the fourth output (78) of the first control block (7) is coupled to the first output terminal (14). 2. The diaphragm vacuum gauge according to claim 1, characterized in that a first input (81) of the second block (8), the bulk output (12) is connected between the fourth output (78) of the first control block (7) and the first output terminal (14). 11 / block / 1 / parameter input is connected to the collective second input / 82 / of the second control block / 8 /, the first output / 83 / of the second control / block / 8 / is connected to the second output terminal / 15 /, the collective second output / 84 / second block (8) of the control is connected to the collective third output terminal (16), the collective third output (85) of the second control block (8) is connected to the collective input (91) of the D / A converter whose output / 92) is coupled to the fourth output terminal (17), the collective fourth output (86) of the second control block (8) is coupled to the collective input (101) of the indication block, and the fifth output 1 & by the fifth output terminal (18).