DE1023610B - Device for measuring the paramagnetic gas content of a gas mixture - Google Patents

Description

The invention relates to devices to measure the paramagnetic content of a gas mixture Gas », mainly of oxygen, to be measured in gas mixtures.

Numerous methods are known to measure the magnetic properties of paramagnetic gases, in particular of oxygen to be used in order to measure its proportion in a gas mixture. Under these Methods are also known in which the measurement of the paramagnetic gas content the measurement of the thermomagnetic conduction is based. We understand thermomagnetic conduction as the change in temperature that occurs in a body which is exposed to a gas stream containing a paramagnetic gas is, namely a stream whose. Movement due to the effect of an inhomogeneous magnetic field is exerted on this gas and whereby the magnetic susceptibility of that gas by a local Heating is made non-uniform.

It is also known similar electrical windings for generating local heating and to use as a resistance thermometer, the temperature of which changes due to the movement of the gas flow that is exposed to the inhomogeneous magnetic field and at least one, paramagnetic Contains component.

In order for this method to achieve satisfactory results, all creeping influences must be suppressed that could change the measurement result, in particular the influence that other types of factors, how the effect of the inhomogeneous magnetic field on the movement of the gas mixture can have that contains one or more paramagnetic components.

Among those foreign influences is in the first place highlight the usual heat conduction (chimney effect), which is the thermomagnetic heat conduction superimposed when the gas flow, the thermal effect of which is to be measured, passed over a guide that is inclined to a horizontal plane. For this reason it was previously considered to be difficult, if not impossible, to use devices that use this measurement method, if so the applications were not stationary.

The invention is mainly based on the use of a magnet that generates a magnetic field generated, the inhomogeneous part of which the! homogeneous Part of the field surrounds, and which acts in such a way that the lines of the gas to be examined are guided in such a way are that it is first introduced into the homogeneous part of the magnetic field.

Then the mixture, its magnetic susceptibility by local heating in the magneti device to measure

the paramagnetic gas content

a gas mixture

Applicant:
Office National d'Etudes & de Recherches

Aeronautiques ONERA,
Chatilon-sous-Bagneux, Seine (France)

Representative: Dr.-Ing. R. Meldau, patent attorney,
Harsewinkel (Westphalia)

Claimed priority:
France 21 February 1955

Karl Luft, Massy, Seine (France),
has been named as the inventor

see field is changed, divided into at least two gas flows ¹ , which move in opposite directions from the inside of the homogeneous part of the magnetic field to the outside into the non-homogeneous zone of the magnetic field and thereby on. at least two electrical wires, which serve as resistance thermometers, stroke along, these electrical wires expediently simultaneously serving to generate the local heating that changes the susceptibility, with the special feature that the electrical wires are arranged along the gas streams flowing in the opposite direction, that one of these wires cooperates with those parts of each of the two gas flows which are in the inner zone of the magnetic. Field, while the other wire cooperates with those parts of each of the two gas flows which are in the outer zone of the magnetic field, so that the oppositely directed, from the field. gas streams to flow to the outside of the field cause a difference in the mean temperatures of the two wires, while a thermal convection that enters the field from outside and the latter is fully

709 877/240

constantly traversing gas stream no significant difference in the mean temperatures of the two Causes wires.

Apart from this basic device, the invention consists in some other devices, which are preferred be used together with the basic device; however, if necessary, they could can also be used independently. They are explained in detail below.

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and preferably selectable means regardless of the effect of the inhomogeneous magnetic field on the to be measured. Are gas flow. Their effect on the movement of the gas flow is either opposite to the effect of the inhomogeneous magnetic field or in the same direction as it.

In particular, the invention is directed to a device from, which mainly applies to arrangements and d d Sffhl

The air gap between the two poles 1 and 2 forms a transverse breakthrough, which is diametrically connecting opposite parts of the annular chamber. The breakthrough comes from the Gas flow set in motion by the inhomogeneous area of the magnetic field, go through before the gas flow a local change in the magnetic susceptibility of the gas mixture is subjected. To achieve this

It is mainly a matter of a second anio-local change in the magnetic susceptibility Order, consisting of means whose predetermined of the gas mixture is arranged in the air gap alek-

bi-tric wires that cause local heating of the

Cause gas and at the same time serve as a resistance thermometer.

