DE1498351A1 - Electric measuring device for flow rates - Google Patents

Description

Electric Flow Rate Meter The invention relates to a flow rate measuring device. Measuring the flow rate of gases. The expression "Amount of flow" is used here to designate the per unit of time through the measuring device flowing gas stream of interest. used.

There have already been numerous designs of a flow rate measuring device suggested; the most important are the hot wire and hot grid arrangements. at i these anoridings the wire or the grid is electrically heated and the The cooling effect of the gas stream flowing over it is used as a measure of the gas flow rate measured. These two known arrangements have various disadvantages, for example the hot wire arrangement is necessarily delicate and also only very small signal changes (i.e. changes in resistance) for the measurement available; in addition, it is two-fold with a large temperature difference between the temperature of the gas and that of the hot-wire Klement to work with so far in connection with such hot wire elements used directly coupled In order to obtain sufficient sensitivity, amplification is a high degree of amplification and a very careful design of the amplifier to avoid the instabilities necessary. The orders normally resulting from these demands are only suitable for Laobr use. The hot grid arrangement, on the other hand, requires a thermal symmetry of high order of magnitude, which until now has only been achieved by using a large thermal mass with a consequent coarse time constant, for example in the order of magnitude of 90 seconds could be achieved.

It is an object of the present invention to provide a gas flow rate measuring device to create at which the above. the disadvantages mentioned are significantly reduced or be completely avoided0 The gas flow meter designed according to the invention is characterized by the following structure; One heated by means of electric current heating element exposed to the gas flow, an electrical bridge circuit which is formed from a number of elements, of which a first temperature-dependent element is arranged in relation to the heating element, that heat transfer is possible as well as due to deviations in the bridge circuit elements from a predetermined ratio responding control circuit, which aen, The current fed to the heating element is changed in such a way that the deviations is counteracted.

It is preferably provided that the first temperature-dependent element is in a first of the four bridge circuit branches and a second temperature-dependent Element lies in a second of the four branches and exposed to the gas flow should, so that the bridge elements do not strive when the gas temperature changes; are to be deviated from the aforementioned ratio determined by goal.

It is preferably provided that the first and second temperature-dependent Element is chosen such that they have essentially the same temperature characteristics own.

It is preferably provided that the first and second bridge branches are exposed branches of the bridge circuit.

According to a preferred embodiment it is provided that of the four bridge branches the mentioned first bridge branch still a third temperature-dependent Has element which is exposed to Gastromung and wilches with a such Tempeartur characteristic is chosen that the back elements strive even more are not of the aforementioned predetermined ratio due to changes in the Gas temperature deviate.

It is preferably provided that the first and third temperature-dependent Element connected in series in the first of the four bridge circuit branches are.

Preferably at least one of the temperature-dependent elements is of the kind that it reacts to changes in temperature by changing its effective electrical resistance responds.

The mentioned element can be a resistor or, for example, a thermistor - (i.e. a resistor whose resistance increases noticeably with temperature) be. Alternatively, said element can be a body building element, for example be a silicon element (e.g. "silicon chip"), Further advantages and details. of the invention emerge from the following description of exemplary embodiments on the basis of the drawing In the drawing: Pigur 1 shows a circuit diagram of a Gas flow rate meter according to the invention; Firgur 2 a more detailed circuit a changed form of training an eating device according to the Invention; Figures 3, 4 and 5 different types of arrangement for a device according to the invention; 6 to 11 are schematic circuit diagrams of further, modified ones Forms of embodiment of the device according to the invention.

The gas flow rate meter according to FIG. 1 has a sensor element 30 in the form of a resistance circuit 1. Three branches of the bridge circuit are each formed by a separate, corresponding thermistor 2, while the fourth branch of the bridge is formed by a series connection of thermistors 3, 2a An electrical element 4 is arranged opposite the thermistor in such a way that that heat transfer take place. can.

The thermistor 2a is expediently of the "type" more sensitive Pearl "is used, the amount of glass of which is reduced and the delicate pearl around it is reduced and wherein the heating element 4 is wound around the remaining bead Has wire.

