CS262212B1 - Arrangements for electronical switching of arbitrary number of measuring points - Google Patents

Description

In industrial practice, especially in the chemical and power industries, it is often encountered with the requirement to measure the temperature of a production plant at regular intervals and in tens of places equipped with resistance thermometers from a single control station. So far, mechanical contacts have been used to switch measuring points, which are designed as «manual measuring point switches or as electrical relays.

The disadvantages of these connections are the relatively high purchase costs and considerable maintenance costs, since the contacts need to be cleaned in time. Furthermore, constant measurement accuracy is not guaranteed, as transient resistances on individual contacts lead to measurement errors over time.

More recently, it is also known to electronically switch measuring points with resistance thermometers according to Czechoslovakian Patent No. 241 939. The advantage over the use of mechanical contacts is, first of all, a significant reduction in the cost of circuit acquisition. In the long-term operation of the electronic switching of the resistance temperature sensor locations of the present invention, it has been found that, under certain operating conditions, for example, when the thermowells for resistance temperature sensors are flooded and frozen, .

The rectangular well is then conductively connected to the frame of the other technology equipment. If the galvanic voltage of more than one resistance temperature sensor rises, the measured temperature is incorrectly evaluated on all connected resistance temperature sensors, since their individual supply lines are connected to each other by means of the measuring and compensating branches of the evaluation device.

These drawbacks are eliminated by the circuitry for electronic switching of any number of measuring points with resistance thermometers according to the invention, which is based on the fact that the resistance temperature sensors are connected to an evaluation device and two stabilized hapthe sources via two switching transistors in inverted three-wire connection.

The first conductor connects the resistance temperature sensor to the measuring arm of the evaluator262212 through the first adjustment resistor and the first switching transistor in inverse wiring, the second conductor to the compensating branch of the evaluating device through the second adjustment resistor and the second switching transistor by Inverse wiring and finally the third wire through a forward diode to the power supply line of the evaluation device.

The positive branch of the first stabilized power supply is coupled through the first working diode and the first double actuator to the collector of the first excitation transistor and simultaneously through the second double actuator and the first working resistor based on the first excitation transistor. The emitter of the first excitation transistor is connected through a first ballast resistor based on the first switching transistor, to the collector of which the negative branch of the first stabilized source is connected. The positive branch of the second stabilized source is coupled via the second working diode and the first double actuator to the collector of the second excitation transistor, simultaneously through the second double actuator and the second working resistor based on the second excitation transistor.

The emitter of the second excitation transistor is connected via a second upstream resistor to the throw of the second switching transistor, to whose collector a negative branch of the second stabilized source is connected. Further, a first parallel resistor is connected between the emitter of the first excitation transistor and the collector of the first switching transistor. Similarly, a second parallel resistor is connected between the emitter of the second excitation transistor and the collector of the second switching transistor. A protective diode is connected in the forward direction between the power supply and the compensating branch of the evaluator and two protective diodes are connected in series between the power supply and the measuring branch.

The circuit according to the invention makes it possible to replace individual mechanical contacts with pairs of silicon switching and excitation transistors in inverse wiring whose operating points are set to the minimum saturation voltage level, while the excitation transistors function as a logic product for both double actuators. Individual pairs of switching and excitation transistors are paired according to the minimum saturation voltage under given operating conditions and any differences are corrected by adjustment resistors. The temperature changes of the minimum supply voltage are compensated for by each other.

By connecting protective diodes, the switching transistors are protected against the creation of an unauthorized voltage. The separating diodes ensure galvanic separation of the power supply of the evaluation device from all other resistance temperature sensors connected in the system.

The advantages of the circuitry according to the invention are roughly half the cost compared to the mechanical systems used to switch measuring points with resistance thermometers up to now, as well as stability in measuring accuracy, minimal maintenance and the possibility of direct connection of various switching elements such as digital circuits, output computer ports and the like.

Advantages of the connection according to the invention in comparison with the known electronic systems of measuring point switching are firstly the possibility of decadic choice of the given resistance temperature sensor, which results in savings on the acquisition of especially large measuring systems with many tens of measured points and total resistance against foreign disturbing voltages. results in increased accuracy and reliability of measurement.

An example of the connection according to the invention is shown in the attached drawing, for simplicity, only one measuring point has been drawn, with the switch being shown in the on position for measuring the temperature at a given measuring point.

