DE3152081C2 - - Google Patents

Description

The invention relates to a measuring device for determination the solidification time of binders in core molding compounds a container placed in a heating oven for a Test sample of the core molding compound to be tested, one with the test sample contacting donor for electrophysical parameters such as B. electrical Conductivity, EMF or the like, which is an analog Signal in the form of a measured parameter proportional voltage generated, a measuring unit for Measurement of the analog signal and an indicator for the Value of the measured parameter, a temperature measuring unit in the heating oven and an on / off unit that is connected to the Container in the heating furnace and with the measuring unit for the analog signal of the encoder interacts.

As from the publication by Peter H. Sydenham "Transducers in Measurement and Control", Bristol 1980, Adam Hilger Ltd., pages 40 and 41 already converters in various measuring devices Types used, e.g. B. when measuring the temperature.

From the SU copyright certificate 5 63 609 dated 3/9/1977 is one Measuring device for determining the curing time of Core molding compounds known that put one in a heating furnace placed container with a core molding compound, one with the Core molding compound contacting donor for electrophysical parameters of the core molding compound, one with the heating furnace connected temperature measuring unit for the Heating oven and one connected to the container Start / stop unit and one with the encoder for electrophysical parameters of the core molding compound electrically coupled indicators for the value of the Measuring unit for electrophysical parameters for electrophysical parameters of the core molding compound, the are linked together.

However, this device only allows a visual inspection the course of the solidification process after a electrical conductivity to be recorded. Furthermore will be the processing of the Measurement results and the determination of the solidification time of Hand by measuring electrophysical parameters characteristic points of a change curve of the electrical conductivity carried out on the indicator which significantly reduces the measuring accuracy and the Workload for the measuring process increased.

The invention has for its object a Measuring device for determining the curing time of To create binders in core molding compositions that Has additional devices that allow the Increase measurement accuracy and the workload for the Lower measuring process.  

This object is achieved in that Measuring device of the type mentioned the measuring unit an additional one for the analog signal of the encoder Has converter with which the analog signal of the encoder is converted into a digital code, and that the Temperature measuring unit in the heating furnace, the On / off unit and the indicator for the value of the measured parameters electrically with the converter are connected.

The converter for the analog signal expediently contains the In series in a digital code a converter unit for converting the analog Signals from the encoder, a registration unit for the Curing time of the test sample, a storage unit and a registration unit for the different Times measured values of electrophysical Parameters and a display unit to which the Converter unit, the registration unit and the Storage unit are connected, further one to the Registration units coupled pulse generator, the one Control unit and one coupled to it Comparison unit for at different times contains measured electrophysical parameters, where the registration unit for at different times measured electrophysical parameters the registration unit for the curing time of the Test pattern and the storage unit is connected, and this storage unit additionally with the Converter unit for the signal of the encoder and the Comparison unit for at different times measured values of the electrophysical parameters is connected, which in turn to the registration unit for  the curing time of the test sample of the test item Core molding compounds is connected.  

The signal converter preferably contains one connected the sensor for electrophysical parameters Primary converter and one coupled to it, analogue connected to the control unit Digital converter.

The registration unit advantageously contains a series connection for the curing time of the test sample from a single pulse shaper, a flip Flop, an AND basic circuit and a counter for the curing time of the test sample and a series connection from an additional AND circuit whose one input with another input of the AND basic circuit together and connected to the pulse generator is a counter for the elapsed time, a main switch unit and a control circuit for information output, the other input with the input of the single pulse shaper and with the other input of the counter for the curing time of the Test pattern together and to the control unit switched on and an additional one at their further input Switch unit is connected, whose one input with another input of the main switch unit together and to whom a time registration counter is turned on with the other input of the flip-flop, the other input of the additional AND circuit and the other input of the counter for the elapsed time to the control unit, the output of the flip-flop to the storage unit, the input of the time registration counter, another input of the additional ones Switch unit and the last input of the  Control circuit for information output each to the unit for the measuring distance of the electrophysical Parameters, the signal converter and the comparison unit for the values of electrophysical Parameters are connected.