The thermistors 2 and 3 are preferably also such or Construction with sensitive "pearl".

The sensing element 30 is arranged so that it is the Strönung of the Gas, the flow rate of which is to be measured, is exposed to all thermistors 2, 2a and 3 can be arranged within a tube 5 (FIGS. 3 to 5) so that it is exposed to the gas flow in the pipe, e.g. "ecL '" "' L'- £ .i £ e'rwe'ise 1-st Js-d0 '- L "7- f =: Qür'it1istrjl radially inward, on the central axis of the Tube 5 protruding, arranged in such a way that the sensitive ferrules of the thormistors lie on the central axis of the pipe; the Thermistroen are on one level and arranged at equal angular intervals around the @case of the tube nerum, as a result With this arrangement, all five Thermistroen are equally affected by changes beefinlust in the pipe.

Thorwistors 2 and 3 3 'are shielded, so asz the stranlung from the thermistor 2a and the heating element 4 not directly to the Tahermistroen 2 and 3 falls, in two opposite corner points of the bridge circuit 1 is, by eiLe Control unit 6 electrical power fed in, while the (of the white remaining opposite corner points of the bridge tapped) Meßdiagonalisgnalspannut in an amplifier of the same control unit 6 is amplified, un serve the heating element 4 to generate electricity to be supplied; the arrangement is so made that the heating element 4 supplied electric current in Achängigkeit of the Deviations of the eebidagonal signal -t a predetermined value, is changed in such a way that a-ie bridge circuit strives to be in a state of equilibrium to return, in which the Heßdigaonalsiganl on the mentioned, predetermined Value returns.

It was found that the heating element 4 The electrical current supplied is a measure of the amount of gas flow passing through the pipe 5 is, provided that the thermistor 2, 2a and 4 grows appropriately are, therefore, if the current is to eat by means of an indicating instrument 7, so Is this a measure of the flow rate of the gas.

In order to achieve the effect described in the previous paragraph, the four thermal strands 2 and 2a chosen so that they essentially coincide Have temperature characteristics, on the other hand, the choice of thermistor 3 takes place in the Way, he ate a different temperature curve, so that the bridge scarf tion, 1 imluer, can at least almost reach a state of equilibrium, in which the bridge circuit generates a weak measurement diagonal signal and the dem The electric current supplied to the electric heating element 4 has a value such that that the temperature of the heated thermistor 2a is the temperature of the thermistor 3 and z "" also includes that of thermistor 2 by a substantially constant amount exceeds. The arrangement is designed so that this equilibrium situation. and the essentially constant Temperature difference always exactly, or can be almost reached regardless of changes in the flow rate (innergakb euies given designation) of the gas and independent of changes in the Gas temperature (within a given range). to understand better how the Themistor 3 3 'is selected, consider first the bridge circuit 1 if the thermistor 3 is omitted and a constant gas flow rate.

Current än the joint Thermistroen flows past. If the. Heating element 4 supplied electric current would be zero, then the bridge circuit 1 would be balanced (i.e. it would produce a zero measurement diagonal) Because the thermistors 2 and 2a essentially coincide; this condition would last as long as as the gas temperature within a certain temperature range of the areas, in which the thermal strands 2 and 2a are adapted) would be changed. However, it is required the bridge circuit 1 at such a temperature of the thermistor 2a, which is essentially higher by a constant amount than ide temperature of thermistors 2; if now the temperature of the Thermistren 2 increases becomes, inan states that (due to the non-linear T temperature characteristics of the Thermisors) the change in the maintenance of the heating element 4 a substantially constant temperature difference is a non-linear function of the Temperature is: it is a job of the thermistor 3, the effect of this Non-linearity to compensate.

