DE2018548B2 - INDUCTIVELY WORKING ELECTROMECHANICAL TRANSMITTER - Google Patents

Description

The invention relates to an inductively operating electromechanical measuring transducer a cylindrical housing into which a hollow cylindrical spool is coaxially fitted, and with a magnetic core from a plurality of U-shaped, electrically insulated core pieces, of which each eic leg is arranged in and one leg outside of the coil, the free ends of the Legs of all core pieces on the same end of the coil forming the active end of the transducer lie.

In a known transmitter of this type (German patent specification 1 140 717) the core is made of practically adjoining sector-shaped core pieces composed. Since the highest frequency, with which a transmitter can be operated, due to the greatest thickness of its core pieces in the circumferential direction is determined, the eddy current losses in this bckannv ^ ii transmitter are pretty great. Accordingly, the highest frequency with which this transmitter can be operated is relatively low. Furthermore, it has an adverse effect. that the known core pieces as close as possible lie next to each other without coming into electrical contact with each other. The well-known transmitter thus has practically no spacers.

With rising temperatures there is thus the risk that the radially outward expanding Core pieces can touch the housing, which can result in an electrical short circuit.

which could cause the current to flow through several or all of the core pieces, resulting in significant eddy current losses leads. In the event of contact between the core pieces and the housing, forces can be exerted on the core pieces through the housing. the magnetic features of the core pieces can adversely affect.

It is the task of 1-rfindiing. a transmitter of the type explained at the outset so that this transducer works at considerably higher frequencies and also operated at considerably higher temperatures than the known plasticizer can be.

This object is achieved according to the invention in that the U-shaped core pieces are each integrally

kig consist of unlayered flat material bounded by parallel surfaces and are arranged at a distance from one another around the coil in such a way that said surfaces are radial

full, and that between the Uu Ik rc η legs liinuh bobbin I and a winding 2 according to

adjacent core pieces around the outside Fi g, Iu, with eight U-shaped core pieces according to fig

the coil niclunuignetic, electrically insulating F i g, I b are provided, Ks should be mentioned that more

Absiandluilter are arranged, the radial Ab- or less core pieces 4 depending on

Niussungen are larger than the radial dimensions 5 of the desired inductance., The transmitter

the outer leg of the core pieces and their should have, can be used. As in the

Dimensions in the circumferential direction of the coil shown in larger figures »each core piece 4 is radial to

are arranged as the dimensions of the core pieces in wrap-around 2, with the free ends of the

fangsridilung the coil. Legs of all void 4 are at the same end

Since the core pieces are consistently io of the winding 2.

Have thickness that is substantially less than the Fig. If is a perspective view of a Maximaldickc the known core gap in environmental spacer 6 illustrates, in the form of a Ringsekiangsrichtung, the transmitter can be constructed with considerable tors and borrowed from the same material higher Frequencies are operated, which is about like the coil body 1. Fig. Ig shows alas! 2.5 times the operating frequency of known measuring 15 such spacers 6, which make up on the outside of the converter. The arrangement shown in FIGS. 1c, 1d and 1e by the arrangement between the core pieces are provided in order to keep the core pieces 4 spaced apart, the dimensions of which are circumferentially relative to one another. As from the drawing ersichirrichtung the coil are larger than the dimensions borrowed, the spacers 6 protrude in the radial direction of the core pieces, the displacement current losses ao further outward air the core pieces 4, so that in considerably reduced. Since these spacers are installed in the case of FIG. 1 g anzwisr-hen the outer legs of the core pieces order in a housing the core pieces 4 do not protrude radially beyond the core pieces, will surely come into contact with the housing walls,
placed that the core pieces do not have their radial Die in F i g. 1 g arrangement shown will be able to touch the inner wall of the as means of a housing resistant to high temperatures with outwardly facing surfaces, even if they are in the case of binding agents, such as. B. expand a ceramic binding properties of the temperature radially outward. medium, cemented into a housing made of an electrical short circuit with the austenitic steel.
considerable eddy current losses associated therewith. From Fig. Id it can be seen, for example, that the is thus effectively eliminated. The consequence of this is that core pieces 4 do not touch each other, which means that this measuring transducer can be reduced with considerably higher displacement current losses and the arrangement temperatures than the known measuring transducer can be operated by an insulating layer on the core pieces. eg an oxidation layer is avoided. In addition to further developments of the invention, the arrangement has a central hole, the contradiction. 35 which facilitates the installation of the arrangement and for a better understanding of the invention, this is shown in the construction of a device shown in FIG. 2 is expediently illustrated by means of three exemplary embodiments with reference to the converter unit.
would take on the drawing explained in more detail. As shown in FIG. 2, the compound F i g. 1 a to 1 g each parts or assembly transducers two transducer units, which have been described in stages of a simple transducer according to the invention described with reference to FIGS. 2 with the reference numeral 7 F i g. 2 an axial section through a composite and 8 are provided. These units are located inside the transducer, in which two simple transducers of a cylindrical housing 9 made of austenitic according to FIGS Heat shield 10 is also a modified embodiment of a measuring transducer made of austenitic steel and at the other end mer unit and is closed by a screw cap 11.