It is preferred if the storage unit is a Series connection from a main former for single pulses, its input with an output of the flip-flop the registration unit for the curing time of the test sample is coupled, an OR basic circuit, a main delay element, a flip-flop, a additional single pulse shaper and a main memory register, an additional one at its other entrance OR circuit is connected, one of which Input with the input of the main delay element is interconnected, and an additional delay element, whose entrance with the other entrance the flip-flop together and to the unit for the measuring distance of the electrophysical parameters switched on and two additional memory registers contains, with an input of a memory register the main shaper for single impulses, one input to the other connected to the additional OR circuit and the other entrance of the latter with the entrance of the additional delay element is combined, furthermore the one inputs of the main memory register and the additional memory registers together and on the analog-digital converter of the signal converter is switched on are another input of the OR basic circuit and the output of the additional delay element the comparison unit for the values of the electrophysical Parameters, an input of additional OR circuit to the control unit and its with the Output of the additional memory register merged Output and the input of the additional delay element to the unit for the measuring distance of the electrophysical parameters are connected.

It is advantageous if the unit for the measuring distance  the electrophysical parameters are connected in series from an AND circuit, the inputs of which the pulse generator or with the flip-flop of the memory unit are coupled, a counter to which an adjuster and its further entrance to the additional one OR circuit of the storage unit connected is a decipherer and a single pulse shaper contains.

It is preferred if the control unit is a main threshold element, to the one input of an AND basic circuit is connected, an additional threshold element, to another input of the AND basic circuit and an input of an additional AND circuit are connected, one to another input single pulse shaper connected to the AND basic circuit, a flip-flop whose output is connected to the input of the single pulse shaper and to the other input of the additional AND circuit is connected, and one OR circuit contains one input with one input of the flip-flop together and to the start Stop unit is on with the other input the OR circuit to the comparison unit for the values of the electrophysical parameters and the inputs of the main and the additional threshold element to the temperature measuring unit for the heating furnace or connected to the primary converter of the signal converter are.

The present invention allows the setting time the binder and the core molding compound automatically to determine what the labor intensity of the measurement processes reduced and the accuracy of the measurement results increased.

Furthermore, the present invention allows the information received in an electronic data processing system (EDP) for further processing and Use in process computing systems for preparation of core molding compounds and cores.  

The present invention leaves the entire obtained Process information and the end result in output finished form.

Brief description of the drawings

The present invention is based on the following the description of an embodiment with reference be explained in more detail on the drawings. It shows

Figure 1 is a functional circuit of a measuring device according to the invention for determining the curing time of binders and core molding compounds in section through a heating furnace.

Fig. 2 is a circuit structure of a converter for electro-physical parameters;

Fig. 3 is a circuit structure of a signal converter;

Fig. 4 is a circuit structure of a registration unit for the cure time of a test pattern;

Fig. 5 is a circuit structure of a memory unit;

Fig. 6 is a circuit structure of a unit for measuring distance of the electro-physical parameters; and

Fig. 7 is a circuit structure of a control unit.

Preferred embodiment of the invention

The measuring device for determining the curing time of core molding compounds contains a heating furnace 2 mounted on a foundation 1 ( FIG. 1). A container 3 (in the following sleeve 3 ) with an examination pattern 4 (for example with a core molding compound) is accommodated within the furnace 2 . A transmitter 7 for electrophysical parameters contacting the pattern 4 is let through the openings in the lid 5 of the furnace 2 and in the lid 6 of the sleeve 3 . The furnace 2 is heated by means of radiators 8 built into the body of the furnace 2 . A temperature measuring unit 9 for the heating furnace is connected to the inner surface of the furnace 2 . A start-stop unit 10 , to which the sleeve 3 is connected, is mounted on the foundation 1 . The device also contains a measuring unit 11 for electrophysical parameters of the examination pattern, which has an indicator 12 for the value of the electrophysical parameters and a converter 13 for electrophysical parameters connected to it. The converter 13 is electrically connected to the transmitter 7 and to the units 9 and 10 . The indicator 12 has an independent output 14 for connecting a recording device (not shown in FIG. ).

The converter 13 for electrophysical parameters contains a series connection of a signal converter 15 ( FIG. 2), a registration unit 16 for the curing time of the examination pattern, a storage unit 17 and a unit 18 for the measuring distance of the electrophysical parameters. A display unit 19 for the information is connected to the units 15 , 16, 17 . The converter 15 is connected to the unit 17 and the unit 16 to the unit 18 . A pulse generator 20 is connected to the units 16 and 18 . The converter 13 further contains a control unit 21 and a comparison unit 22 connected thereto for the values of the electrophysical parameters. The unit 21 is connected to the units 15, 16, 17 . The unit 22 is connected to the units 16, 17 .