The device described above has the advantage of making measurements: essentially of, the thermal conductivity to make the gas mixture independent. This allows the device to be used under

g, p g others in those cases where the to be analyzed

is used, which serve to the oxygen content 20 gas mixture contains hydrogen.

to measure a gas mixture. The invention includes the device described above

furthermore, there is no detrimental influence in this application which is suitable for this purpose Arrangement. exercise mixed convection on the measurement result

As new technical devices for the solution of can, if the device is installed at an angle, The task set in it is specially adapted to this last-mentioned 'harmful influence Individual parts and arrangement groups that can be completely switched off are fed into the gas mixture

the air gap through one or more channels 4, the open into the homogeneous zone of the magnetic field. The channels 4 advantageously open into the In the middle of the homogeneous zone. These channels are expediently drawn through the poles in such a way that their Axes coincide with those of the poles. You stand with the inside of the annular chamber that surrounds the poles, via one or more radially extending lines 5 in connection.

The electrical wires, which are arranged between the poles and serve as resistance thermometers, are expediently used at the same time as elements for local heating. According to the Fig. 4 contains circuits of the windings of the overall 40 basic embodiment of the invention werrätes of FIG. 1 in the manner of a Wheatstone α the at least two wires and b provided,

which one, b, is arranged on the inner part of the air gap on both sides of the confluence of the channel or channels 4 into the air gap, while

Fig. 6 shows schematically the Wheatstone 45 whose other, a, is in the outer part of the air gap bridge of winding circuits, as it is on both sides of the wire b ,
Execution of the invention according to FIG. 4 or also according to If the gas mixture to be tested has a para-

Fig. 5 is applicable. contains magnetic component, arises under the

According to the invention, and in particular according to the influence of the local heating which is carried out by the application and execution of its various wires α and b , a circulation of which parts it seems to be advantageous, a forward movement of the gas indicated by the arrows in Fig. 1 direction for measuring the content of a gas mixture is indicated. Part of the gas that is located in the paramagnetic gas, in particular an Sauer ring-shaped chamber, flows from the right and material, to be interpreted as follows or in a similar manner. left in the radially extending lines 5, which in

To create the device, each pole is arranged in each case, and in this way two frustoconical poles 1 and 2 are reached, channel 4, in which the opposite polarity coming from the right and left, between which a gas unites. After this gas the channel 4 air gap remains. The poles are parts of one that has flowed through it, it enters the center of the homogeneous magnet, which creates an intense magnetic field- part of the magnetic field where it can be created anew. This field is divided between, forehead 60 into two streams, while b the air gap in opposed surfaces la, 2a of the poles 1 and 2, homogeneous and passed through intermediate reverse direction, and the Inschen the tapered boundary surfaces 1 partners according to the outer parts. This movement is inhomogeneous and 2b. The inhomogeneous field surrounds the rests on the weakening of the outer inhomogeneous centrally located homogeneous. magnetic field and the local change of the

The frustoconical poles 1 and 2 form with 65 magnetic susceptibility of the gas, which is caused by the a cylinder 3 an annular chamber which the local heating is achieved. The gas is in Pole surrounds. The poles are to be analyzed from the transverse direction through the air gap to the outer one renden gas mixture flows through, which is then driven again to divide in order to re-enter the ring-shaped flows into the chamber and it does not enter through the chamber. The circulation described is provided lines leaves. "70 the more intense," the greater the content of paira-

g gpp form the respective overall device.

The invention is based on a few exemplary embodiments explained, which only contain examples of the essentially new type of training.

Fig. 1 shows in a schematic section the embodiment of the invention;

Fig. 2 shows in a corresponding representation type windings that are simultaneously used for local heating and serve as resistance thermometers;

Fig. 3 shows a partial section on a reduced scale an embodiment corresponding to that shown in Fig. 1, but with additional means that act on the gas flow;

Bridge;

Fig. 5 shows circuits according to the embodiment rm of Fig. 2;

magnetic gas is in the gas mixture. This movement of the gas mixture causes at the same time a difference in the mean temperatures of the wires a and b . If the gas movement does not take place, these wires have the same mean temperatures. Under the effect of this movement of the gas mixture, the mean temperature of wire b becomes lower than that of wire a. This temperature difference is a function of the intensity of the

When arranging the wires, which at the same time form resistance thermometers and the means for local heating, it is advantageous to fasten them in the air gap in the manner shown in FIGS. 1 and 2. According to these figures, the collars 6 are made of a non-magnetic material and are attached to the sides of the poles 1 and 2. These collars support Isoiierplatten 7, which with one boundary surface against the end faces, Xa and 2 a

Movement of the two gas streams, which in the transverse direction hegen the poles and with the other the wires a, b

flow through the air gap and run from its center in the opposite direction. Hence the Temperature difference continues to be a function of the paramagnetic content of these flows Gas.

