SE439739B - METHOD DEVICE FOR DETERMINING THE CURRENT TIME OF BINDING MATERIAL IN NUCLEAR PASS - Google Patents

Description

8200333-6 2 is to provide a measuring device for determining the curing time for binders in core mixtures, which is provided with such additional units, which make it possible to increase the measuring accuracy and reduce the work effort in the measurement.

This object is achieved by means of a mains device for determining the curing time of binder (binder material) in core mixtures, which measuring device comprises a vessel which is filled with a sample body of sample material and placed in a heating furnace, a measuring sensor for electrophysical quantities which forms an analog signal for example. a voltage proportional to the value of the quantity being measured, such as, for example, the electrical conductivity of the test material or the electromotive force between the sensing electrodes in contact with the test body, a unit for measuring the analogue analog signal provided with an indicator for indicating the value of the quantity, a unit for measuring the temperature in the furnace, and a start and stop unit connected to the vessel in the furnace and the unit for measuring the analogue of the measuring sensor, the measuring device for measuring the analog signal, according to the invention, further comprises a converter for converting the analogue signal of the measuring sensor to a digital code, the unit for measuring the temperature in the oven, the starting and stopping unit and the indicating means being electrically connected to the converter.

It is suitable that the converter for converting the analog signal from the measuring sensor to a digital code comprises in series a unit for converting the analog signal from the measuring sensor, a unit for recording the curing time of the sample material, a memory unit, a unit for recording the time between the measurements of the values. on the electrophysical quantities, as well as a data display unit, to which the signal conversion unit, the unit for recording the curing time of the specimen and the memory unit are connected, a pulse generator which is connected to the unit for recording the curing time of the specimen and the unit for recording the time between the measurements of the values of the electrophysical quantities, and interconnected a control unit and a comparison unit for adjusting the values of the electrophysical quantities measured at different times, the unit for recording the time between the measurements of the values of the electrophysical quantities in addition, it is connected to the unit for recording the curing time of the specimen, and the control unit is connected to the signal conversion unit 8200333-6 3, the unit for recording the curing time of the specimen and the memory unit, which is also connected to the signal conversion unit, and the comparison unit is connected to the recording unit. of the curing time of the specimen.

It is suitable that the signal conversion unit comprises a primary converter connected to the sensor and an analog-to-digital converter connected to it and to the control unit.

It is furthermore suitable that the unit for recording the curing time of the test body comprises in series a former for forming single pulses, a rocker, an AND main gate and a counter for calculating the curing time of the test body and in an additional AND gate, one input of which is connected to an additional input of the AND gate and connected to the pulse generator, a moment counter, a main commutation unit and a circuit for controlling the data output, the other input of which is connected to the input of the shaper and the other input of the counter and connected to the control unit, a further input of the data output control circuit being connected to a further commutation unit, one input of which is connected to another, to a time registration counter and input of the main commutation unit, that the second input of the rocker, the second input of the additional AND gate and instantaneous time count the second input of the array is connected to the control unit, while the output of the flip-flop is connected to the memory unit, the input of the time registration counter, an additional input of the additional commutation unit and an end input of the data output control circuit being connected to the measuring time recording unit. - the values of the electrophysical quantities, the signal conversion unit and the unit for comparison of the values of the electrophysical quantities, respectively.

It is suitable that the memory unit comprises in series a main shaper for forming single pulses, the input of which is connected to the rocker in the unit for recording the curing time of the specimen, partly an OR main gate, partly a main delay element, partly a rocker and partly a further shaper for forming individual pulses and on the one hand a main memory register, the second input of which is connected to a further OR gate, one input of which is connected to the input of the main delay element, and comprises a further delay element, the input of which is connected to the second input of the flip-flop. 6 4 and connected to the unit for recording the time between the measurements of the values of the electrophysical quantities, and two further memory registers, one input of one additional memory register being connected to the main shaper, while one input of the other further memory register is connected to the additional OR gate and its second input is interconnected with the input of the additional delay element, while the further inputs of the main register and the additional registers are interconnected and connected to the analog-to-digital converter in the signal conversion unit, while a further input of the OR main gate and the output of the additional delay element are connected to the comparison unit. , while the input of the additional OR gate is connected to the control unit.

