SE466820B - PROCEDURE AND DEVICE FOR FLOW SPEED Saturation - Google Patents

Description

A466 820 is replaced without recalibration of the bridge. A further disadvantage is that the electronics used must be specially designed for the purpose and it can thus not be used for anything else.

Another known flow meter with a heatable measuring body is based on heating the measuring body in a measuring process and then allowing it to cool under the influence of the flow of nutrients. The heating and cooling are performed in succession so that the temperature of the measuring body will vary between two temperature levels, both of which are significantly higher than the temperature of the medium to be flow measured. In a typical example, the upper temperature level is 146 ° C and the lower 96 ° C, and then the medium to be flow measured is thought to be air at room temperature. The time for heating the measuring body from the lower to the higher temperature level and the cooling time from the higher temperature level to the lower one are used as measured values on which the speed calculation is based. This known technique entails a rather complicated design in order to make the heating take place with a constant power and between carefully defined temperature levels.

Variations in the heating effect cause significant measurement value errors and the same applies to inaccuracies for the temperature levels. Also in this known embodiment a further measuring body arranged in the media flow is required, which is unheated and which has the task of reflecting the current temperature of the air stream. Here, too, there are imbalances between it. the heated measuring body and the unheated measuring body give rise to measuring errors.

SUMMARY OF THE INVENTION The object of the present invention is to further develop the method and the device according to the preambles of claims 1 and 8, respectively, which preambles report the second example of the prior art given above, so that the method and the device are simplified but nevertheless create conditions for greater measurement accuracy. dependence on potential sources of error is reduced. 466 820 This object is fulfilled according to the invention by the features which are further defined in the features of claims 1 and 8. Accordingly, the present invention is based on the fact that the heat exchange between the measuring body and the media flow follows an exponential process related to the flow rate. The core of the inventive idea is consequently to perform, in diametrical contrast to the initially reported prior art, the measurements of the temperature variable physical quantity of the measuring body with such a known or constant time basis that data is obtained, which gives an unambiguous 'description' of the exponential process. On the basis of the measured values and time data, the flow rate can thus be determined or calculated under the following well-known mathematical / physical principles. The physical quantity measured is preferably, though not necessarily, an electrical quantity, such as resistance.

When applying the method and the device according to the invention, elimination or reduction of a plurality of sources of error is achieved which adheres to the prior art. For example, no unheated measuring body with the same temperature coefficient as the heated measuring body is required. According to an embodiment of the invention (claim 3), the dependence on the heating current and time is completely eliminated. According to another embodiment (claim 2; measurement during heating), the dependence on variances in the heating current is at least significantly reduced since no long-term stability of the current is required as in the prior art. Consequently, in addition to the elimination of the need for a special unheated reference sensor or measuring body, the method and device according to the invention are characterized in that the measurement takes place during a process which is actively initiated (in terms of changing the temperature of the measuring body) but which is not controlled. balance or any intended final value; in the absence of such control, no feedback is required in order to achieve the balance or final value.

This is the key to achieving the simplicity and accuracy of the object of the invention. According to a first embodiment of the method, the quantity RO (see Fig. 1), which is exemplified here as resistance, of the measuring body is measured when the measuring body has substantially the same temperature as the medium flow. It is then appropriate for R to be measured as the first step 0 in the measurement process. Then (at A) a heating current A is applied through the measuring body which increases the body's temperature and thus resistance. After the required heating, the heating current is switched off (at B) and then at least two measurements R1 and R2 are made in rapid succession of the resistance of the measuring body. In this case, it is important (but easy to achieve) that the time difference between the measurements is known or in a number of measurement processes the same. In the simplest case, the same time difference is always applied, but different time differences can also be used provided that they are known in the individual measurement process. In case the same time difference between the measurements is always applied, it is in fact not necessary that the time difference is known, but instead calibration is performed in a manner well known in the measurement technique so that the still applied, always equal time difference means that the intended measurement values are obtained.

