DE1907056A1 - Circuit for a temperature sensor - Google Patents

Description

Standard electrical system Lorenz AG 1907056

7000 Stuttgart-Zuffenhausen
Hellmuth-Hlrth-Strasse 42

G.G. Gassraann -72

Circuit for a temperature sensor

The invention relates to a circuit which the multiplication product of the temperature measured by the temperature sensor and a ■ second multiplicant or the integral of this multiplication product. Circuits of this type are already known in which e.g. the ohmic resistance of a cold or hot conductor is used to measure the temperature and one multiplicant is an impressed current constant value that flows through the temperature sensor. The on the voltage dropping over it then corresponds to the multiplication product. Of the-

Such circuits have the disadvantage that they require a digital evaluation are not easily accessible and, moreover, an integration of the multiplication product is only possible with great difficulty. Particularly The disadvantage is the fact that the dependence of the ohmic resistance on the temperature in such elements is strongly non-linear, so that they are completely unsuitable in the case of a temperature difference evaluation.

The invention has the task of creating a simple circuit ai, with which both the multiplication product and its integral can easily be determined. Another object of the invention is in being able to carry out the evaluation digitally. In addition, it should be possible to use it for temperature difference measurements without major measurement errors be.

In a circuit of the type mentioned, this is done according to the invention achieved in that a semiconductor element with from as a temperature sensor

29th January 1969. "A.

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the temperature-dependent locking delay time is used, the control pulses are supplied with a stabilized amplitude, the frequency of which represents the second multiplicant and which appear at the output of the semiconductor element Pulses are fed together with the control pulses to an AND circuit and the mean value of the output pulses of the AND circuit as Multiplication product or the area of all output pulses serves as an integral of the multiplication product in a manner known per se by means of an integrator (e.g. by means of an auxiliary frequency and an electronic Counter) is evaluated.

According to a further feature, it is provided that when evaluating the temperature difference between two objects, e.g. two liquids, two semiconductor elements with temperature-dependent locking delay time and the output pulses of the respective AND circuit in rhythm

a switching frequency sequentially to the integrator (e.g. electronic ' Counter) whose counting direction (up / down) is switched synchronously with this switching frequency.

In addition, it is considered to be particularly advantageous that in the Evaluation of temperature differences a single semiconductor element with temperature-dependent blocking delay time serves as a temperature sensor and with an electromechanical arrangement in the cycle of a switching frequency is alternately pressed against the two objects, their temperature difference is to be evaluated, and the counting direction (up / down) of the downstream integrator synchronously with the switching frequency (e.g. electronic counter) is switched.

The invention has the advantage that by means of a simple circuit a digital integration by means of a meter is possible. The fact that the locking delay time can be approximated very well is particularly advantageous increases linearly with temperature. This makes it very easy to has relatively small temperature differences over a relatively large temperature range to evaluate, whereby the difference is again formed digitally by switching the counting direction of the integrator,

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The temperature difference measurement with one is particularly advantageous single temperature sensor, which is pressed alternately against the two objects in the rhythm of a switching frequency, because in this way the tolerances, aging and the like with small temperature differences fall out completely, so that the unavoidable measurement error is smaller, the lower the temperature difference, while with all methods with two temperature sensors the measurement error with decreasing temperature difference increases extremely sharply.

A particularly interesting application example for the inventive Switching is the measurement of the amount of heat in heating technology. A pulse frequency is generated with a known pressure flow meter, which corresponds to the flow rate of the liquid. This pulse frequency serves as a control signal for the temperature sensor

ler working semiconductors with temperature-dependent blocking delay time.

Another application is the display of the mean value of a certain Time range measured temperature, e.g. the display of the mean daytime temperature.