It is also suitable that the unit for recording the time between the measurements of the values of the electrophysical quantities comprises in series partly an AND gate, the inputs of which are connected to the pulse generator and the flip-flop in the memory unit, respectively, and a counter which is connected to a presetting sensor, wherein an additional input of this counter is connected to the additional OR gate of the memory unit, partly a decoder and partly a former for forming individual pulses.

It is preferred that the control unit comprises on the one hand a main threshold element which is connected to one input of the AND main gate, on the other hand a further threshold element which is connected to the other input of the AND main gate and to one input of an additional AND gate and a former for forming individual pulses which are connected to a further input of the AND main gate, partly a flip-flop, the output of which is connected to the input of the former for forming single pulses and to the second input of the further AND gate, and partly an OR gate, one input of which is connected to one input of the rocker and connected to the start and stop unit and the other input of which is connected to the comparison unit, the inputs of the main threshold element and the additional threshold element being connected to the unit for measuring the temperature of the heating furnace and to the primary converter in the signal conversion unit. The invention makes it possible to automatically determine the curing time for binders in core mixtures, which helps to reduce the work effort in the measurement and to increase the accuracy of the measurement results. In addition, with the device according to the invention, the data obtained can be entered into an electronic computer, ___. Jf "'J" ___ V _ \ _____-_. A - <- "" __ _ ,. »_-; 1f-w -1 ..-- í '. »._ .vs vas ve _, 1 ___... - 8200333-6 5 for the further processing and use of data in systems for controlling technological processes for the production of nuclear mixtures and cores.

The invention enables the processing of all the data obtained, whereby the measuring device can output the end result in finished form.

BRIEF DESCRIPTION OF THE DRAWINGS The invention is described in more detail below with reference to the accompanying drawing, in which Fig. 1 shows a block diagram of the measuring device according to the invention for ignition or the inside of binders a characteristic mixtures (the heating furnace is shown in section Fig. 2 shows a block diagram of a converter for converting electrophysical parameters, Fig. 3 shows a block diagram of a signal conversion unit, Fig. 4 shows a block diagram of a unit for recording the curing time of a test body being tested, Fig. 5 shows a block diagram of a memory unit, Fig. 6 shows a block diagram of a measuring interval presetting bit for electrophysical parameters and Fig. 7 shows a block diagram of a control unit.

Preferred embodiment of the invention The measuring device for determining the curing time for blends comprises a heating furnace 2 arranged on a foundation 1 (Fig. 1), in which a container 3 with a test body, for example a core mixture 4, to be tested, is placed. The container 3 is hereinafter referred to as the sleeve 3. Through holes, which are accommodated in the lid 5 of the furnace 2 and in the lid 6 of the sleeve 3, a sensor 7 for electrophysical parameters is passed in contact with the test body 4. The oven 2 is intended to be heated by means of heating elements 8 built into the oven body. The inside of the oven 2 is connected to a unit 9 for measuring the temperature of the heating oven 2. Arranged on the foundation 1 is a starting and stopping unit 10, which is connected to the sleeve 3.

The measuring device further comprises a unit 11 for measuring the test specimens electrophysical parameters, which unit comprises a means 12 for indicating electrophysical parameter values and a converter 13 connected to the indicating means 12 for @ 1GkÜr0phybical parameters, which is connected to the sensor 7 and the units 9 and 10. The indicating means 12 is provided with an independent output 14, to which a recording device (not shown in the drawing) can be connected.

The electrophysical parameter converter 13 comprises in series a signal conversion unit 15 (Fig. 2), a unit 16 for recording the curing time of the smooth sample being examined, a memory unit 17 and a measuring interval presetting unit 18 for electrophysical parameters. The units 15, 16 and 17 are connected to a data indicating unit 19. The unit 15 is connected to the unit 17, while the unit 16 is connected to the unit 18. The units 16 and 18 are connected to a pulse generator 20. The converter 13 further comprises a control unit 21 and a unit 22 connected thereto for comparison of electrophysical parameter values (parameters). The unit 21 is connected to the units 15, 16 and 17, while the unit 22 is connected to the units 16 and 17. The signal conversion unit 15 (rigs 2 and 3) comprises a primary converter 23, its output 24 is connected to a input 26 of an analog-to-digital converter 25 and its input 27 are connected to the sensor 7, while the output 24 of the converter 23 and the input 28 of the converter 25 are connected to the unit 21 of the converter 13. The output 29 of the converter 25 is connected to the unit 19 and its output 30 is connected to units 16 and 17.