After the heating of the measuring body has been switched off at B, the measuring body will cool down and finally reach the temperature of the media flow, i.e. RO. From what has been said, it appears that RO could instead be measured after completion. cooling but this means unnecessary time and in addition that prevailing flow conditions can change significantly. In a measuring system where several sensors with measuring bodies are included, the next sensor can be connected immediately after the measurement of R2 if RO is measured first.

If the temperature dependence of the trees is constant within the utilized temperature range, the resistances can be directly translated into energy levels. The relative energy loss from the measuring body during cooling then becomes: (P1-P2) / (P1-P0). Experiments performed show that the relative energy loss, calculated in this way, of the measuring body after heating is only dependent on the dtl2, the aerodynamic properties of the measuring body and the actual flow rate. The relative energy loss was found to be largely independent of: - heating current - heating time delay after heating length of the measuring body nominal temperature coefficient of the measuring body (independently means that the dependence is not greater than that it can be made negligible without increasing the cost of the measuring equipment).

These results are explained by the fact that, as mentioned above, the heat exchange between the measuring body and the media flow follows an exponential process. In the case of a measuring body in the form of a tree, the exponential course is characteristic of a certain wire diameter. An exponential process is unambiguously described if the end point and two points with a known time difference are known.

Thus, in accordance with this embodiment of the present invention, all required information on the exponential course of the temperature equalization (heat exchange) between measures 1, R2 and the time difference between R1 and R2 is obtained. Consequently, by means of these measured values and the body and. the media flow genonl RO, R the time difference the flow rate is calculated.

According to a second embodiment of the invention, an unambiguous description of the exponential course of the flow rate-dependent temperature equalization between the measuring body and the media flow can be achieved by measuring the actual physical quantity, eg the resistance, of measuring 1, R2 and R3 during the cooling of the measuring body. , wherein the time difference between both R1 and R2 and R2 and R3 is known to the body at least three times, namely R or always the same. Consequently, with knowledge of these measured values R1, R2 and R3 and the time differences between them, one can calculate the flow rate according to per se well-known principles. When at least three measured values are taken during the cooling, no measurement of R, i.e. the value of 1, is no longer required. the physical quantity when the measuring body has substantially the same temperature as the media flow, but this is defined by the exponential process. This means that according to this embodiment of the invention it is no longer necessary to allow the measuring body to cool to substantially the temperature of the medium flow, but instead the measuring body can be caused to oscillate relatively quickly between two different temperature levels, during the cooling between these levels at least three measurements.

According to a third embodiment of the invention, it is also possible to perform flow rate measurement by measuring the physical quantity, in particular the resistance, at least three times during the heating of the measuring body, see R4, R and R6, the time difference between R and R and between R and R is known or always the same. Here, too, the measured values R 1, R 5 and R 6 and the time differences therebetween give a clear description of the exponential course of the heat exchange between the measuring body being heated and the media flow so that the flow rate can be calculated on the basis of the measured values and time differences.

Since the quantity measurements are performed without any maintained balance or without defining defined temperature levels, variations in the heating conditions (heating current) over a longer period will not interfere with the obtained flow rate value. Also for this embodiment with measurement during heating it applies that the physical quantity (RO) of the measuring body does not need to be measured when the measuring body has substantially the same temperature as the medium flow and also when the measuring body has a final value in terms of temperature but also here the measuring body by alternating heating and cooling is caused to rapidly oscillate between two different temperature levels, both lying above the temperature of the media flow. Thus, according to the invention, these temperature levels need not be known or determined.

When measuring during heating, it is suitable to carry out the heating with a substantially constant effect or otherwise with known characteristics.

According to a fourth embodiment of the invention, it is also possible to perform flow rate measurement in particular in media with relatively high temperatures while in a measuring process the measuring body is first actively cooled to a temperature below the medium temperature and then the measuring body is allowed to be heated under the influence of media flow. in the direction of or to its temperature. During the heating of the medium flow, measurements of a physical quantity of the measuring body which changes with temperature can be performed to obtain measured values (analogous to RO, RR or R1, R1, R3) and time data sufficient for a clear description of the exponential course of the heat exchange. in basically similar, although in terms of temperature change reversed, ways as already described above for the cooling case. In analogy to what has already been described above with reference to the third embodiment, the physical quantity can also be measured at least three times during the positive cooling process in order to obtain measured values corresponding to those denoted by R R and R in the heating case 4 '5 6.