The signal converter 15 ( FIGS. 2, 3) contains a primary converter 23, to the output 24 of which an analog-digital converter 25 is connected with its input 26 . The input 27 of the converter 23 is connected to the transmitter 7 and its output 24 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 the output 30 to the units 16 and 17 .

The registration unit 16 for the curing time of the test sample contains a single pulse shaper 31 ( FIG. 4), to which a flip-flop 32 is connected with its input 33 . An input 34 of an AND circuit 35 is connected to the output of the flip-flop 32 . A counter 36 for the curing time of the examination pattern is connected to the output of the AND circuit 35 . The unit 16 contains an additional AND circuit 37 , the input 38 of which is connected to an input 39 of the AND circuit 35 and connected to the pulse generator 20 . A counter 40 is connected to the AND circuit 37 , at the output of which a main switch unit 41 is connected with its input 42 . A control circuit 43 for information output with its input 44 is connected to the unit 41 . An additional switch unit 46 is connected to an input 45 of the circuit 43 . The inputs 47 and 48 of the units 41 and 46 are interconnected in a connection point 49 . A time registration counter 50 is connected to the connection point 49 . The respective inputs 51, 52, 53 of the former 31 , the counter 36 and the circuit 43 are interconnected in a connection point 54 . The respective inputs 55, 56, 57 of the flip-flop 32 , the AND circuit 37 and the counter 40 are connected to the unit 21 . The inputs 58, 59 and 60 of the unit 46 , the counter 50 and the circuit 43 are connected to the units 15, 18 and 22 , respectively.

The storage unit 17 contains a main former 61 ( FIG. 5) for individual pulses, to which an OR circuit 62 is connected with its input 63 . Combined inputs 64 and 65 of an additional OR circuit 66 and a main delay element 67 are connected to the OR circuit 62 . A flip-flop 68 is coupled to the element 67 with its input 69 , while its input 70 is combined with the input 71 of an additional delay element 72 in a connection point 73 which is connected to the unit 18 . The input 75 of an additional individual pulse shaper 76 is connected to the output 74 of the flip-flop 68 . A main memory register 77 is connected to the former 76 with its input 78 . Inputs 79 and 80 of additional memory registers 81 and 82 are routed to former 61 and point 73 . The inputs 83 and 84 of the registers 77 and 82 are connected together at a connection point 85 and connected to the OR circuit 66 . The inputs 86, 87, 88 of the respective registers 81, 77, 82 are connected together in a connection point 89 and connected to the output 30 of the converter 25 . The inputs 90 and 91 of the registers 81 and 82 are connected to the unit 19 . The inputs 92 and 93 of the OR circuits 62 and 66 are connected to the respective units 22 and 21 .

The unit 18 for the measuring distance of the electrophysical parameters contains an AND circuit 94 ( FIG. 6), to which a counter 95 is connected with its input 96 , to the input 97 of which an adjuster 98 is connected. A decoder 99 with its input 100 is connected to the counter 95 and a single pulse shaper 101 with its input 102 is connected to the decipherer 99 . The inputs 103 and 104 of the AND circuit 94 are each connected to the generator 20 and to the output 74 ( FIG. 5) of the flip-flop 68 . An input 105 ( FIG. 6) of counter 95 is coupled to the output of OR circuit 66 ( FIG. 5) at connection point 85 .

The control unit 21 contains a main and an additional threshold element 106 and 107 ( FIG. 7), which are connected to the inputs 108 and 109 of an AND basic circuit 110 . A single pulse shaper 112 is connected to an input 111 and the AND circuit 110 . An input 114 of an AND circuit 115, which is combined with the input 109 of the AND circuit 110 at a connection point 113 , is connected to the element 107 . A flip-flop 118 , which has inputs 119 and 120 and whose input 119 is combined with the first of the inputs 121 and 122 of an OR circuit 123 , is connected to the input 116 of the former 112 which is connected to an input 117 of the AND circuit 115 .

The measuring device for determining the curing time of binders and core molding compounds works as follows.