The unit for recording the curing time of the tested specimen comprises a former 31 (Fig. 4) for forming single pulses, which is connected to an input 33 of a rocker 32, its output being connected to an input 34 of an AND gate. 35, its output is connected to a counter 36 for counting the cured time of the examined sample body. The unit 16 further comprises a further AND gate 37, the input 38 of which is connected to the OH gate of the gate 39 and a gate to the peel generator 20. AND the gate 37 is connected to a counter 40, the output of which is connected to an input 42. of a main commutation unit 41, which is connected to an input 44 of a circuit 43 for controlling the data output. The input 45 of the circuit 43 is connected to a further commutation unit 46. The inputs 47 and 48 of the units 41 and 46, respectively, are interconnected in an interconnection point 49, which is connected to a time registration cleaner 50. The shaper 31, the counter 36 and the circuit 43 inputs 51, 52 reepeknve 53 are hepkeppleee in a pep coupling point 54. The inputs 55, 56 and 57 of the rocker 32, AND gate 37 and the counter 40 are connected to the unit 21. The unit 46, the counter 50 and the circuit 43 lpgåmger 58. 59 and eo are connected to units l5, 18 and 22 respectively.

The memory unit 17 comprises a main shaper 61 (Fig. 5) for forming single pulses, which is connected to an input 63 of an OR gate 62, which is connected to interconnected inputs 64 and 65 of an additional OR gate. 66 and of a main threshold element 67, which is connected to an input 69 of a flip-flop 68, their input 70 is connected to an input 71 of an additional threshold element 72 at an interconnection point 73. which is Kepplea, the unit wants to smile. vlppene see output 74 is coupled to an input 75 of a further shaper 76 for forming single pulses, which is connected to the input 78 of a main memory register 77. The shaper 61 and the connection point 73 are connected to inputs 79 and 80, respectively, of additional memory registers B1 and 82, respectively. The register 77 een sa included 83 reepexelve al »is nepkeppleae 1 an interconnection point 85 and connected to the OR gate 66.

The registers 81, 77 and 82 inputs 86, 87 and 88, respectively, are connected at an interconnection point 89 and connected to a switch. vw p. \., f \.-'-_ h \, d vu ... w Lin * CI.

»Mb Ü I 8200333- 6 10 15 20 25 30 35 the output 25 of the converter 30. The registers 81 and 82 inputs 90 and 91, respectively, are connected to the unit 19. The inputs 92 and 93 of the 62 gate branches 62 and 66, respectively, are connected to the units 22 and 93, respectively. 21.

The measuring interval presetting unit 18 for electrophysical parameters comprises an AND gate 94 (Fig. 6), which is connected to an input 96 of a counter 95, its input 97 being connected to a presetting sensor 98. The latch 95 is connected to an input 100 of a decoder 99, which is connected to an input 102 of a single pulse shaper 101, the inputs 103 and 104 of the UCH gate 94 are connected to the output 74 of the generator 20 and the flip-flop 68, respectively (Fig. 5).

The input 105 (rig. 6) of the counter 95 is connected to the output of the OR gate 66 (Fig. 5) at the connection point 85.

The control unit 21 comprises a main and a further threshold element 106 and 107, respectively (Fig. 7), which are connected to inputs 108 and 109, respectively, and an AND main gate 110, each input III is connected to a single pulse former 112. . The element 107 is connected to an AND gate 115 input 114, which is interconnected with AND gate 110 input 109 at an interconnection point 113.-Formerene 112 with AND gate 115 input ll? interconnected input 116 is connected to a rocker 118 with inputs 119 nen leo, of which the input 119 is non-connected to inputs 121 and 122 of an ELEER gate 123. The measuring device for determining the curing time for binders and core mixtures operates on the following way.