Based on the embodiments of the accompanying drawings are now in the following explains the invention and other of its features and advantages:

1 shows the circuit of the semiconductor element (transistor 3) working as a temperature sensor and of the AND circuit 5. In this, 1 is the input terminal to which the control pulses with a stabilized amplitude are fed. These pulses are fed via the coupling resistor 2 to the base of the transistor 3 with a temperature-dependent blocking delay time. h is the collector resistance of the transistor. The pulses appearing at the collector and the pulses fed to terminal 1 are fed to an AND circuit 5, at whose output 6 the limited or modulated pulses appear. The known AND circuit consists of the

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.both diodes 7 and 8 and the resistor 9 · All others can also AND circuits are used. About the base resistor 10 can a additional auxiliary voltage on terminal 11 to adjust the Blocking delay time can be used to the desired value.

The mode of operation of this circuit is to be explained in more detail with reference to FIG The voltage at terminal 1 of FIG. 1 is shown in FIG. 2a. Fig. 2b shows the voltage at the collector of transistor J5, whose reverse delay time is j ". Both voltages become the AND- ■ Circuit supplied so that at the output 6 the voltage - according to FIG. 2c stands. This voltage can only occur during the locking delay time * £ " almost 0 volts drop, so that negative-going pulses with a pulse duration equal to the temperature-dependent blocking delay time ^ ". From this it can be seen that in this case the negatively directed Impulses are considered. For this reason, the. Circuit 5 uses the designation AND circuit. One would get the impulses count in the positive direction, one would have to use circuit 5 as an OR circuit grasp.

A particularly simple averaging can be achieved by using the pulses with the duration * Γ either directly or via an amplifier Instrument with correspondingly sluggish indicator supplies. In other cases it may be useful to use RC low-pass filters for averaging. A particularly useful application for such averaging is shown in an example described below.

In the event that not the mean, but the integral of the multiplication product is to be evaluated, an auxiliary frequency can be used in a manner known per se for sampling the pulses with a duration of 4 " and count the sampling periods of the auxiliary frequency with an electronic counter.

In Fig. 5 the block diagram of such an arrangement is shown. In this JO is 12 the pulse source, the frequency of which is represented by the one multiplier, 1J5 is the multiplying temperature sensor, according to FIGS. 1, 14 is one

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AND circuit, which in this case works as a gate circuit. 15 is a Generator of relatively high frequency, l6 is the counter that is used by the generator 15 periods supplied, which are in the time range * £ "of the temperature» the impulses supplied by the sensor are what counts. 25 is a connected mechanical one Counter with numeric display.

In Fig. 4a the pulse signal of the source 12 is shown.

In Fig. 4b the (in this case shown as positive) pulse period *? * shown. '

Finally, FIG. 4o shows the voltage leaving the gate circuit 14.

The period of the generator 15 does not have to be significantly lower than the duration will be * £ * if the frequencies of the generators 15 and 12 are not synchronous are. In this non-synchronized state, you average over one corresponding time range quantization errors.

With reference to FIG. 5, a particularly expedient use of the inventive Circuit are explained in more detail. It is a device that provides the output over a certain period of time Thermal energy of a flowing liquid counts. The counter shows how many kcal emitted from a radiator, for example, in a reading period became.

In Fig. 5, 17 is the supply pipe, 18 the exchange site, e.g. a Radiator, and 19 the drain pipe. A small impeller 20 is rotated by the flowing liquid. It controls with known means contactless the pulse generator 21. The number of electrical pulses it emits in a time range are proportional to the amount of liquid, which has flowed through the exchange site in this time range. 22 and 23 are two temperature sensors according to the invention, 24 is a very slowly switching one Clock that receives the pulses coming from the pulse generator 21 by means of the switch 26 alternately forwards it to temperature sensors 22 and 2j5. 14 is the gate circuit, 15 is the relatively "high frequency generator. 16 is the Counter, however, in this "application synchronous with the Umsahalter 26 im

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electronic counters may have a relatively small counting volume. That _; Counting volume only needs the grb'ssten period number that falls within the time range \ to meet.