The method and device according to the present invention, in the case of gas, provide, as in the case of hot body flow sensors in general, the mass flow, i.e. the relationship between the measured number and the flow rate in meters per second changes in accordance with the general gas law when medium temperature and air pressure change. 466 820 The term "determination or calculation" as used herein with respect to the flow rate on the basis of the measured values and the time differences between the measurements should, as already stated from the above, be interpreted in a broad sense. On the one hand, when the time differences are known, a regular mathematical operation, manually or in a computer, can be performed. However, when the time differences between performed measurements are always the same, calibration can instead be performed such that the obtained measured values can be the basis for deriving flow rate reflecting 'values without. does anyone know the actual time difference between the measurements?

It is a given that the exponential course in terms of the heat exchange between the measuring body and the media flow is affected by changes in the media temperature and speed during a measuring process.

According to the invention, the flow rate cannot be monitored completely continuously. However, the embodiments defined in more detail in claims 2 and 9 allow oscillation involving heating and cooling or, conversely, with relatively high periodicity, which allows fairly good following of flow rate changes. When measuring average flow rates, it is not of interest to continuously monitor the flow rate.

BRIEF DESCRIPTION OF THE DRAWINGS Referring to the accompanying drawings, a more detailed description of exemplary embodiments of the invention follows.

In the drawings, Fig. 1 is a diagram illustrating the relationship resistance / time (or approximate energy / time or temperature / time), Fig. 2 is a basic circuit diagram of the device according to the invention, and Fig. 3 is a schematic view illustrating another embodiment of the measuring body. than that in Fig. 2.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS Figs. 1-2 The embodiment described below relates to the case where RO, R and R2 1 are measured.

As a means for measuring the flow rate indicative resistance values RO, R1 and R2 and means for calculating the flow rate of the medium in question on the basis of these values, a suitable computer 1 is used, which is preferably in the form of a programmable data logger. In experiments, such a data logger available from the company Campbell Scientific Inc., Logan, Utah, USA under the designation "CR 10 Measurement and Control Module" was successfully used. In the experiment, this was equipped with two AM 416 16-channel relay multiplexers 2. A control connection between the data logger 1 and a relay multiplexer is indicated in Fig. 2 by 3.

To each of the relay multiplexers 2 were connected measuring bodies 4, the resistance of which changes with temperature. Measuring bodies in the form of wires were used. More specifically, these wires were of Pt and their diameter was 0.1 mm. A diameter range suitable from a practical point of view should here be below 0.5 mm, preferably 0.01-0.2 mm.

Fig. 2 illustrates only two sensors 5 provided with measuring wires 4. Although this is not illustrated in Fig. 2, in the experiment several sensors were connected to the relay multiplexers. The measuring wires 4 can for instance be fastened, such as by soldering, between the legs of a holding bracket. By means of the relay multiplexers 2, a set of switches 6 is controlled for each 1466 820 10 by the sensors 5. In practice, the distance 'between the sensors 5 and the respective relay multiplexer 2 was between 10 and 80 meters. To normalize the cable resistances to the resistance that applied to the four longest cables of 80 meters, resistor 7 with a resistance value depending on the current cable length was used.

Connected to the data logger 1 is a relay 8 including a switch 9 for stopping and interrupting the heating current via a conductor 10 and a current limiting resistor 11 to the sensor 5 in question.

The data logger 1 has an output 12, which is excited, gives a constant voltage, during resistance measurement and is applied to the measuring wire 4 of the respective sensor 5 via a reference resistor 13 via a switch of the relay multiplexer 2 in question.

The data logger 1 further has connections 14, 15 for voltage measurement, which connections are connected via conductors and respective switches 6 over the respective measuring wires 4.

The relay multiplexers 2 enable a single data logger 1 to serve a large number of sensors 5, which are successively connected to the data logger's connections for heating current and measurement.

When a certain sensor 5 is to perform a measuring process, it is connected by means of the relay multiplexer 2 to the data logger 1. First, the resistance RO of the measuring wire 4 is measured without prior heating, i.e. when the measuring wire 4 has the temperature of the media flow.

