DE3429729A1 - Flow measurement arrangement operating on the calorimetric principle - Google Patents

Abstract

The invention relates to an arrangement for flow measurement in accordance with the calorimetric principle, using a control loop.

Description

Due to the simplicity and today's availability

corresponding components, such as temperature-dependent semiconductors in miniature design, flow monitoring devices that are based on the calorimetric Working principle, constantly increasing in importance.

Offenlegungsschrift DE 32 22 o \ 046 Ai.

Common to all known devices and: process, -that a part exposed to the flow to be controlled is electrically heated and the temperature that is established on this part is measured. The one that appears Temperat.ur depends on the thermal conductivity of the medium, the temperature of the medium and the flow rate of the medium and the supplied heating power.

m generally eliminating the influence of the medium temperature in addition, the medium temperature is recorded and, as a variable to be processed, the Temperature difference between the medium and the heated flare element.

In principle, the temperature difference is the smaller, the more the flow velocity of the medium to be controlled is greater The resulting temperature difference is then optionally converted into an electrical switching signal, in the case of flow monitors, or to an analog measurement signal, in the case of Flow meters, further processed.

What is common to all previously known * according to the calorimetric described above Principle working devices that the necessary to heat the FiJthlerelemenetes Heating power is constant. Thus, the primary result is for the desired effect The measured variable to be processed further is the temperature difference between a with constant Heating power beau + hit sensor element and the medium temperature has a disadvantageous effect With the known methods, the constant heating power of the heater element because this limits the working area of the devices considerably.

In the case of constant heating power, this must be dimensioned in such a way that Inadmissible overheating can occur when the medium is at rest.

Since, in principle, the primary measured variable is the temperature difference between If the heater element is heated and the medium is heated, this decreases at a constant value from the above Reasons of limited heating output very quickly below the measurable limit, which means the applicability of this principle after higher flow velocities senr is limited.

The method described below on which the invention is based extends the applicability of the calorimetric method significantly.

According to the invention, known calorimetric methods are used to this effect extends that the temperature difference between the heated sensor element and the medium is not used as a measured variable, as was previously the case, but as a rule variable and the Measured variable is formed by the rule variable This method has opposite the known processes have a number of essential advantages: t. The temperature difference between the sensor and the medium can be kept extremely low.

2. When the medium is at rest, the heating output is very low and there is no risk of overheating.

The working range of the calorimetric principle becomes higher Flow velocities increased considerably.

4. The relationship between measured quantity and signal quantity follows one more linear function than with. constant heating power.

5. The measured value can be digitized with simple technical means and therefore very easy to decompose. with a microprocessor, further process as required.

According to the invention described here, the object is achieved the flow measurement, a control loop built up from the following elements consists of 1 sensor element consisting of a heating element with an assigned temperature sensor 2. Temperature sensor for recording the temperature of the medium to be controlled Medium and 4. a rule organ This arrangement is generally applicable, regardless of the design of the sensor elements. For example, arrangements are known where the temperature sensor has a direct thermal connection with the heated one Has a flow + cooling element and thus also above the medium temperature is heated. The method described can also be used for such arrangements use.

A simple embodiment of the invention is shown in Fig. 1 shown. A temperature sensor (semiconductor or temperature-dependent resistor) (RTh) is used heated by a heating resistor (H) and is with one the temperature of the medium detecting second temperature sensor (etc) connected in series and closed. a bridge circuit expanded. With the potentiometer (Rr) a value can be set as the control voltage, which determines the size of the temperature difference between the medium and the sensor and so that regulates the heating current.

The arrangement shown keeps the temperature difference within specified limits constant between Mess + ühler and media.

The current flowing through the heater is proportional to that to be measured Flow velocity.

To increase the linearity of the output signal, you can also use corresponding switching means the heating power as a measure of the flow rate Select.

Another example is shown in Fig.2. Here is the bridge signal fed to a two-point controller, which, depending on the bridge voltage, switches the heating current or turns off.

This results in those in Fig. 2a for a low flow velocity and in Fig. 2b diagrams shown for a greater flow velocity for the heating pulses.

The resulting pulse p a u s e n ratio is here a measure of the flow velocity. This pulse-pause ratio can be output either through integration in analog form or through digital processing as a digital value.

Another possible simple embodiment is shown in Fig.

Here is a flow measuring arrangement based on the control principle described above shown in two-wire technology. via a series resistor, which is also used as a constant current source can be formed, a bridge circuit, as described above, is fed. The output of the amplifier controls one in series with the heating resistor Controller such that the conditions of the control loop, namely the temperature difference to keep constant between the medium and the sensor is fulfilled. This regulator lets any controllable resistor, for example a transistor, represent. An ammeter connected in series with the arrangement then shows one the current proportional to the flow velocity. This arrangement can be in the form presented for operation on both DC and AC networks use if they are connected to a simple rectifier circuit, not shown here is expanded.

Another embodiment of the invention is shown in Fig.4. Here the bridge signal is first fed to a threshold switch (SS) and then from a downstream pulse shaper (IF) to a defined pulse further processed, with which the heater is then operated.

The resulting pulse diagrams for low and high flow rates show Figs. 4a and 4b. Because the flow rate is proportional to the time between the individual heating pulses can be achieved with this arrangement realize advantageous circuits. In connection with today in large numbers The available digital ICs can thus be practically all imaginable Realize measurement, regulation or control tasks.