The thermistor 3 can be chosen, for example, in such a way that that after its use in the bridge circuit 1 an increase in temperature of thermistor 2a by about 400C is required to turn the bridge back into a to bring back some unbalanced state of balance in which that of the bridge coming measuring back digaonal signal an electric current in the heating element 4, which is sufficient to maintain the temperature difference of 40 ° C. Farther the thermistor 3 is chosen such that when the gas temperature changes (and thus the temperature of the thermistors 2 and 3) the bridge circuit still strives is to bleach in (or almost in) the above-mentioned state of equilibrium. is also possible to consider the thermistor 3 as a biasing element, which enables the bridge circuit 1 to achieve the above-mentioned equilibrium state, -in which (the bridge is slightly out of balance and) the heating element 4 continuously an electric current is supplied 0 When the voltage across the thermistors 2, 2a and 3 Passing gas flow increases, so the gas tries to move from the heating element 4 to dissipate a proportionally larger amount of heat, so that to maintain the aforementioned constant temperature difference of the electrical heating element supplied Current must be increased, the bridge circuit will then reach a new equilibrium state in which the Heßdiagonal signal is somewhat different from the previous one, but since the amplifier is the control unit 6 shows a relatively high gain, the new equilibrium state distinguishes itself little of the previous equilibrium f.

Even if the gas flow is Hull, that the heating element 4 is still with a temperature difference sufficient to maintain the above-mentioned temperature difference electric current can be fed. Thus, the gas flow rate becomes "zero" a positive deflection of the instrument 7 is displayed, a faulty deflection of the measuring instrument 7 therefore indicates a system.

The plant according to the invention has compared to the known ones nilaen, aur measurement of gastric flow following advantages; Ij The temperature-dependent The elements (the thermistors 2, 2a and 3) and the heating element 4 are proportionate robust; II) With suitably selected thermistors 2, 2a and 3, the eating of the Gas flow largely independent of changes (at least in the predetermined Ranges) the temperature and density of the gas be made; (III) the system responds relatively quickly and can, for example a thermal force constant on the order of 5 seconds or less. to have ; (IV) the system can be relatively easy to measure different areas the gas flow rate can be modified; (V) the amplifier of the control unit 6 needs only a relatively simple amplifier (for example an amplifier with Solid state components) with a relatively high reliability; (Vi) the simple display instrument also has a relatively high one Reliability; (VII) the sensing element 30 has such a shape that it only causes a relatively small pressure drop in the gas stream; (VIII) the positive one The deflection of the indicating instrument 7 when the gas flow is equal to zero is an indication that the facility is working properly; I The device works at considerably lower temperatures (of the heating element 4 and the heated Thermistor 2a) as conventional hot wire measuring devices for gas flow.

The sensor element 30 shown in Figure 2 controls with the element 3C of Figure 1 basically about; therefore, there are corresponding circuit elements provided with the selan reference mark.

In the above description of the sensor element according to ig, ur- 1 was said how the thermistors 2, 2a and 3 are chosen, namely such that drls Bridge circuit 1. Independent of changes (within a given area) the gas temperature in a state of equilibrium (in which a small measurement diagonal signal arises) seeks to remain.

The sensor element 30 shown in Figure 2 is more suitable due to the installation. Resistances in certain bridges changed in such a way that the one in the previous one Section mentioned equilibrium state with changes in the gas temperature can be maintained more precisely what the Vorrtichtung even more independent of Makes changes in gas temperature.

There is accordingly one resistor 8-parallel from two Therimestors 2 each switched, while the remaining thermistor 2, a resistor 9 connected in series is. The resistors 8 are chosen in such a way that the mentioned equilibrium state, if the guest temperature reaches a lower value, tries to persist, while the resistor 9 is chosen in such a way that the mentioned state of equilibrium, if the gas temperature reaches higher values, it also tries to persist ; the setting is carried out in every J2all with a gas flow equal to Wull, whereby the sensitivity of the device within the between the mentioned higher and lower temperature range regardless of the kneeling position Gas temperature is.

In other respects, the device according to FIG. 2 works in a similar manner like that according to Figure 1. The Weichaselstower suction of the control unit 6 is working 400 Hz and 115 volts and feeds a transformer 10. An output winding of the Transformer 10 sit dorart through a diode and willertands-Begernzungsnetzwek 13 connected to two opposite corner points of the bridge circuit 1, the the bridge circuit has a 1 volt real-wave voltage with ljll substantially more constant amplitude feeds. The measured diagonal signal voltage of the bridge circuit is from two remaining, overlapping: ends of the corner points of the bridge tapped and the Input of a modified, transistorized 1 1/2 gatt low frequency AC amplifier supplied. The amplifier is powered by a second output winding of the transformer 10 via a full-wave rectifier bridge 11, the output of which by a 9 volt Zener diode 12 is stabilized. The measured diagonal signal the bridge is reinforced by the amplifier and the resulting current from The output of the peripheral transformer 14 is supplied to the wheat element 4.