Then the switch 9 is closed by means of the relay 8 so that a heating current flows through the measuring wire 4 and this is heated.

At point B in Fig. 1 (this point does not have to be well-defined at all), the heating current is interrupted and then the data logger 1 automatically takes care of the two resistance measurements R and R in Fig. 1 during the cooling of the measuring wire l 2 4. The location of the measuring points R1 and R2 in time, i.e. during the exponential heat exchange process between the wire and the media flow, is not critical; however, it is appropriate that the two measurements R1 and R2 be made in a not too flat part of the exponential curve.

Thereafter, measurement procedures are performed in an analogous manner with other sensors connected to the data logger 1 via mediation of the relay multiplexers 2.

A test series of 22 sensors made in artisanal shapes and having measuring wires of 0.1 mm Pt wire was found to give measured values with very small mutual deviations. The measured value spread was within 1%, which is a remarkably good result.

In addition to the fact that the method and the device according to the invention entail excellent measuring accuracy, a special advantage lies in the fact that the sensors can be of an extremely simple and inexpensive kind. The electronic components needed to adapt the sensors to the data logger used were limited to the reference resistor 13 for the resistance measurement, the relay 8 and the current limiting resistor 11 for the heating current and a number of resistors 7 for normalizing the cable resistances.

The sensors 5 with the measuring wires or bodies 4 can also be used to measure, in addition to the flow rate, the temperature, which requires individual calibration of the sensors with respect to temperature. Such a combination of flow rate and temperature measurement is of particular interest in meteorological contexts and can be used in energy exchange measurements.

By simple programming, the equipment described with reference to Fig. 2 can be adapted to exclude measurement of RO and instead measurement of the at least three values R1, R2 and R3 during cooling.

Adaptation of measuring equipment suitable for the purpose in. And for R and R during the execution of the measurement of the measured values R4, 5 6 4-66 820 12 the heating is, against the background of the instructions according to the invention given above, within the area of competence of the average person skilled in the art. some further descriptions are given in this connection. Fig. 3 illustrates an alternative embodiment of the measuring body 4.

In this case, the measuring body comprises a hollow member 16, preferably in the form of a tube closed at one end 17. At least the part of the tube located closest to the closed end 17 of the tube is intended to be located in the media flow 18. The tube can then extend into the media flow through an opening in a wall 19 of a channel delimiting a media flow. A sealing means 20 is suitably arranged between the pipe 16 and the channel wall 19.

The tube 16 may suitably extend substantially perpendicular to the flow direction of the medium.

In the following description, the medium in question is thought to have a relatively high temperature. In such a case, for example, the duct wall 19 could be provided with cooling devices, for example internal cooling ducts. ß In this case, the means for causing the temperature of the measuring body 4 to deviate from the temperature of the media flow is arranged to cool the measuring body. More specifically, the cooling means comprises a suitable cooling fluid source 21, which delivers cooling fluid to a conduit 22, which extends into the measuring body 4 formed as a tube 16 to release the cooling fluid inside the tube 16 and thereby cool its inside. The line 22 can. for example, be arranged to discharge the cooling fluid towards the inside of the closed end of the tube 16 so that this inside is cooled, whereupon the cooling fluid is forced to turn and flow back inside the tube 16 away from its closed end 17 to finally be led out of the tube through an outlet 23. As illustrated in Fig. 3, it is convenient for the conduit 22 to enter the tube 16 at a point outside the channel wall 19 and i. 466 826 13 extend along the tube 16 within the same to a point fairly close to and opposite the inside of the closed end of the tube. .

The measuring means for measuring the temperature-varying physical quantity of the measuring body 4 here consists of an IR meter, which is schematically indicated at 24 and which comprises an IR sensor 25 arranged to sense IR radiation from the measuring body 4, more specifically the inside of the closed end of the tube 16. The IR meter 24 is as indicated in Fig. 3 connected to the end of the tube 16 from its closed end 17 and the IR sensor is directed along the tube to be able to detect the IR radiation from the inside of the closed end 17. This location involves, in combination with the cooling fluid, relatively good safety against overtemperatures of the 'IR meter and its sensor.