After the sleeve 3 (Fig. 1) with the examined test body (core mixture) 4 has been placed in the heating furnace 2, the start and stop unit 10 is actuated at the same time as the unit 11 for measuring the electrophysical parameters of the test body 4 is switched on. A signal from the unit 10 is then transmitted to the converter 13 for electrophysical parameters, which are simultaneously fed with output signals from the sensor 7 and the unit 9 for measuring the temperature of the heating furnace. The data partially processed in the transducer 13 is fed to the means 12 for indicating electrophysical parameters and at the same time to one output of the transducer 13, which functions as the output of the measuring device. This data can in future be used in an electronic computer for controlling process processes for the production of core mixtures and cores. From the second output of the converter 13, as the second output of the measuring device, the completely processed data is output. which was used to control the curing of the core mixture.

The converter 13 for converting electrophysical parameters works as follows.

An output signal from the unit 10 (Figs. 1, 2) is supplied to the control unit 21, which outputs to the signal conversion unit 15 an order signal for initiating the measurement. The unit l5, which is fed with the output signal from the sensor 7, begins the measurement and the conversion of the measurement results. The output signal from the unit 15 is transmitted to the unit 16 for recording the curing time of the specimen and to the data indicating unit 19. The unit 16 registers 1 depending on order signals from the unit 21 an initial value of the electrophysical parameter of the examined specimen 4 and transmits data to the unit 19 , the memory unit 17 and, if required, to an electronic computer for the continued use of data in a process flow control system. Since the unit l? received and stored the first measurement result for the electrophysical parameters of the specimen 4, it emits an order signal to the measuring interval presetting unit 18 1 and to start the time counting, after which the unit l8 emits to the unit 1? an order signal to store the new value of the body's electrophysical parameters. The unit 17 then starts the unit 22 for comparison of electrophyelical parameters. If _PÛQR in TY Q 8200333-6 10 15 20 25 30 35 10 the cure of the specimen 4 is not completed, the first and second measurement results being compared are not equal to each other. An inequality or difference signal is in this case supplied to the unit 16, which forms reset order signals.

The unit 17 stores the new, first value of the electrophysical parameters of the test body 4 and restarts the unit 18, which begins to count the predetermined time interval. The unit 17 then stores again the second value of the electrophysical parameters of the specimen 4, the comparison unit 22 again making the implementation of the new pair of measurement results.

Before the curing is completed, the results of two successive measurements are not equal to each other, so the measurement cycle is repeated. That the hardening of the specimen 4 is completed is indicated by the fact that the first and the second measurement result during a single measuring cycle for the electrophysical parameters of the specimen 4 are equal to each other. In this case, a similarity signal is transmitted from the unit 22 to the unit 21, which interrupts the operation of (disconnects) the unit 11 for measuring the electrophysical parameters of the examined specimen.

During the entire measuring cycle, the unit 19 indicates the initial and instantaneous values of the electrophysical parameters of the specimen 4. At a time when the curing ceases, the unit 19 indicates the value of the parameter in question which corresponds to the curing being completed. In addition, the unit 19 indicates the time corresponding to the end of the curing, and the instantaneous time. Similar data regarding the values of the test body's 4 parameters and the process time can be entered into an electronic computer. This data is entered even after completion of curing, so that the quality properties of the test specimen 4 can be assessed. In order to completely interrupt the registration of the parameter values of the specimen 4, the unit 10 emits an order signal to the unit 21, which resets the measuring device. The signal conversion unit 15 operates in the following manner. The input 27 (Figs. 8, 3) is fed from the sensor 7 (Figs. 1-3) with a signal which is proportional to the sample body. 4 electrophysical parameters and which are processed by the primary converter 23, via the output 24 of which a signal is generated which, with respect to the electrical parameters, is adapted to the input parameters of the measuring circuits of the analog-to-digital converter 25. The converter 25 converts if an allowable signal from the acid 21 appears across the input 28 - with the desired accuracy and frequency the signal to a numerical code, which is transmitted over the outputs 29 and 30 to the units 16, 17, 19.

The output signal from output 2 # also supplies the unit 21.