When the sleeve 3 ( FIG. 1) with an examination pattern 4 (core molding compound) is inserted into the heating furnace 2 , the start-stop unit 10 responds and switches on the measuring unit 11 for electrophysical parameters of the examination pattern. Here, a signal passes from the unit 10 into the converter 13 for electrophysical parameters. Simultaneously with this, 13 signals from the transmitter 7 for electrophysical parameters and from the temperature measuring unit 9 for the heating furnace arrive at the converter. The information partly processed in the converter 13 arrives at the indicator 12 for the value of the electrophysical parameters and at the same time occurs at an output of the converter 13 which serves as the output of the device. This information can also be used in a computer system as a process computer in the preparation of a core molding compound and in the production of cores. At the output of the converter 13 , which occurs as another output of the device, completely processed information appears which is used to control the solidification process of the core molding compound.

The converter 13 for electrophysical parameters works in the following way:

The signal from the unit 10 ( FIGS. 1, 2) arrives at the control unit 21 , which issues a command to the signal converter 15 to initiate a measurement process. The converter 15 , at which a signal from the transmitter 7 arrives, initiates the measurement and conversion process for the measurement results. The signal from the converter 15 reaches the registration unit 16 for the curing time of the examination pattern and the display unit 19 for the information. The unit 16 , on commands from the unit 21, registers the initial value of the electrophysical parameters of the examination pattern 4 and transmits the information to the unit 19 , the storage unit 17 and, if necessary, to an EDP system for use in a process computing system. After the unit 17 has received and stored the first measurement result for the electrophysical parameters of the examination pattern 4 , it issues a command to the measuring unit 18 for the measuring distance of the electrophysical parameters to start counting a time after which the unit 18 of the unit has expired 17 issued a command to store the new value of the electrophysical parameter of the sample 4 to be examined. The unit 17 then operates the comparison unit 22 for the values of the electrophysical parameters. If the process of solidification of the sample 4 to be examined has not yet ended, the first and second measurement results to be compared will be unequal to one another. In this case, the inequality signal arrives in the unit 16 , which forms delete commands.

A new first value of the electrophysical parameter of the pattern 4 is stored by the unit 17 , the unit 18 is actuated again, as a result of which the predetermined time interval is counted down. Then, unit 17 again stores a second value of the electrophysical parameter of sample 4 , and unit 22 again makes a comparison in the new pair of results.

As long as the solidification process is not completed, the results of two successive measurements will be unequal and the cycles will repeat. The end of the solidification of the examination pattern 4 is testimony to the equality of the first and the second result of a measurement cycle for an electrophysical parameter of the examination pattern 4 . Here, the equality signal comes from the unit 22 into the unit 21 , and the latter ensures that the work of the measuring unit 11 is adjusted for electrophysical parameters of the examination pattern.

In the course of the entire measuring cycle, the unit 19 displays the initial and the time value of the electrophysical parameter of the examination pattern 4 and, at the moment when the solidification ends, a value of this parameter which corresponds to the completion of the solidification process. In addition, the unit 19 indicates a time corresponding to the moment when the solidification process is completed and the current time. Similar information about the parameter values of the examination pattern 4 and about the running time of the process can also be obtained in the EDP system. This information is also obtained after the solidification process has ended and allows the qualitative properties of the examination pattern 4 to be assessed. For a final setting of the registration of the parameter values of the pattern 4 , a command is sent to the unit 21 from the unit 10 , which ensures that the device is reset to the starting position.

The signal converter 15 operates as follows. A signal proportional to the electrophysical parameter of the examination pattern 4 arrives at the input 27 ( FIGS. 2, 3) from the transmitter 7 ( FIGS. 1, 2, 3). This signal is subjected to processing by the primary converter 23 , at the input 24 of which a signal appears which, according to the electrical parameters, is matched to the input parameters of the measuring circuits of the analog-digital converter 25 . The latter converts the signal when there is a release at the input 28 from the control unit 21 with a required accuracy and frequency into a digit code which comes from the outputs 29 and 30 to the respective units 16, 17, 19 , while the signal from the output 24 also reaches unit 21 .

The registration unit 16 for the curing time of the examination pattern works as follows.