When performing flow rate measurement with the embodiment according to Fig. 3, according to a first variant, cooling of the tube 16 is performed by means of. the coolant 21, 22 so that the tube 16 is cooled down to a temperature below the medium temperature. Thereafter, the cooling is interrupted, which means that the tube 16 will tend to adapt in terms of temperature to the temperature of the media flow.

During this adjustment, by means of the IR meter 24, 25 measurements are made of the IR radiation (corresponding to the temperature) on the inside of the closed end of the tube. In this case, in the manner described in gmincip with reference to Fig. IL, at least two measurements can be performed which in combination with a measurement when the measuring tube 16 has substantially the same temperature as the media flow gives measured values which in combination with required information concerning the time difference between the first two the measurements give an unambiguous description of the exponential course according to which the temperature equalization takes place between the measuring tube 16 and the medium flow so that the flow rate of the medium can thereby be determined or "466 szo 14 calculated. Alternatively, at least three measurements of the IR radiation during the measuring tube 16 to the media flow, whereby the temperature equilibrium position does not need to be measured.

According to a second variant, at least three IR radiation measurements are made during the cooling process itself with a known or equal time difference, and on the basis of this the unambiguous description of the exponential process for the heat exchange conditioned by the media flow is obtained. This means that the cooling should be carried out with constant conditions or otherwise conditions with known characteristics.

If desired, the device according to Fig. 3 can of course be modified so that the coolant 21, 22 instead becomes a heating means, i.e. supplies fluid which causes heating of the measuring body to a temperature above the temperature of the medium flow.

POSSIBLE MODIFICATIONS The method and device according to the invention can of course be modified in a number of ways within the scope of the inventive idea. In the case of heating, the measuring body can be part of a more complex sensor of varying nature, which could have a special heating element, for example electrically, in order to heat the same by heat transfer to the measuring body. In this case, both the measuring body and the heating element could be enclosed in a body or body of the sensor. Such an embodiment could be particularly suitable for flow rate measurements in liquids, and thus the heat exchange between the measuring body and the medium would take place indirectly via some form of housing. As an alternative to the described measuring body in the form of a wire, more regular thermistors could also be used. Other types of measuring bodies, such as thermocouples, exhibiting other electrical quantities that are temperature-dependent can also be used. As can be seen from Fig. 3, physical quantities other than electrical ones can also be measured in accordance with the inventive concept. As an example it may be mentioned that (å.

The temperature is measured by means of a measuring body constituting a thermometer of a per se known or arbitrary type, for example a so-called optical thermometer.

Finally, it should be mentioned that in the case of a measuring body which is electrically heated, the measuring current and the heating current could be the same. This could then be applied to the measuring body continuously but with such varying strength that the measuring body would oscillate between separate temperature levels, which, however, do not need to be defined or known. As a result of the change in resistance of the measuring body as a function of the temperature, the measuring current (and also the heating current) will obtain a variance, ie constitute the physical quantity changing with temperature which is referred to according to the invention. By measuring this quantity, measured values and time data can be obtained sufficient for determining the exponential course of the heat exchange and thus the flow rate can also be determined.

A design according to these guidelines could provide a high measurement periodicity so that rapid changes in flow rate can also be followed.

Claims (18)