The unit 16 for recording the sample curing time operates in the following manner.

After a signal from the unit 21 (Figs. 2, 4) is fed to the input 55 of the flip-flop 32, this is affected, so that a signal is generated over the output of the flip-flop 32, which is led to the unit 17 and the input 34 of the gate 35. AND the gates 35 second input 39 is continuously fed by means of generator 20. The generation of a signal over the input input 34 of AND gate 35 thus enables the pulse servers to be transmitted to the counter 36 for counting the sample body curing time, while the output signal from the counter 36 is fed to the unit 19, where it is indicated. When the signal from the unit 21 is conducted to the input 51, the former 31 for forming individual pules is actuated. A single pulse is generated across the output of the former 31, which is applied over the input 33 of the flip-flops 32 and resets the flip-flop 32, so that the operation of the counter 36 is stopped. At the same time the signal from the unit 21 is fed to the input 56 (Fig. 4) of the AND gate 3. ? it begins to transmit the pulses from the generator 20, which is fed to the second input 38, to the torque timer 40, the state of which (output signal) is supplied to and indicated by the unit 19 and at the same time transmitted over the commutation unit 41 to the input 44 hoe circuit 43 POOR Qezmzii -6 12 for controlling the data output. The counter 40 operates at the same time as the signal appears over the AND grin's J? input 56 and is reset by a signal which is read to the input 57 of the razor 40. ~ The input 45 of the circuit 43 is fed through the commutation unit 46- with a signal from the input 58 of the unit 46, which is connected to the A / D converter 25. output 30 (rig. 3). the jellyfish 43 (rig. 4) is affected by the antigen output signals from the time registration counter 50 or by output signals from the control unit 21 (via input 53) and from the comparison unit 22 (via input 60).

The input 59 of the counter 50 is supplied with signals from the unit 18, the output signal being generated over the counter 50 after a predetermined number of measuring intervals.

The circuit 43 forms - for data input in a computer or a printing device data (not shown) concerning the time value 4 (Fig. 1) of the test body a corresponding period 4 (Fig. 1) and concerning a time, when the function is started, (initial values) after of gg the counter 50 preset (predetermined) time intervals, and at a time when the signal is fed to the input 60 of the counter 50 from the unit 22.

The memory unit 17 operates in the following manner.

When an output signal from the flip-flop 32 is fed to the shaper 61 (Figs. 2, 5) for single pulses, the shaper 61 is affected, so that the memory register 81 is affected. The register 81 stores the state of the output 30 of the converter 25 over its input 86. At the same time the signal is transmitted via the OR gate 6¿ to the input 64 of the OR gate 66 and to the input element 67 of input 65. The signal passes through the OR gate 66 to the memory register 77 82 inputs 83_ respectively 84, while the signal from the element 56 is fed to the input 69 of the flip-flop 68, so that it is actuated, which results in a signal being generated over the flip-flop 68 output 74. This signal is transmitted over the single pulse shaper 76 to re- is ¿I- e., a .. d ä »Qænnï 10 15 20 25 39 35 8200333-6 13 the input 78 of the register 77, so that the state of its input 87 is read into the register 77, after which the signal is routed to the output 22. The output signal from the unit 18 is routed to the interconnection point 73 and at the same time to the input 70 of the flip-flop 68, so that it is reset, and to the input 82 so that the state of its input 88 is read into the register 82, and into - walk a 71, so that the element 72 is affected. The signal from the register 82 is then fed to the unit 22 in the same way as the signal is transmitted from the element 72. The actuating cycle of the OR gates 62, 66, the element 67, 72, the flip-flop 68, the former 76 and the registers 77 and 82 is performed in the same way as the above-described actuation of these components not only by means of the signal from the former 61 but also by means of the signal supplied from the unit 22 to the input 92 of the OR gate 62.

The measuring interval presetting unit 18 for electrophysical parameters operates as follows.