In a particular embodiment, the circuit according to the invention for measuring the temperatures at the individual measuring points of the manufacturing apparatus was performed as follows.

Digital indicator D 377 was used as the evaluation device 5, two stabilized 5 V DC power supplies equipped with MAA 723 integrated circuits were used as the first stabilized source 18 and the second stabilized source 21, and resistance thermometers Pt 100 were used for resistance temperature sensors 1. each connected by three conductors of the same material, the same cross-section and the same length.

The first conductor is connected to the measuring branch 4 of the evaluation device 5 via a first adjustment resistor 2 and a first switching transistor 3 of the KFY 34 type in an inert connection. The second conductor is connected to the compensating branch 8 of the evaluation device 5 via the second adjustment resistor 6 and the second switching transistor 7 of the KFY 34 type in inverse connection. The third conductor is connected via a diode 9 of the KA501 type to the supply line 10 of the evaluation device S.

On the basis of the first switching transistor 3, the emitter of the first excitation transistor 12 of the KC 147 type is connected via the first ballast resistor 11, similarly on the basis of the second switching transistor 7 the emitter of the second excitation transistor 14 of the KC 147 type is connected. the resistor 11 and the second series resistor 13 are of the TR 193 type and their ohmic value is determined by the magnitude of the excitation currents of the first switching transistor 3 and the second switching transistor 7 so as to guarantee a minimum saturation voltage between their emitters and collectors.

The first working resistor 22, the second working resistor 24, the first parallel resistor 28a

282212 the second parallel resistor 2Sr is <in a particular embodiment of type TR 114 5K6. A first parallel transistor 28 is connected between the emitter of the first excitation transistor 12 and the collector of the first switching transistor 3, a similarly rough parallel resistor 29: is connected between the emitter of the second excitation transistor 14 and the collector of the second switching transistor 7.

The first parallel resistor 28 provides a reliable trip of the first switching transistor 3 in its non-conductive state, as well as the second parallel resistor 29 provides a reliable trip of the second switching transistor. 7 in its non-conductive state. The first excitation transistor 12 and the second excitation transistor 14 are connected so as to form the product logic boat. whose control inputs are collector and base. When the first, double actuator 13 and second double actuator 23 are used simultaneously, the first excitation transistor 12 and the second excitation transistor 14, 'decimal', make it possible to select a given resistance temperature sensor 1.

The first working diode 18 and the second working diode 19 of the KA'501 type are connected in the forward direction and provide a predetermined voltage between the collector of the first, transistor 12 and the positive branch 17, the first stabilized source 18, similarly between the collector of the second excitation transistor 14 and the positive branch 2a. second stabilized source. 21. KA 501 protection diodes 27 are connected in the forward direction and prevent exceeding the permissible closing voltage of the first switching transistor 3 and the second switching transistor 7 in their inverse connection when the first, double control 15 and second double control are switched off. 23, when a voltage of up to 30 V is generated between the supply line 10 and the compensation line 8 of the evaluation device 5 as well as the compensation line 8a, the measuring line 4 of the evaluation device S, which would damage the first switching transistor 3 and the second switching transistor 7 their inverse connection.

The first excitation current flows from the positive branch 17 of the first stabilized source 18 through the first working diode 18 and the first double actuator 15 to the collector of the first excitation transistor 12, but simultaneously from the same positive branch 17 of the first stabilized source 18 through the second double actuator 23 and the first working a resistor 22 based on the first excitation transistor 12. The first excitation circuit is closed from the emitter of the first excitation transistor 12 via the first upstream resistor 11 and the base-collector transition of the first switching transistor 3 to the negative branch 25 of the first stabilized source 18.

The second excitation current flows from the positive branch 20 of the second stabilized source 21 through the second working diode 19 and the first double actuator 15 to the collector of the second excitation transistor 14, but simultaneously from the same positive branch 20 of the first stabilized source 21 through the second double actuator. - a stiff working resistor M: not at the base of the second excitation transistor 14;

The second excitation circuit is closed from the emitter of the second excitation transistor U across the second series. resistor 13 and base • junction collector of the second switching transistor · 7. The value of the excitation currents for each of the first switching transistor 3 and the second switching transistor 7, respectively, is set. Individually by the first ballast resistors 11 and the second ballast resistors 13 so as to guarantee a minimum saturation voltage between emitters and collectors of the first switching transistors 3 and the second switching transistors 7 at a given fixed switching current.