If, as a result of an inclination of the air gap with respect to the horizontal, the gas is under the action thermal convection (chimney effect) into the air gap from one of the outermost points, e.g. B.

and c, d record. The plates, 7 point. Holes 8, which are in the extension of the channel 4. They leave a certain space 9 between them for the gas to flow through, which is moved by the thermal-magnetic effect. These gas streams are in direct contact with wires a, b and c, d.

FIG. 4 shows the circuit of the four wires α, b, c and d, which are arranged according to FIG. 1, in one

from the right side, flows back and represents the air gap 20 Wheatstone Bridge. Each wire is in

completely flowed through and at the outermost two wire sections a _v a _% ~ b _v &., -C ₁ , C ₂ and Ii ₁ , d _o

opposite side leaves again, one calls divided. Wheatstone slides indicator I

such gas movement does not change the middle bridge between the two conductors of which the

Temperatures of the wires α and b . The Tem- a the part a _{2 of} the wire α with the part b _{t of} the temperature change that such a gas movement on 25 wire b and the other the part c, the wire c

one side of this wire a, namely on the outer part d _{1 of} the wire d connects,

The first right side of the air gap would result in Fig. 5 discloses the analog circuit diagram of the

by changing the temperature of the part of the wires which form a spiral, as shown in FIG

Wire, which is provided on the extreme opposite. One of the spirals points to the side where the air gap is located, canceled. One ahn, - 30 wires α and b and the other the wires c and d

This phenomenon would appear on the wire b . Each of these spirals is divided into two parts, in the

and from this it follows that the gas movement is due to the outer, and in the inner, divided by the point

Inclination of the air gap no temperature difference (marked with e for the wire from and with / for the

between the mean temperatures, the wires α wire cd), on which the display panel ent I ange- and b causes. Such a flow would thus be closed.

without affecting the measurements that are based on In the two exemplary embodiments according to

a difference between the mentioned mean temperatures Fig. 1, 4 and 2, 5, it is advantageous to give each wire »

"are based. If a certain difference and d, which wires in Figs. 1, 4 from the

exists at the beginning of the measurement, the change would put two wire sections Ci ₁ , a ₂ and d _v d ₂ together.

this difference in mean temperatures, unused, the same electrical resistance as the

stay flowing. To give wires b and c.

When laying out the wires, it is advantageous to put wires b and c in FIGS. 1 and 4

not just a pair of wires running on one of the wire sections Jb ₁ , b. ₂ and c _v C ₂ together.

Side of the poles that form the air gap are, on, - From Figs. 4 and 5 it follows that the cons

zuoirdnen, but two pairs, namely a, b and c, d. 45 states α and b are connected in series. The cons

These wires are expediently placed on both sides of the stand (or a _v a. ₂ ), which is on the outer one. page

Air gap in the neighborhood of each pole. That of the air gap is connected to the positive pole

four wires of two pairs can be connected in this way and the resistor b (or b _v b ₉ ) that is connected to

which will be that it is the four branches of a Wheatstone - the inner side of the air gap with which

see bridge represent. The arrangement of the wires 50 negative pole. The reverse is true for those in series

"can be modified differently. According to FIG. 1, resistors d and c are switched on, among which the

each wire has two wire sections, which in resistance ei (or d _v d ₂ ), the one on the outer, side

the air gap on both sides of the in the middle of the air gap is connected to the negative pole

running channel4 are arranged. Such an off is while the resistors (or C ₁ , C ₂ ) are on

guidance can then be used in all cases. 55 is arranged on the inner side of the air gap, with

when the breakthrough for the gas that crosses the
Air gap runs and in plan a circular shape
has, is limited, e.g. B. by radially extending
Channels. The radial ones are! channels

connected to the positive pole. One helps oneself
of the Wheatstone Bridge circuit diagram, such as
it is shown in Fig. 6 and in dam the connections of the four resistors a, b, c and d are shown

according to one or more diameters that are 60. This circuit results in a for the instrument

correspond to the air gap. If but
the gas after its entry into the central part
of the air gap can flow in any radial direction, it is advisable to use a device

very great sensitivity. The gas flows which
flow through the air gap in the transverse direction,
go from the center in "opposite direction
and cause the internal resistances b

as shown in Fig '. 2 is shown. Each of the wires 65 and c is relatively cold, while the outer one forms a spiral that surrounds the channel 9. The two resistors α and d get relatively hot. Wires α and b can be formed in a single spiral. Thus, it follows from the scheme of FIG. 6, which are formed in two wire sections through the
Tap point is shared at which the measuring instrument

the Wheatstone Bridge is attached.

of the above-described relationships among the two
electrical wires connected to the same pole

who are and from whom one wire is always

relatively cold and the other is relatively warm, a particularly large voltage difference between the points e and f, between which the instrument I is switched on.