The latter topples over to a signal arriving from the unit 21 ( FIGS. 2, 4) at the input 55 of the flip-flop 32 , a signal appearing at its output which enters the unit 17 and the input 34 of the AND circuit 35 arrives. At the other input 39 of the AND circuit 35 , pulses from the generator 20 arrive continuously. The appearance of a signal at the first input 34 of the AND circuit 35 thus ensures passage of the pulses to the counter 36 for the curing time of the test sample. Here, the signal from counter 36 reaches unit 19 , where it is also mapped. When the signal from the unit 21 arrives at the input 51 , the single pulse shaper 31 is triggered. A single pulse appears at its output, which arrives at the input 33 of the flip-flop 32 and resets the flip-flop 32 to the starting position, which causes the counter 36 to be stopped. When the signal from the unit 21 arrives at the input 56 ( FIG. 4) of the AND circuit 37 , the latter begins to pass the pulses arriving at its other input 38 from the generator 20 to the counter for the elapsed time. The status value of the counter 40 reaches the unit 19 , is mapped and arrives at the same time via the switch unit 41 at the input 44 of the control circuit 43 for the information output. The counter 40 operates as long as there is a signal at the input 56 of the AND circuit 37 and is reset to the initial value with a signal which arrives at the input 57 of the counter 40 . At the input 45 of the circuit 43 , a signal arrives via the switch unit 46 from its input 58 , which is coupled to the output 30 ( FIG. 3) of the analog-digital converter 25 . The circuit 43 ( FIG. 4) responds either to signals from the registration time counter 50 or to signals from the control unit 21 (via the input 53 ) and the comparison unit 22 (via the input 60 ).

The signals from the unit 18 arrive at the input 59 of the counter 50 , and a signal is generated at the output thereof after a predetermined number of measuring intervals.

The circuit 43, for input into a computer system (not shown in the drawing) or a printing device, forms information about the value of a parameter of the examination pattern 4 ( FIG. 1) and about a time corresponding to this value at the start of the work ( Initial values) at time intervals determined by the counter 50 and at the moment a signal arrives at its input 60 from the unit 22 .

The storage unit 17 operates as follows.

When a signal arrives from the output of the flip-flop 32 at the individual pulse shaper 61 ( FIGS. 2, 5), the latter is triggered, as a result of which the memory register 81 responds, which stores the state at the output 30 of the converter 25 via its input 86 . At the same time, the signal passes through the OR circuit 62 to the input 64 or OR circuit 66 and to the input 65 of the delay element 67 . The signal passes through the OR circuit 66 to the inputs 83, 84 of the memory registers 77 and 82 and from the element 67 to the input 69 of the flip-flop 68 , which is why this is reversed, which in turn causes a signal to appear at the output 74 . This signal passes through the individual pulse shaper 76 to the input 78 of the register 77 , which enables the state of its input 87 to be entered in it, and then reaches the unit 22 . The signal comes from the unit 18 at point 73 and at the same time at input 70 of flip-flop 68 , which resets it, at input 80 of register 82 , thereby entering the state of its input 82 , and at input 71 , whereby element 72 is triggered. Here, the signal from register 82 enters unit 22, as does the signal from element 72 . The switching cycle of the OR circuits 62 and 66 , the elements 67, 72, the flip-flop 68 , the shaper 76 and the registers 77 and 82 takes place in analogy to the above-described when a signal arrives not only from the shaper 61 , but also at Arrival of a signal at input 92 of OR circuit 62 from unit 22 .

The measuring unit 18 for the distance between the electrophysical parameters works in the following way:

At input 103 ( FIGS. 2, 6) of AND circuit 94 , pulses from generator 20 arrive continuously, but these can only get to counter 95 if a signal is present at input 104 thereof. When the said signal is present, the counter 95 starts counting. When the preset value of the signal is reached, the counter 95 issues a command via the decipherer 99 and the individual pulse shaper 101 , which comes into the unit 17 ( FIG. 5). The signal value at which the counter 95 ( FIG. 6) emits a signal to the decipherer 99 defines its operating time and is specified with the aid of the adjuster 98 . The counter 95 is reset via the input 104 connected to the OR circuit 66 ( FIG. 5).

The control unit 21 operates as follows.