The input 103 of the AND gate 94 (Figs. 2, 6) is continuously supplied with pulses from the generator 20, which, however, can pass to the counter 95 only when the signal appears over the input 104 of the AND gate 94. When this signal occurs, the counter 95 the bill. At the same time as the signal reaches a predetermined amplitude, the counter 95 outputs an order signal to the unit 17 via the decoder 99 and the single pulse shaper 101 (Fig. 5). The signal amplitude at which the counter 95 (Fig. 6) outputs a signal to the decoder 99 determines its operating time and is preset by the preset sensor 98. The counter 95 is reset via the input 104 connected to the OR gate 66 (Fig. 5). works as follows.

When the measuring device is prepared for operation, a predetermined temperature is generated in the heating furnace 2 (Fig. 1), whereby a corresponding signal from the unit 9 for measuring the temperature of the heating furnace is fed to the threshold element 8200335-6 10 \ a '25 25' ao 14 106 (fig. 7) input. If the signal amplitude is not lower than the predetermined one, the element 106 is affected, so that a signal is generated across its output. When the examined specimen 4 (Figs. 1-3) is in the sleeve 3, a signal is generated across the output 24 of the converter 23, the amplitude of which is not lower than the predetermined one. This signal is fed to the input of threshold element 107, so this is affected and a signal is generated across its output. When the sleeve 3 with the specimen 4 is then placed in the heating furnace 2, the unit 10, whose output signal is fed to the input 120 of the flip-flop 11, is actuated, so that it is actuated and the output signal from the flip-flop 118 over single pulse shaper 112 is transmitted to the gate 111. At this time, signals from the elements 106 and 107, respectively, already appear across the other inputs 108 and 109 of the AND gate 110, so that a pulse signal is also generated across the output of the AND gate 110. At the same time a signal is generated over the output of the AND gate 115, because over its inputs 114 and ll? the signals from the element 107 and from the flip-flop 118, respectively, coincide when the flip-flop 118 is reset when the signal is generated over its input 119, which occurs when the unit 10 switches off the measuring device. In this case, as with the generation of a similarity signal for the values being compared, the unit 22 or gate 123 is affected, over the output of which a reset order signal is generated, which is fed to the OR gate 66 (Fig. 5).

The invention makes it possible to automate the measurement, which contributes to higher measurement accuracy.

Industrial usability The measuring device according to the invention can be used to advantage in the production of articles of materials whose electrophysical properties change during the curing, for example of plastic materials.

Claims (7)