The current made available to the heating element 4 is indicated by a display instrument 7 (which has a fax output of 240 °) measured, the display instrument 7 is in series with one for the gloeich aligning and shaping of the messistrumant supplied Current serving diode 16 and parallel to a resistor 15 the resistor 15 is in series two between the output transformer 14 and the heating element 4. The Measuring instrument 7 is calibrated in Gasströmungsmgneen-Nertem in such a way that the ASusschlag des ofinstamentes 7 is a linear function of the gas flow rate.

Figures 3, 4 and 5 show different ways of how to the sensing element 30 can expose the gas flow. when the gas flow is proportionate is small, the filler element 30 (as described above) within a die whole gas flow leading pipe 5 are arranged (Figure 3).

With stronger gas flows, the Ronr 5 can be used as a parallel pipe to the main pipe 35 and over a perforated plate 36 so arranged will. the nru a beatinter part of the gas flow duron the fohr 5 flows. These arrangement is shown in FIG.

If the gas flow is in a large pipe 37 (Figure 5) with a smooth Flow distribution and high flow velocity of the gas takes place, uann can the pipe 5 is installed within the main gas flow as a dine bond in such a way that that only part of the total Geastrom flows through the pipe 5. This arrangement results in a crowded structure of only a few relatively small ones Pressure drop generated in the system.

In the arrangements according to Figures 1 and 2, as mentioned above, the Thermistro 3 can be regarded as a biasing element, which it is the back circuit 1 enables a state of equilibrium to be reached in which (the bridge is not calibrated and) the heating element 4 is supplied with a continuous electrical current will. In the arrangements of Figures 6 and 7, the thermistor 3 is omitted and its effect as a pretensioning element is changed from one in series to the measuring diagonal line the bridge circuit 1 lying Werhelstomquelle exercised, the sum of the two signals is applied to the input of the amplifier 38.

The arrangement can include an AC-powered transformer 39 (FIG 6), the starting point of which is in series with the measuring diagonal of the bridge circuit 1 or it may have one for summing the measurement digital signal and one Wechaelstromsi supplied from the outside, gnals arranged transformer 40 (FIG 7).

In the bridge circuits 1 of Figures 6 and 7 there are also two Thermistors 2 omitted. and replaced by resistors 42 and 43. Every of the bridge circuits strives to remain in an equilibrium axatand, in which the bridge circuit 1 is essentially balanced and that of the heating element 4 supplied continuous current a predetermined temperature difference between the Temperature of the thermistor 2a and that of the thermistor 2; the resistances 42 and 43 are chosen in such a way that they maintain this state of equilibrium allow, whereby the claims of the device against changes in gas temperature is made almost independent.

Figures 8, 9 and 10 include further possible modifications of the formwork Figures 1 and 2. The circuit shown in Figure 8 is similar to that of Figure 2, with the exception of the fact that two branches of the bridge circuit 1 only have two resistors 18 and 19, respectively, while two of the thermistors 2 are omitted. The resistance 18 and 19 are selected such that the bridge circuit 1 strives must remain in the state of equilibrium in which the bridge shell works is not completely balanced and the continuous current supplied to the heating element 4 is a predetermined temperature difference between the T temperatures of the thermistors 2a and 3 (or 2). The resistor 20 is chosen such that at Changes in the gas temperature (in a predetermined range) this equilibrium state is maintained, thereby reducing the response of the device to temperature changes of the gas is made independent in an even higher degree.

The circuit according to FIG. 9 is similar to the circuit according to FIG. 8, however, the resistor 20 is connected in parallel with the thermistor 3 Replaced resistor 21, which has the same task as the resistor 20 in Figure 8th.

