CS233255B1 - Crystal termometer connection - Google Patents

Abstract

The present invention relates to crystal engagement thermometer, solves the problem of conversion temperature dependent intrinsic crystal frequencies thermometric temperature sensor data for tormometric crystal sensors with generally different sensitivity and frequency. The essence of the invention is that that the measured oscillator output is controlled temperature-dependent crystal sensor, is through the main preamplifier and shaping circuit and over the main gate attached to main preset input counter the computer whose status outputs are connected to the display while leaving the output frequency-controlled reference oscillator normal, is through the auxiliary gate connected to the counter of the auxiliary preset counter to output transmission is connected to the closing control main and auxiliary gate inputs, while opening control inputs main -i the auxiliary gate is connected to the , entertaining output of logic control : water, the setting output of which is only for inputs to set the preset 4 main and auxiliary preset counters with preset inputs. Logical the control circuit is preferably provided sync input connected to auxiliary amplifier and forming output circuit and external control inputs.

Description

Crystal thermometer wiring

The invention relates to the integration of a crystal thermometer, solves the problem of converting a temperature-dependent natural frequency of a crystal thermometric sensor into a temperature indication for crystal tormometric sensors of generally different sensitivity and frequency.

SUMMARY OF THE INVENTION The output of a temperature-dependent crystal sensor controlled oscillator is connected via a main preamplifier, a shaping circuit, and a main gate to an input of a master preset computer whose status outputs are connected to a display, the reference normalized output oscillator output. , an auxiliary preset counter input is connected to the counter via an auxiliary gate, the transmission output of which is connected to the main and auxiliary gate closing control inputs, while the master main opening inputs

The auxiliary gates are connected to a func- tion output of the logic control circuit whose adjusting output is connected to the preset inputs 4 of the main and auxiliary preset counters provided with the preset inputs. The logic control circuit is preferably provided with a synchronization input connected to the output of the auxiliary amplification and shaping circuit and inputs for external control.

(52) Int. Cl? G 01 K 7/02

233 255

The invention relates to the connection of a crystal thermometer, solves the problem of converting a temperature-dependent natural frequency of a crystal thermometric sensor into a temperature reading for crystal thermometric sensors of generally different sensitivity and frequency *

Known crystal thermometer connections utilize the temperature dependence of the intrinsic resonance frequency of a thermometric crystal sensor with a precisely defined sensitivity that controls the frequency of a measuring oscillator whose frequency is heterodyne

233 255 is compared to the frequency reference of a stable reference oscillator controlled by the frequency normal to zero record, in which the instrument shows zero. · Changing the temperature to the instrument zero indicates a non-zero signal which is applied to the decimal counter input. Preferably, the sensitivity of the thermometriocrystalline crystal sensor 1000 Hz / K is used, which allows to indicate the measured temperature directly with a resolution of 0.01} 0.001 or 0.000 1 K. depending on the length of the sample sampling period of 0.1 or 10 seconds.

Disadvantages of the known wiring are the use of a crystal thermometer sensor with a precisely defined readability, which must be reproducible accurately in the repeatable production of crystal thermometer sensors. This requires a high technological level of robust manufacturing process which is reflected in the cost and consequently the cost of such a sensor · Another disadvantage is the necessity to use a frequency standard with high stability and at the same time with high accuracy in the nominal frequency setting, which is again a very difficult theological issue. crystal thermometrioc sensor at zero instrument reading, because the difference is reflected in nonzero glare and therefore bending instrument ·

The above mentioned drawbacks are eliminated by the connection of the crystal thermometer according to the invention, which is based on the fact that the output of the measuring oscillator controlled by the temperature-dependent crystal

233 255 is connected to the input of the main preamplifier and shaping circuit, the output of which is connected to the counter input of the main preset counter whose status outputs are connected to the inputs of the display unit, the opening control input of the main gate and the opening control input of the gate are connected to providing a logic control circuit output whose adjusting output is connected to a preset preset input having preset inputs, and the adjusting output is connected to a preset preset input having preset inputs, wherein the transmission output is coupled to a shutdown control input and the output of the transmission is connected to the closing control input of the auxiliary gate, whose output is connected to the counter input of the auxiliary gate before the adjustable The input of the gate is connected to the output of the auxiliary amplifier and the forming circuit, the input of which is connected to the output of the reference oscillator controlled by the frequency normal. The logic control circuit is provided with a synchronization input, which is connected to the output of the auxiliary amplifier and shaping circuit, and is further preferably provided with an input for external control by a switching element and an input for controlling the internal measure clock of the control element. The status outputs of the main preset counter are preferably led to a separate output for further use.