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CD 'D (N 2 .N I Ö \ 15 P a t e n t k r a v Measuring device for determining the curing time for binders in core masses, comprising a vessel filled with a sample body of sample material and placed in a heating furnace, a measuring sensor for electrophysical quantities which forms an analog signal for example a voltage proportional to the value of the quantity being measured, such as, for example, the electrical conductivity of the sample material or the electromotive force between the sensor electrodes in contact with the sample body, a unit for measuring the analog signal of the sensor sensor provided with an indicator for indicating the value; on the quantity, a unit for measuring the temperature in the furnace, and a start and stop unit which is connected to the vessel in the furnace and the unit for measuring the analog signal of the measuring sensor, known as the unit (11) for measurement_of the analog signal of the measuring sensor (7) is additionally provided with a converter (13) for converting the analog signal of the measuring sensor into a digital co d, wherein the unit (9) for measuring the temperature in the oven (2), the start and stop unit (10) and the indicating means (12) are electrically connected to the converter. Device according to claim 1, characterized in that the converter (13) for converting the analog signal from the measuring sensor (7) into a digital code comprises in series a unit (15) for converting the analog signal from the measuring sensor (7). , a unit (16) for recording the curing time of the sample material, a memory unit (17), a unit (18) for recording the time between the measurements of the values of the electrophysical quantities, as well as a data indicating unit (19), to which the signal conversion unit (15), the unit (16) for recording the curing time of the specimen and the memory unit (17) are connected, a pulse generator (20) connected to the unit (16) for recording the curing time of the specimen and the unit (18) for recording the time between the measurements of the values of the electrophysical quantities, and interconnected a control unit (21) and a comparison unit (22) for adjusting the values of the electrophysical quantities measured at the time (18) for recording the time between the measurements of the values of the electrophysical quantities is also connected to the unit (16) for recording the curing time of the specimen, and the control unit (21) is connected to the signal conversion unit (15). the unit (16) for recording the curing time of the specimen and the memory unit (17), which is also connected to the signal conversion unit (15), and the comparison unit (22) is connected to the unit (16) for recording the curing time of the specimen. (fl ï * ine Device according to claim 2, characterized in that the signal conversion unit (15) comprises a primary converter (23) connected to the sensor (7) and an analog-to-digital converter (25) connected to it and to the control unit (21). 4. that the unit (16) for recording the curing time of the examined specimen comprises in series partly a former pulse former (31), partly a rocker (32), partly an AND main gate (35) and partly a counter (36) for The curing device according to claim 2, characterized by time and in series a further AND gate (37), one input (38) of which is connected to a further input (39) of the OCH main device. gate (35) and connected to the pulse generator (20), partly a morentan timer (40), partly a circuit (43) for controlling the data output whose second input (53) is connected to the input (51) of the shaper (31) and to the (36) an array input (52) and connected to the control unit (21) and having an additional commutation unit (46), one input (48) of which is connected to a further input (47) of the main commutation unit (41) and connected to a time recording counter ( 50), while the second input (55) of the rocker (32), the additional AND gri the second input (56) of the end (37) and the second input (57) of the current timer (40) are connected to the control unit (21), while the output of the flip-flop (32) is connected to the memory unit (17), the input (50) of the timing register (50). 59), a further input (58) of the further commutation unit (46) and a closing input (60) of the data output control circuit (43) are connected to the unit (18) for recording the time between the measurements of the values of the the electrophysical quantities, the signal conversion unit (15) and the unit (22) respectively, for comparison of the values of the electrophysical quantities. a main commutation unit (41) and a 5. that the memory unit (17) comprises in series partly a main former (61). Device according to claim 4, characterized by single pulses, each input being connected to the flip-flop (32) in the unit (16) for recording the curing time of the specimen. , partly an OR main gate (62), partly a main delay element (67), partly a flip-flop (68), partly an additional former (76) for single pulses and partly a main memory register (77), the second input of which (83) is connected to a further OR gate (66), one input (64) of which is connected to the input (65) of the main delay element (67), and comprises a further delay element (72), the input (71) of which is connected * to the rocker ( 68) second input (70) and connected to the unit (18) for 8200333-6 I? recording the time between the measurements of the values of the electrophysical quantities, and two additional memory registers (81, 82), one input of one additional memory register (79) being connected to the main shaper (61) and one input of the other additional register (84) is connected to the further OR gate (66), while the second input (80) of the latter register is connected to the input (71) of the further delay element (72), while further inputs (87, 86, 88) of the main register and the further registers (77, 81 and 82, respectively) are interconnected and connected to the A / D converter (25) of the signal conversion unit (15), an additional input (92) of the OR main gate (62) and the output of the further delay element (72) is connected to the comparison unit (22), while the input (93) of the further OR gate (66) is connected to the control unit (21). Device according to claim 5, characterized in that the unit (18) for recording the time between the measurements of the values of the electrophysical quantities comprises in series partly an AND gate (94), the inputs (103, 104) of which are connected to the pulse generator (20) and the flip-flop (68) in the memory unit (17), respectively, and a counter (95) which is connected to a preset sensor (98), the further input (105) of the counter (95) being connected to the further OR gate (66) in the memory unit (17), partly a decoder (99) and partly a shaper (101) for single pulses. 7. that the control unit (21) comprises on the one hand a main threshold element (106) which is connected to one input (108) of a AND main gate (110) and on the other hand a further threshold element (107) which is connected to the AND main gate ( 110) second input (109) and to an additional AND gate (115) one input (114), and a single pulse former (112) connected to a further input (111) of the AND main gate (110) , partly a rocker (118), which is connected to the input (116) of the former (116) and to the second input (117) of the further AND gate (115), and partly an OR gate (123), one of which input (121) is connected to one input (119) of the rocker (118) and connected to the start and stop unit (10) and the other input (122) of which is connected to a device according to claim 6, characterized by the comparison unit (22). ), while the inputs of the main threshold element and the additional threshold element (106 and 107, respectively) are connected to the unit (9) for measuring the temperature of the heating furnace. respectively to the primary converter (23) in the signal conversion unit (15). 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