If it is increased, the excitation current set in this way, then the saturation voltage of the switching transistor will always be increased. The first adjusting resistor 2 and the second adjusting resistor 6 serve, using the ejector 5 type D 377 ', to be withdrawn with a leased supply current for the measuring bridge to achieve the same overall resistance of the measuring line 4 of the evaluation device 5 and the compensating resistor. the branch 8 of the evaluation apparatus 5, including the resistance which is. given by the value of the transient voltage between the emitter and the collector of the first switching transistor 3 h and one side, as well as the value of the transient voltage. emitter and collector of the second switching transistor 7 ‘on the other side.

After switching on the double control elements 15 'and the second control element 23 in the described connection. it closes the electrical ohm and current, which starts to flow between the collector and the emitter of the switching transistor 3 and between. the collector and emitter of the switching transistor 7 electronically connects the temperature sensor 1 to the evaluation unit 5. The KA 501-type separation diode 9 is connected in the forward direction and ensures galvanic separation of the branch 10 of the evaluation unit 5 from the other temperature sensor 1. other measured points in the system.

No current flows through the protective diodes 27 when evaluating the temperature. Only when one is disconnected. the excitation currents flowing into the first switching transistors 3 or the second switching transistors 7 are interrupted from the first double actuators 15 or the second double actuators 23, and the current of the measuring string 4 or the compensating string 8 of the evaluating device 5 starts to flow through the protective diodes 27 generating the highest voltage on the first switching transistors 3 and the second switching transistors 7, respectively, in their inverse connection.

By using a different number of protective diodes 27 connected in series between the power supply line 10 and the compensation line 8 of the evaluation apparatus 5 on the one hand and between the compensation line 8 and the measuring line 4 of the evaluation apparatus 5 on the other All resistance temperature sensors 1 will evaluate the maximum value just as an indication of disconnection of all resistance temperature sensors. Subsequently, it is possible to connect electronically to the evaluation device 5 any other resistance temperature sensor 1 in the measuring system by means of the decimal choice by means of the respective first double operating elements 15 and the second double operating elements 23.

Claims (1)

SUBJECT Circuit for electronic switching of any number of measuring points with resistance thermometers, using an evaluation device for three-wire connection, switching transistors with separate excitation circuits and two independent stabilized DC voltage sources, characterized in that during measurement the resistance temperature sensor (1) is connected through the first conductor a first adjustment resistor (2) and an inverse connected first switching transistor (3) to the measuring branch (4) of the evaluation device (5), a second conductor through the second adjustment resistor (6) and an inverse connected second switching transistor (7) to the compensation branch (8) ) of the evaluation device (5), by a third conductor via a separating diode (9) to the power branch (10) of the evaluation device (5), the excitation branch of the first switching transistor (3) being connected to the emitter via a first resistor (11) the first excitation transistor (12), the excitation branch of the second switching transistor (7-} is connected via a second series resistor (13) to the emitter of the second excitation transistor (14J), the collector of the first excitation transistor (12) is connected via the first double actuator (15) and a first working diode (16) on the base branch (17) of the first stabilized source (18), similarly to the collector of the second excitation transistor OF THE INVENTION (14) is connected via a first double operating element (15) and a second working diode (19) to a positive branch (20) of a second stabilized power supply (21), the base of the first excitation transistor (12) being connected via a first the working resistor (22) and the second two-wound actuator (23) on the positive branch (17) of the first stabilized power supply (18), likewise the base of the second excitation transistor (14), is connected via the -drive working resistor (24) and a second double control element (23) on the balance beam (20) of the second stabilized power supply (21), the negative branch (25) of the first stabilized power supply (18) is connected to the collector of the first switching transistor (3) and negative the branch (26) of the second stabilized power supply (21) is connected to the collector of the second switching transistor (7) with the connection between the supply branch (10) and the measuring branch (4) of the evaluation device (5) connected in series protective diodes (27), between the compensating branch (8) -am one protection diode (27) is connected in the forward direction between the emitter of the first excitation transistor (12) and the collector of the first switching transistor (3) is connected with the first parallel resistor (28J) between the emitter of the second excitation transistor (12). 14) and the collector of the second switching transistor (7) is connected with a parallel parallel resistor (29).