Another embodiment of the invention is as follows:

Additional funding will continue to be provided, which is independent of those making a move of the gas mixture through the. thermomagnetic effect cause the mixture in a beforehand certain type, and advantageously controllable type. Either they lift the movement caused by the thermomagnetic effect, or they weaken it. These additional means, in that they counteract the thermomagnetic effect, allow the Device with a zero point, which is taken from the measuring scale, to let work or this device to let it act according to the zero point method. These additional funds are beneficial as well arranged that they at the inner part of the poles where the magnetic field is practically zero, a Cause a pressure difference or a gas flow. This flow serves to either the thermomagnetic Flow to reach zero, suppress or for the beginning of each Measurement to avoid the thermomagnetic flow (zero point method).

These additional means can consist in a heated tube 10 (Fig. 3) which has a thermal convection flow causes which is opposite to the thermomagnetic convection flow. To change the effect of these additional agents, it is enough to heat the tube change.

It is admitted that the effect of these last indicated means does not depend on the inclination of the device is independent. The use of the additional funds reduces the advantage of the basic ones Device according to the invention. This advantage consists in the independence of the measurement on the inclination of the device.

The object of the invention is in no way limited to the indicated application and embodiment of the various parts, which are particularly considered were limited. Rather, it also includes their modifications.

Claims (9)

Claims ·. 1. Device for measuring the content of a gas mixture of paramagnetic gas, in particular Oxygen, wherein the mixture to be examined in the homogeneous part of one of; a magnet generated magnetic field is introduced and then the mixture, its magnetic Susceptibility is changed by local heating in the magnetic field, in, at least two gas streams split in opposite directions from the interior of the homogeneous Part of the magnetic field out to the outside in. The non-homogeneous zone of the magnetic Move the field while connecting at least two electrical wires that act as resistance thermometers serve, brush along, these electrical wires expediently at the same time for generating the susceptibility serving changing local heating, characterized in that the electrical wires are arranged along the gas streams flowing in the opposite direction that one of these wires cooperate with those parts of each of the two gas streams that are in find the inner zone of the magnetic field, while the other wire cooperates with those parts of each of the two gas streams, which are in the outer zone of the magnetic field, so that the opposite directed gas streams flowing from the inside of the field to the outside of the field Causing difference in the mean temperatures of the two wires while one is through thermal convection caused by entering the field from outside and the latter completely gas stream traversing no significant difference in mean temperatures of the two wires. 2. Device according to claim 1, characterized in that that the oppositely directed gas flows and the wires connecting them Stroke gas streams along, lie in horizontal planes. 3. Device according to claims 1 and 2, wherein the magnetic field between two frustoconical magnetic poles of opposite polarity is formed inside a chamber filled with the gas to be examined is arranged, characterized in that that at least one of these poles, expediently both poles, have an axial bore (4), one end of which is in the middle of the magnetic field formed in the air gap lies, while its opposite end by one or more substantially radially directed lines (5) is in communication with the gas chamber surrounding the magnetic poles. 4. Device according to claims 1 to 3, characterized in that in one of the walls, expediently, however, in both walls of the one formed between the magnetic poles Air gap on both sides of the mouths of the gas supply channels (4) radially behind one another two wire sections lie, the two inner wire sections the one of the two Resistance thermometer wires and the two outer wire sections the other resistance thermometer wire form. 5. Apparatus according to claim 4, characterized in that the wire sections substantially are straight and extend radially. 6. The device according to claim 4, characterized in that the wire sections are formed by wire spirals, the inner turns forming the one and the outer turns forming the other wire, these two wires ^{can be formed by a single 1} , continuous spiral whose division is formed by the tapping points of a Wheatstone bridge. 7. Device according to one of the preceding claims, characterized in that in the Arrangement of the wire sections on both sides of the air gap and when these wire sections are switched in the form of a Wheatstone bridge that lies on one side of the air gap Wire sections are connected to the network in such a way that the to the inner zone of the magnetic field adjacent wire sections connected to one pole, for example the negative pole of the network are, while the wire sections adjoining the outer zone of the magnetic field to the opposite, pole of the network, for example the positive pole are switched on, while the circuit of the wire sections on the other side of the air gap is connected The opposite is true of the positive and negative poles of the network. 8. The device according to claim 1, characterized by additional, of the magnetic Field independent means that the gas flow caused by the magnetic field promote or inhibit. 9. Apparatus according to claim 8, characterized by a heated section (10) in the line supplying the gas to be examined to the air gap, the heating of this Section is expediently adjustable. 1 sheet of drawings