This counter 16 is followed by an electromechanical counter 25, • 5 which is also switched to the rhythm of the clock frequency. In the In most cases, switching over of the electronic counter 16 is superfluous, since the counting errors in forward and backward operation vary over time Save means if the counting volume is correspondingly small. Switching over ensures that the difference is calculated digitally and therefore absolutely works safely while a difference is formed before the multiplication, e.g. by sending pulses whose duration is the difference in the blocking delay times

J. and *) ρ of the two temperature sensors would correspond, would be much more difficult and unreliable.

Figure 6 shows a particularly advantageous arrangement for measuring the temperature difference shown, by which it is achieved that the specimen aging, tolerance and the like., When using two temperature sensors - arise, be turned off.

In FIG. 6, 17 is the supply pipe, 18 the drain pipe running parallel in this case, 27 and 28 are blocks which have the temperatures of the corresponding liquids, 29 is the one and only temperature sensor that works with the electromagnetic arrangement JO in the rhythm of the Clock frequency is pressed once on one and once on the other block. The changeover switch 26 in FIG. 5 is of course omitted in this arrangement. The switchover of the counter or counters 16 and 25 is still carried out synchronously with the clock frequency. This arrangement ensures that measurement errors remain extremely small, especially in the case of small temperature differences, since aging effects in the one and only element are eliminated by the formation of the difference. In addition, there is the advantage that a comparison, as is the case with the arrangement with two temperature sensors, for the purpose of creation

30. synchronization is absolutely necessary, is not applicable here. This example shows the evaluation of the integral of the multiplication product. Do you want

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determine the instantaneous power emitted by the radiator or display, you can only form the integral over a clock period by using another counter to determine the result of the respective even holds and displays the completed up and down counting. So far the arrangement when evaluating a temperature difference measurement.

The same procedure can of course also be used where it is not the temperature difference but the absolute value of the temperature that is to be evaluated. With chemical processes it often happens that the result depends on the multiplication product, the temperature and the duration of exposure. After a certain value of temperature times duration has elapsed, the relevant process should be switched off. This is relatively easily possible with the arrangement according to the invention according to FIG. J, since the frequency generator 12 supplies a fixed frequency which, however, can optionally be switched from case to case. The instantaneous temperature, weighted with the respective setting of the frequency of the generator 12, can be displayed by averaging the output pulses of the temperature sensor 1J> by feeding them either directly or via an amplifier to a pointer instrument with corresponding inertia. In this way, the multiplication product is displayed directly.

J5 claims

2 sheets. Drawings with 6 Fig.

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Claims (2)

GG Gassmann - 72
Claims Circuit for a temperature sensor which supplies the multiplication product of the temperature measured by the temperature sensor and a second multiplicant or the integral of this multiplication product, characterized in that a semiconductor element with a temperature-dependent blocking delay time is used as the temperature sensor, to which control pulses with a stabilized amplitude are supplied, the frequency of which is the second multiplicants and the pulses appearing at the output ■ of the semiconductor element are fed together with the control pulses to an AND circuit and the mean value of the output pulses of the AND circuit serves as the multiplication product or the area of all output pulses as the integral of the multiplication product in a manner known per se is evaluated by means of an integrator (for example by means of an auxiliary frequency and an electronic counter). 2. Circuit for a temperature sensor according to claim 1, characterized in that two semiconductor elements with temperature-dependent blocking delay time are used and the output pulses of the respective AND circuit are sequentially fed to the integrator (e.g. electronic counter), whose counting direction (up / down ) is switched synchronously with this reversing frequency. J5. Circuit for a temperature sensor according to claim 1, characterized in that a single semiconductor element with a temperature-dependent blocking delay time serves as a temperature sensor and is pressed alternately against the two objects whose temperature difference is to be evaluated, using an electromechanical arrangement at a switching frequency, and synchronously with the switching frequency The counting direction (forwards / backwards) of the integrated integrator (e.g. electronic counter) is reversed. 009847/0225 Blank page