A further implementation using ICs available today will be below based on the basic circuit explained in bb.4 of the block diagram in Fig. 5: The calling is an unknown, to register the existing flow velocity as the target flow velocity and if there is a deviation from this target flow rate by an adjustable value Value to send a signal.

The arrangement consists of a circular connection as described in Fig. 4 for the delivery of impulses proportional to the actual flow velocity, an integrated pulse generator (IG), a main counter: - (HZ), a controllable one Preset counter (TARGET), an adjustable preset counter (SELECT) and a button (T).

The pulse generator (IG) is permanently connected to the main meter (HZ) and is opened again by the pulses emitted by the measuring circuit (MESS) "0" reset.

With the (T) key, the auxiliary counter (TARGET) is temporarily saved with the Measuring circuit connected in such a way that the value just registered for the flow velocity is entered as a setpoint in this auxiliary meter.

A preset value ratio is established via a further auxiliary counter (CHOICE) set to the value Qell read into the auxiliary counter (TARGET). This is that Value, when reached, a switching signal should be given.

The required switching signal is not given as long as the Main counter by the measuring pulse again before reaching the set switching value is set to "0".

Since the arrangement described above is general today well-known digital technology is involved here on detailed circuitry Description omitted.

Claims (3)

Flow measuring arrangement P operating according to the calorimetric principle a t e n t a n s p r ü c h e i. clutter for a calorimetric principle working flow measuring arrangement, consisting of a heated one to be measured by the Flow influenceable temperature measuring element and a second, primarily the Temperature measuring element detecting the temperature of the medium to be measured, characterized in that that the temperature difference between the two temperature measuring elements is used as a control variable is used for a control loop and the control loop forms the measured value. 2. Arrangement according to claim t, characterized in that the Temperaturdif f erence between the temperature measuring elements through an electrical bridge circuit is fixed. 3. Arrangement according to claim 1 d a d u r c h g e k e n n z e i c h n e t that the temperature difference between the two temperature measuring elements can be set is. 4. Arrangement according to claim 1, characterized in that the temperature difference between the two temperature measuring elements by never returning the measured value is changed. 5. Arrangement according to claim 1 to 4, characterized in that the Heating current is used as a measure of the flow velocity. 6. Arrangement according to claim 1 to 4 characterized in that the Heating voltage is used as a measure of the flow velocity to be measured. 7. The arrangement according to claim ibis 4, characterized in that the Heating power is used as a measure of the flow velocity to be measured. 8. An arrangement according to claim 1 d a d u r c h g e k e n n z e i c h n e t that the the temperature difference between the two temperature measuring elements generating heating energy is fed to the heater in pulses. 9. The arrangement according to claim i and 8, characterized in that the The heater is switched on and off by means of a two-position controller, which is controlled by the temperature difference between the two temperature measuring elements is controlled in such a way that that when the temperature drops below a specified temperature difference, the heater switches on and off if a specified temperature difference is exceeded, the heater is switched off 10. Anorcinungnach claim 1 and 8, characterized in that the pulse Pause ratio is used as a measure of the flow velocity. 11. The arrangement according to claim 1 and 1, characterized in that the Pulse-pause ratio is determined by integration and the measured value is analog is issued. 12. The arrangement according to claim 1 and 1, characterized in that the Pulse-pause ratio is determined digitally and the measured value is output in analog form will. 13 arrangement according to claim i and 1, characterized in that the Pulse-pause ratio is determined digitally and the measured value is output digitally will. 14 arrangement according to claims 1 and 8, characterized in that at Falling below a specified temperature difference between the two temperature measuring elements the heater is switched on. 15 arrangement according to claim i and 14, characterized in that the Duty cycle of the heater is constant. Xb. Arrangement according to claim 1 and 14, characterized in that the switch-on time of the heater is determined by the measured variable. 17. Arrangement according to claim 1 and 14, characterized in that the switch-on time of the heater is not constant and can be selected externally. 18 arrangement according to claim t and 8 characterized in that at exceeding a predetermined temperature difference between the two temperature measuring elements the heater is switched off. 19. The arrangement according to claim 1 and 18, characterized in that the switch-off time of the heater is constant 2. Arrangement according to claim 1 and 18 characterized in that the switch-off duration of the heater is determined by the Hess size is determined. 21. Arrangement according to claim 1 and 18, characterized in that the switch-off duration of the heater is not constant and can be selected externally. 22. Arrangement according to claim 1, 8, 14 to 21, characterized in that that the time that elapses between the individual heating pulses is measured and as An arrangement according to claims 1, 8 and 22 is used as a measure for the measured variable marked that the time serving as the measured variable is determined analogously. 24. Arrangement according to claim 1, 8 and 22, characterized in that the time serving as the measured variable is determined digitally. 25. Arrangement according to claim 1, 8 and? 4 characterized in that Instead of the pulse duration for the heating pulse, the heating voltage is changed. 26. Arrangement according to claim 1 and 8 to 24, characterized in that that both the pulse duration and the heating voltage are changed. 27. The arrangement according to claim 1 to 26, characterized in that the heating resistor consists of a temperature-dependent resistor. 28. Arrangement according to claim t and 8 to 27, characterized in that that a digital memory is assigned to it in which the respective measured value is carried out separate command to be written in later, further processing can. 29. Arrangement according to claim 1 and 8 to 27, characterized in that that in addition to the measuring arrangement a microprocessor belongs to the measured value accordingly processed according to a given program. 3 arrangement according to claim 1, 28 and 29, characterized in that the microprocessor comparing operations according to selectable program between Carries out stored value and measured value.