The higher effect of the circuitry according to the invention is that it allows the use of crystal thermometric sensors in general of varying resistances and frequencies, thereby reducing the theological efficiency of the process of producing crystal thermometer sensors, and the associated manufacturing costs and costs. Furthermore, there is no need to use the frequency standard β with high precision in the nominal frequency setting, instead of using commonly manufactured frequency standards, thereby making the wiring further cheaper, yet still allowing for the measurement to be of equal-value compared to known wiring.

An example of a circuit according to the invention is shown in the attached drawing in the form of a block diagram, which also explains the function of the circuit. The involvement consists of individual members, which can be described as follows:

The measuring oscillator 6 is controlled by a temperature-dependent crystal thermometer sensor 2 and thus gives a highly linear frequency change over temperature.

The main amplifying and shaping circuit 2 amplifies the frequency of the measuring oscillator 6 and adjusts it to a pulse train of corresponding frequency with steep edges.

The master 11 opens or closes the transmission of the measured pulses between the output of the main amplifier and shaping circuit 2 and the counter input 51 of the main preset counter 5, preferably having two control inputs, an opening control input 43 controlled by the control voltage from output 61 of logic the control circuit 6 and the closing control input 44 controlled by the control voltage from the output 74 of the auxiliary preset counter 2.

The main preset counter 6 is provided with at least a counter

233 255 through input 51, preset inputs 52 and preset input 54, ^and status outputs 54. The main preset counter 5 adds the measured pulses from the main amplification and contouring circuit 3, which have passed through the main gate on the counter 51 to the preset value before being counted, it was overwritten from the preset inputs 52 by the control voltage from the output 62 of the logic control circuit 6 applied to the preset input 53. Upon completion of the counting, the final state is available at the status outputs 54. In the case of a particular requirement for expressing the temperature scale, it is possible for the main preset counter 8 to also subtract from the preset value.

The status outputs 54 of the main preset counter 5 may preferably be led to a separate output 13 for further use.

The display unit 12 is used to express the measured temperature, the input of which is connected to the status outputs 54 of the main preset counter 5. The display unit 12 can advantageously be realized by means of a digital display, possibly with a memory.

The reference oscillator 10 is controlled by a stable frequency standard 11 at any frequency, and is a source of a highly stable frequency.

The auxiliary amplifying and shaping circuit 2 amplifies the frequency of the reference oscillator 10 and adjusts it to a sequence of reference pulses corresponding to the frequency with steep edges.

- 6,233 2SS

The auxiliary gate 8 opens and closes the transmission of the reference pulses between the output of the auxiliary amplifying and shaping circuit 6 ^{and the} read input 71 of the auxiliary preset counter 2. preferably controlled by a control voltage from the transmission output 74 of the auxiliary preset counter 2.

The auxiliary preset counter 2d® is provided with at least a distinct input 71 »of the preset inputs 72 and an input for setting the preset 73 and a transmission output 74 for the control voltage. to provide a gate control input 44 * of the main gate 4 and preferably a gate control input 84 of the auxiliary gate 8 '

The logic control circuit 6 is provided with an adjustment output 62 for control voltage. to preset the main preset counter 54 by preset input 53 and to preset the auxiliary preset counter 2 by preset input 73 and further provided with an output 61 for the controller! napět! to equip the opening control inputs 43 of the main gate 4 and the opening control input 83 of the gate 8. the circuit 6 is also provided with a synchronization input 63 for the control voltage synronolzaol of the output 61 with a reference pulse edge from the output of the auxiliary amplification and shaping circuit 2, and is further preferably provided with an input 64 for external

233 255 is controlled by the switching element 14 and the input 65 for controlling the internal measure of the logic control circuit 6 by the control element 15.

The switching element 14 may be an electronic or mechanical switching element, in the wiring example a button is used. The control element 15 may also be an electronic or mechanical element, with potentiometers being used in the wiring example.

The function of the circuit according to the invention is as follows: The measuring oscillator 6 controlled by the crystal thermometric sensor 6 operates as a precise temperature / frequency converter. Its output voltage is amplified and formed in the main preamplifier and shaping circuit J to a sequence of measured pulses corresponding to the frequencies that are applied to the input of the main gate 4. The reference oscillator 10 controlled by the fixed frequency standard 11 is a source of highly stable frequency. Its output voltage is also amplified and formed in the auxiliary pre-amplification and shaping circuit of 2 ¹¹⁸ reference pulses of the corresponding frequency, which are applied to the input of the auxiliary gate 8.