466 820 16 Patent claims A method for flow rate measurement, wherein a measuring body (4) exposed to the medium to be measured is used and in a measuring process the temperature of the measuring body is caused to deviate from the temperature of the media flow and is then allowed to adapt to or to the latter under the influence of the media flow. the measuring body will be heated and cooled or vice versa, and whereby flow rate indicative values are measured and on the basis thereof the flow rate is determined or calculated, characterized in that in connection with the heating and / or cooling of the measuring body measurements are made of temperature physical quantity of the measuring body for obtaining measured values and time data sufficient to give a clear description of the exponential process according to which the heat exchange between the measuring body and the media flow takes place, and that the flow rate is determined or calculated on the basis of these measured values and time data. 2. A method according to claim 1, characterized in that in a measurement process a) the physical quantity (R1, R3 and R4, R5, R6, respectively) 2! of the measuring body is measured at least three times during the heating and / or cooling of the measuring body, the time difference between the measurements being known or in a plurality of measuring processes equal, and that b) on the basis of the quantity measured values (R1, R2, R and R 3 4 'R5, R6) and the time difference flow rate is determined or calculated. 3. A method according to claim 1, characterized in that in a measuring process a) the physical quantity (R1, R of the measuring body is measured) 2 at least twice during the temperature adaptation of the measuring body to d! V) CJ! The temperature of the media flow, the time difference between the measurements being known or in a plurality of measuring processes equal, b) the quantity (RO) of the measuring body before or after the measurements in step a) being measured when the measuring body has substantially the same temperature as the media flow, and that c ) on the basis of the quantity measured values (R R2) and the time RO '1' difference the flow rate is determined or calculated. 4. A method according to any preceding claim, characterized in that the physical quantity measured is electrical, eg resistance. 5. A method according to any one of the preceding claims, characterized in that a wire is used as the measuring body. 6. A method according to claim 5, characterized in that a Pt wire is selected as the wire. 7. A method according to claim 5 or 6, characterized in that the diameter of the wire is selected to be below 0.5 mm, preferably 0.01-0.2 mm. A flow rate measuring device, comprising a measuring body (4) for exposure to the medium to be measured, means for causing the temperature of the measuring body to deviate from the temperature of the media flow and then allowing the temperature of the measuring body to adapt to or to the temperature of the media flow so that the measuring body will be heated and cooled or, conversely, means for measuring flow rate indicators. values and. means to. on the basis of these values, determine or calculate the flow rate, characterized in that the measuring means is arranged to measure, in connection with heating and / or cooling of the measuring body (4), a physical quantity of the measuring body which changes with temperature in order to obtain measurement values A466 320 18 and time data sufficient to give an unambiguous description of the exponential course according to which the heat exchange between the measuring body and the medium flow takes place, and that the determining or calculating means is arranged to determine or calculate the flow rate on the basis of these measured values and time data. Device according to claim 8, characterized in that the measuring means is arranged to measure the physical quantity (R1, R2, R3 and R4, R5, respectively, times with its difference of time which is known or in a plurality of measuring processes equal during its heating and / or cooling and that R6) of the measuring body at least three determining or calculating means is arranged to determine or calculate the flow rate on the basis of the quantity measured values (R1, R2, R3 and R4, R5, R6, respectively) and the time difference. Device according to claim 8, characterized in that the measuring means is arranged to measure the physical quantity (R1, R2) of the measuring body at least twice during its temperature adaptation to the temperature of the medium flow with a time difference which is known or in a plurality of measuring processes. , that the measuring means is further arranged to measure the quantity (RO) of the measuring body when the measuring body has substantially the same temperature as the medium flow, and that the determining or calculating means is arranged to determine or calculate the flow rate on the basis of the quantity measured values (RO, R R2) and the time difference. 11. Device according to any one of claims 8-10, characterized in that the measuring means is arranged to measure an electrical quantity, such as resistance, of the measuring body. Device according to one of Claims 8 to 11, characterized in that the measuring body is a wire. Device according to claim 12, characterized in that the wire is of Pt. m Fri 466 820 19 Device according to claim 12 or 13, characterized in that the diameter of the trees is below 0.5 mm, preferably 0.01-0.2 mm. Device according to one of Claims 8 to 14, characterized in that the means for causing the temperature of the measuring body to deviate from the temperature of the media flow is arranged to heat the measuring body. 16. Device according to any one of claims 8-14, characterized in that the means for causing the temperature of the measuring body to deviate from the temperature of the medium flow is arranged to cool the measuring body. Device according to claim 15 or 16, characterized in that the measuring body comprises a hollow member, arranged at least partially in the medium flow, that the device comprises means for cooling or heating the hollow member, and that the measuring means is an IR meter with a IR sensors arranged to sense IR radiation from a portion of the inner surface of a wall of the hollow member. Device according to claim 17, characterized in that the IR sensor is arranged at. such a part of the hollow member which is intended to be located outside a wall of a media flow delimiting channel.