In the. In the circuit according to FIG. 10, resistors 20 and 21 are omitted and another "pearl type" thermistor 22 is provided and the gas flow exposed in a similar way to the Themistor 2. When the gas temperature is changes and as a result, the bridge circuit 1 of Figure 10 is striving to be of a the preceding equilibrium state ', the thermistor 22 serves to the degree of amplification of the amplifying the measuring diagonal signal of the bridge circuit Amplifier and in this way the continuous current fed to the heating element 4 in this way to change that the bridge circuit endeavors in their previous To come back evenly; in this way the response of the device becomes The circuit is also made largely independent of changes in gas temperature according to FIG. 11 is generally similar to that according to FIG. 1, but with the thermistor 3 is omitted; furthermore, one of the thermistors 2 is through a resistor 46 he sets one and / of the remaining two thermistors 2 is a resistor 45 in parallel, the other one - a resistor 44 connected in series0 The arrangement is so taken that the bridge circuit 1 is in a not completely balanced state of equilibrium seeks to pause in which of the continuous current supplied to the heating element 4 a Predetermined temperature difference between the temperatures of the thermistors 2a and 2 maintains. The choice of resistor 46 is made in such a way that the Bridge circuit 1 this equilibrium state with a gas flow equal to zero and a mean gas temperature is reached, while the resistance 45 is chosen such that becomes that this equilibrium state (with a gas flow equal to zero) also is substantially maintained at lower gas temperatures; in the end the tiliderstand 44 is chosen in such a way that this equilibrium state Essentially (with a gas flow equal to zero) even at higher gas temperatures is maintained. In response to changes, the device becomes silent 'the gas temperature in the range between the above-mentioned higher and The power supply of the circuit is largely made independent of low temperatures According to FIG. 11, a 400 Hz alternating voltage of 115 volts is supplied.

This is rectified in a DC power supply 47 which is itself resulting direct current is used to supply the amplifier 38 and a 1 kHz oscillator 48 used. The bridge circuit 1 is fed by the output of the oscillator 48.

The measurement diagonal voltage of the bridge circuit 1 is via an input transformer 49 is fed to the amplifier 38, the alternating current output of which via an output transformer 50 is connected to a full-wave rectifier stage 51.

The DC output of the rectifier stage 51 feeds via the Display instrument 7 the heating element 4.

Although the temperature-dependent elements 2, 2a and 3 of the bridge circuits 1 as described above as thermistors, the invention is not limited on thermistors as temperature-dependent elements. Rather, it can be any suitable temperature-dependent elements are used: .these elements are preferred of such a kind, @@@ their real electrical resistance sioh zait them Temperature changed; it can, for example, be sensitive or solid-state components (Silicon components, for example, "Silisfum-Chipe").

Claims (1)