The logic control circuit 6 either generates a control voltage at the adjusting output 62 based on its own internal measure clock, which can be controlled by the control element 15 to the internal measure clock input 65, or by command to the external control input input 64. control voltage is applied to input 53 for presetting the main preset counter 5 and also to

233 255 input 73 for presetting the auxiliary counter 7 * This will overwrite the information from pre-selection inputs 52 to the main preset counter 8 and from the preset inputs 72 to the auxiliary preset counter 7 ·

This activity can be called a preset. Information on the preset inputs 52 of the main preset counter 5 and on the preset inputs 72 of the auxiliary preset counter 7 is input by known methods. After the presetting, the control voltage is generated at the trip input Jčl. This control voltage is applied to the opening control input 43 of the main gate 4 and to the opening control input 83 of the auxiliary gate 8. This opens both the main gate-4 and the auxiliary gate 8 and this can immediately be considered the beginning of the measurement interval. During the measurement interval, measured pulses that have passed from the main preamplifier and shaping circuit 2 through the main gate 6 to the counter input 51 of the main preset counter 2 are added to the preset value of the main preset counter 5. 5 is shown on the connected display unit 12 directly in the temperature reading in the desired thermodynamic step. To end the measurement interval occurs in the time of generating the control voltage at the output of transmission 74 pomooného presettable counter 2 · ^This occurs only after a certain precise time interval which is realized pomooným presettable counter 7 via the transfer counts the oscillation frequency of normal 11 at the time interval which can

In the first case it subtracts from the preset value or in the second case it adds to the preset value reference pulses, which from the beginning of the measuring interval pass from the output of the auxiliary amplifying and shaping circuit 9 through the auxiliary gate 8 on the counter input 71 · At the time of resetting the auxiliary counter 2 ^{in the} first case, or when the auxiliary counter is filled in the second case, a control voltage is generated at the transmission output 2IZE * which terminates the measurement interval. In both cases it is the conversion of the specified number of reference pulses to the time interval between the start of counting and the generation of the control voltage at the transmission output 7 ^ «. In the first case the time interval is given by the number of reference pulses between preset value and zero. given by the number of reference pulses between preset value and filling of preset counter 7 *

In order to avoid an error being introduced into the measurement interval due to a certain reference pulse width, the instant of generating control voltage at the trip output 61 is synchronized with the reference pulse edge, which is taken from the auxiliary preamplifier and shaping circuit output 6 and applied to the logic control circuit 63 6. The described circuit converts the equation of the line expressing the temperature dependence of the natural frequency of the crystal thermometric sensor from the form 5 f (t) = at + b

233 255 where: f (t) denotes the frequency of the sensor, t denotes the temperature, where a, b are constants to the form:

-1 -1 tsa.f-a.b suitable for directly expressing the temperature in the desired thermodynamic scale on the display of a single 12 in numerical form.

The advantage of wiring is its simplicity, individual circuit elements can be realized from commonly available numbered integrated circuits. From the separate output 13 for further use it is possible to output a signal for automatic registration and processing of the record. By simply changing the preset, it is possible to obtain an expression of the temperature in another thermodynew scale.

Claims (3)

SUBJECT OF THE INVENTION 233 255 Crystalline thermometer wiring with preset counters, characterized in that the output of the measuring oscillator (1) controlled by the temperature-dependent crystal thermometric sensor (2) is connected to the input of the main preamplifier and the molding circuit (3), the output of which is connected to the input (41). a main gate (4) whose output (42) is connected to a counter input (51) of the main preset counter (5), whose status outputs (54) are connected to the inputs of the display unit (12), the opening control input (43) of the main the gate (4) and the opening control input (83) of the auxiliary gate (8) are connected to the trip output (61) of the logic control circuit (6), whose setting output (62) is connected to the input (53) for presetting the main preset counter , (5) provided with preset inputs (52), and further, the adjusting output (62) is connected to an input (73) farther to preset the auxiliary preset a preset counter (7) provided with preset inputs (72), wherein the transmission output (74) is connected to the shut-off control input (44) of the main gate (4) and further the transmission output (74) is connected to the shut-off control input (84) (8), the output (82) of which is connected to the counter input (71) of the auxiliary preset counter (7), the input (81) of the auxiliary gate (8) being connected to the output of the auxiliary amplifier and shape circuit (9) connected to the output of the reference oscillator (lo) controlled by the frequency normal (ll). 233 255 Wiring according to claim 1, characterized in that the logic control circuit (6) is provided with a synchronization input (63) which is connected to the output of the auxiliary amplifier and circuitry (9) and has a longer input (64) for external control. a switching element (14) and an input (65) for controlling the internal measure of the measurement by the control element (15). Connection according to Claims 1 and 2, characterized in that the status outputs (54) of the main pre-adjustable counter (5) are led to a separate output (13).