When preparing the device for work, the predetermined temperature in the heating furnace 2 ( Fig. 1) is guaranteed. A corresponding signal from the temperature measuring unit 9 for the heating furnace reaches the input of the threshold element 106 ( FIG. 7). If the signal is not below the predetermined value, element 106 responds and a signal appears at its output. If the examination pattern 4 ( FIGS. 1, 2, 3) is present in the sleeve 3 , a signal does not appear at the output 24 of the converter 23 below the predetermined one. This signal causes the threshold element 107 ( FIG. 7) to respond by striking its input and a signal to appear at its output. Then the unit 10 is triggered when the sleeve 3 with the examination pattern 4 is inserted into the heating furnace 2 . The signal from the unit 10 reaches the input 120 of the flip-flop 118 . The latter topples over, and from its output a signal arrives at the input 111 of the AND circuit 110 via the individual pulse shaper 112 . At this time, signals from elements 106 and 107 are already present at their other inputs 108 and 109 . Therefore, a pulse signal also appears at the output of the AND circuit 110 . At the same time, a signal also appears at the output of the AND circuit 115 because the signals from the element 107 and from the flip-flop 118 coincide at the inputs 114 and 117 thereof. The flip-flop 118 is reset when a signal occurs at its input 119 , which occurs when the device 10 is stopped by the unit. Here, as well as when an equality signal appears for values to be compared, the unit 22 switches through the OR circuit 123 , at the output of which a delete command appears which comes to the OR circuit 66 ( FIG. 5).

The present invention allows the measurement process to automate what increases measurement accuracy.

Industrial applicability

The present invention can be successfully used in Manufacture of articles from materials whose electrophysical properties when solidifying change, as is the case with plastics, for example is applied.

Claims (7)