P a t e n t a n s p r ü c h e: Gamengenströmungsvorrihtung, g E k e n n n e i n e t by a gas flow heated by means of an electric current exposed heating element, an electrical bridge circuit made up of a number is formed by elements, of which a first temperature-dependent element such with respect to the heating element being arranged that heat transfer is possible, as well by one on deviations of the bridge circuit elements from a previously determined one Ratio responsive control pressure, which, the, the heating element supplied current in the quietly changed that the deviations are counteracted, 2nd device according to claim 1, characterized in that the first temperature-dependent Element in one. first of the four bridge circuit branches and a second temperature-dependent element is in a second of the four branches and the gas flow should be exposed, so that the bridge elements when the gas temperature changes are not endeavoring to deviate from the aforementioned predetermined relationship. 3. Apparatus according to claim 2, characterized in that g e k e n n z e i c h -n e t t that the first and second teiape temperature-dependent element is chosen such that essentially the same Have temperature characteristics. 4. Apparatus according to claim 2 or 3, characterized in that g e k e n n -z e i c h n e t that the first and second bridge branches are adjacent branches of the bridge circuit are. 5. Device according to one of claims 2 to 4, characterized g e -k e n n z e i n e t that of the four bridge branches the mentioned first bridge branch still has a third temperature-dependent element, which the gas flow is exposed and which is selected with such a temperature characteristic, that the bridge elements strive even more strongly, not from the predetermined one mentioned The ratio may vary as a result of changes in the gas temperature. 6. VorricXtung according to claim 5, characterized g e k e n n z e i c h -n e t that the first and third temperature dependent elements in the first of the four Bridge circuit branches are connected in series. 7. Vorrcihtungnach one of claims 2 to 6, characterized g e -k e n n s e i n e t that the two remaining branches of the four bridge circuit branches each 'have a resistance. 8. Device according to one of claims -2 bia 6, characterized g e'-k k e fl n z e i n e n e t t t that the remaining two branches the four bridges mentioned each other temperature-dependent Have elements that are intended to be exposed to the gas flow. 9. Apparatus according to claim 8, characterized in that g e k e n n z e i c h -n e t that the first, second and the two further temperature-dependent elements can be selected so that they have substantially similar temperature characteristics own. 10. Apparatus according to claim 8 or 9, characterized in that g e k e n nz e i c h n e t that each of the two further temperature-dependent elements in parallel with a separate, corresponding resistor. 11. Device according to one of claims 2 to 4, characterized g e -k e Note that the remaining two branches of the four bridge circuit branches each have an additional temperature-dependent element or resistor, which are intended to be exposed to the gas flow. 12. The device according to claim 11, characterized in that g e k e n n'z-e ic h -n e t that the bridge connection consists of a series connection of the first, second and of the additional temperature-dependent element and the resistance, namely in in this order. 13. The apparatus of claim 11 or 12, characterized in that g e k e n n -z e i c h n e t that the additional temperature-sensitive element is another Resistance is connected in parallel. 14. Device according to one of claims 6 to 10, characterized g e -k Note that the second temperature-sensitive element in the second Bridge circuit branch an auxiliary resistor is connected in series. 15. Device according to one of claims 6 to 10, characterized g e -k It is noted that the third temperature-sensitive element is another Auxiliary resistor is connected in parallel. 16. Device according to one of claims 6 to 10, g e k e n n -z e i c h n e t through a temperature-dependent auxiliary element, which gives the gas flow is exposed and to change the response of the control formwork as one Function of the gas temperature is used, and in this way the deviation of the bridge circuit elements of the aforementioned, predetermined ratio due to changes in gas temperature, to prevent addiction. 17. Device according to one of the preceding claims, characterized it is not possible that at least one of the first, second, third, watere, additional or auxiliary device dependent @lemente a changes in temperature due to changes in effective electrical resistance dur recoudnes element is. 18. Device according to claim 17, dadruch g e k e n n z e i c hn e t that the mentioned element is a fact. 19. Vorichtung Each Ansrpuche 18, thereby, - e k e n n z e i c h -17 C t that the @element mentioned is a master craftsman, 29, device according to claim there. in that the mentioned element is a sensiotr is. 21. Device according to claim 17, dadruch g e k e n n n z e i c hn e t that the mentioned element is a solid state element. 22./ The device according to claim 21, dadruch g e k e n n n z e i c hn e t that the mentioned element is a silicon element. 23. The device according to claim 22, characterized in that it is not e t that the mentioned element consists of silicon chips. 24. Device according to one of the preceding claims, characterized g e k. Note that the control circuit is a source of electrical power has to supply the @ back circuit and control devices that on the measuring diagonal of the Bridge circuit ansprecent to the stimulus element supplied electricity to verenern depending on this Hetdiagonalighals. 25. Device according to Asparuch 24, dadruch, k k e n n z e 1 c h -n e t that the star devices have an amplifier circuit. 26. Device according to one of the addresses 2 bus, 4, as well as the addresses 24 or 25 d @ e k e n n n e i c h e tthrough its other Alsatian Stronouelle for changing the diagonal signal of the bridge circuit around the, the heating element in the case of a pre-determined value of the supplied electrical current, then also accumulate, if the mentioned elements of the bridge circuit in the mentioned pre-determined Relationship. 27. Device according to one of the preceding claims, e k e In It is shown by pull-on devices, which are attached to the electro-electric heating element respond to the supplied electrical current and in this way the size of the gas mass flow znaigen.