1. Measuring device for determining the solidification time of binders in core molding compositions with a container used in a heating furnace for a test sample of the core molding compound to be tested, a sensor for electrophysical parameters contacting the test sample, such as, for. B. electrical conductivity, EMF or the like, which generates an analog signal in the form of a voltage proportional to the measured parameter, a measuring unit for measuring the analog signal and an indicator for the value of the measured parameter, a temperature measuring unit in the heating furnace and an on / off switch unit, associated with the container in the heating furnace, and with the measuring unit for the analog signal of the encoder in interaction, characterized in that the measuring unit (11) further comprises a converter (13) for the analog signal of the encoder (7), with which the analog Signal of the encoder is converted into a digital code, and that the temperature measuring unit ( 9 ) in the heating furnace ( 2 ), the on / off switch ( 10 ) and the indicator ( 12 ) for the value of the measured parameter are electrically connected to the converter ( 13 ) are. 2. Device according to claim 1, characterized in that the converter ( 13 ) for the analog signal of the encoder ( 7 ) in a digital code has a series connection of a converter unit ( 15 ) for converting the analog signal of the encoder ( 7 ), one Registration unit ( 16 ) for the curing time of the test sample, a storage unit ( 17 ) and a registration unit ( 18 ) for the values of the electrophysical parameters measured at different times, and a display unit ( 19 ) to which the converter unit ( 15 ), to the registration unit ( 16 ) and are connected to the storage unit ( 17 ), further a pulse generator ( 20 ) coupled to the registration units ( 18, 16 ), a control unit ( 21 ) and a comparison unit ( 22 ) coupled to this for the electrophysical measurements at different times Contains parameters, the registration unit for the electrophysical parameters measured at different times ter is additionally connected to the registration unit ( 16 ) for the curing time of the test sample and the storage unit ( 17 ), and this storage unit ( 17 ) additionally with the converter unit ( 15 ) for the signal from the transmitter ( 7 ) and the comparison unit ( 22 ) for the values of the electrophysical parameters measured at different times, which in turn is connected to the registration unit for the curing time of the test sample of the core molding compounds to be tested. 3. Device according to claim 2, characterized in that the signal converter ( 15 ) has a primary converter ( 23 ) connected to the transmitter ( 7) for electrophysical parameters and a coupled to the control unit ( 21 ) connected analog-digital converter ( 25 ) contains. 4. Device according to claim 2, characterized in that the registration unit ( 16 ) for the curing time of the test pattern, a series connection of a single pulse shaper ( 31 ), a flip-flop ( 32 ), an AND basic circuit ( 35 ) and a counter ( 36 ) for the curing time of the test pattern and a series circuit comprising an additional AND circuit ( 37 ), one input ( 38 ) of which is connected to another input ( 39 ) of the AND basic circuit ( 35 ) and connected to the pulse generator ( 20 ) , a counter ( 40 ) for the elapsing time, a main switch unit ( 41 ) and a control circuit ( 43 ) for the information output, the other input ( 53 ) of which is connected to the input ( 51 ) of the single pulse shaper ( 31 ) and to the other input ( 52 ) of the counter ( 36 ) for the curing time of the test sample and connected to the control unit ( 21 ), to whose further input ( 45 ) an additional control unit ( 46 ) is connected, one input ( 48 ) of which is connected to a further input ( 47 ) of the main switch unit ( 41 ) and connected to a time registration counter ( 50 ), the other input ( 55 ) of the flip-flop ( 32 ), the other Input ( 56 ) of the additional AND circuit ( 37 ) and the other input ( 57 ) of the counter ( 40 ) for the elapsed time to the control unit ( 21 ), the output of the flip-flop ( 32 ) to the storage unit ( 17 ) , the input ( 59 ) of the time registration counter ( 50 ), another input ( 58 ) of the additional switch unit ( 46 ) and the last input ( 60 ) of the control circuit ( 43 ) for the information output to the unit ( 18 ) for the measuring distance of the electrophysical parameters, the signal converter ( 15 ) and the comparison unit ( 22 ) for the values of the electrophysical parameters are connected. 5. Device according to claim 4, characterized in that the storage unit ( 17 ) is a series circuit comprising a main former ( 61 ) for individual pulses, the input of which is coupled to the flip-flop ( 32 ) of the registration unit ( 16 ) for the curing time of the test sample, an OR basic circuit ( 62 ), a main delay element ( 67 ), a flip-flop ( 68 ), an additional individual pulse shaper ( 76 ) and a main memory register ( 77 ), at the other input ( 83 ) of which an additional OR circuit ( 66 ) is connected, one input ( 64 ) of which is connected to the input ( 65 ) of the main delay element ( 67 ), and an additional delay element ( 72 ), the input ( 71 ) of which is connected to the other input ( 70 ) of the flip-flop and is connected to the unit ( 18 ) for the measuring distance of the electrophysical parameters, and contains two additional memory registers ( 81, 82 ), one input ( 79 ) of the one memory register ters to the main former ( 61 ) for individual pulses and one input ( 84 ) of the other to the additional OR circuit ( 66 ), the other input ( 80 ) of the latter is combined with the input ( 71 ) of the additional delay element ( 72 ) and furthermore the one inputs ( 87, 86, 88 ) of the main memory register ( 77 ) and the additional memory registers ( 81, 82 ) connected together and connected to the analog-digital converter ( 25 ) of the signal converter ( 15 ), a further input ( 92 ) of the OR basic circuit ( 62 ) and the output of the additional delay element ( 72 ) to the comparison unit ( 22 ), for the values of the electrophysical parameters and an input ( 93 ) of the additional OR circuit ( 66 ) to the control unit ( 21 ) connected. 6. Device according to claim 5, characterized in that the unit ( 18 ) for the measuring distance of the electrophysical parameters is a series circuit of an AND circuit ( 94 ), the inputs ( 103, 104 ) with the pulse generator ( 20 ) or with the A flip-flop ( 68 ) of the memory unit ( 17 ) is coupled, a counter ( 95 ) to which an adjuster ( 98 ), whose further input ( 105 ) is connected to the additional OR circuit ( 66 ) of the memory unit ( 17 ) , a decipherer ( 99 ) and a single pulse shaper ( 101 ). 7. Device according to claim 6, characterized in that the control unit ( 21 ) has a main threshold element ( 106 ) to which an input ( 108 ) of an AND basic circuit ( 110 ) is connected, an additional threshold element ( 107 ) to which another input ( 109 ) of the AND basic circuit ( 110 ) and an input ( 114 ) of an additional AND circuit ( 115 ) are connected, an individual pulse shaper ( 112 ) connected to a further input ( 111 ) of the AND basic circuit ( 110 ) contains the input ( 116 ) of the individual pulse shaper ( 112 ) and a flip-flop ( 118 ) connected to another input ( 117 ) of the additional AND circuit ( 115 ) and an OR circuit ( 123 ), one of which has an input ( 121 ) one input ( 119 ) of the flip-flop ( 118 ) is connected together and connected to the start-stop unit ( 10 ), the other input ( 122 ) of the OR circuit ( 123 ) to the comparison unit ( 22 ) for the Values of the electrophysical parameter he, the inputs of the main threshold element ( 106 ) and the additional threshold element ( 107 ) to the temperature measuring unit ( 9 ) for the heating furnace or to the primary converter ( 23 ) of the signal converter ( 15 ) are connected.