4 shows a cross section along the line IV-IV. In the transmitter according to FIG.

the F i g. 3. converter unit 7 the active transmitter, while

Fig. la shows a hollow cylindrical coil 5 ° rend the Messiimfornieinheit 8 as a compensation

physical which is made of aluminum, sintered aluminum or a reference element

and / or silicon nitride is produced and with flange heat shield 10 closed end of the measuring

has provided end faces, with the active end on the fornif-s.

sen bobbin a single winding 2 from one The housing is designed with a one-piece

non-magnetic wire is applied, the high 55 th partition wall 12, which the two wall

Can withstand temperatures and a high oil purity 7 and 8 of each other (runs and as a buffer

Tcmpcraturcn resistant ceramic or glass insu- lators serves to ensure a transfer of a to the active one

has tion. The ends of the winding are exposed to pressure acting on 3 areas of the transducer

designated. from the active unit 7 to the reference unit 8

F i g. 1 b shows one of the nickel-iron ^6o prevent. Between the buffer 12 and the reference

the U-shaped core pieces 4, of which eight piece unit 8 is a reference plate 13 consisting of the

the same for the transmitter according to FIGS. 1 a to 1g. "Material as the object to be monitored

are provided. The core pieces have a thickness. (e.g. in the special application of the measuring

which is less than 0.25 mm in order to use a transducer to measure the change in position of a

to enable high carrier frequencies without the ^{turbine shaft 6} 5) the plate 13 from the Matc-

noticeable displacement current losses occur. rial from which the turbine shaft is made

The F i g. 1 c, Id and 1 e show a perspective view, a ceramic disk 14 with such a thickness,

see a view, a top view and a lower view of a work cycle, e.g. B. an air gap for the

To simulate measuring transducer unit 8, the essentially modified measuring transducer is merely circular

borrowed the change in position to be measured on the active rods, which are made much easier

ven area of the compound transducer, can be used as the spacers according to

and a metal disk 15 made of the same material Fig. If.

rial and the same dimensions as in 5 When operating the transmitter according to FIG. 2

Heat shield 10 arranged to avoid changes in the per- in a high pressure environment can affect the

meability of the heat shield 10 due to the Tempera area, d. H. on the heat shield 10 of the measuring

to compensate for temperature fluctuations. transducer applying pressure to a compression

A ceramic connecting ring 16 with core pieces 4 made of temperature lead in the longitudinal direction, which is a temperature-resistant steel wires existing anio change the transmitter properties for Consequences 17 is arranged within the housing 9. To prevent such an effect, net to establish a connection between the ends of the modified transmitter according to the Coil 2 in the transducer unit 7 and 8 herzu- Fig. 3 and 4 a star piece 21 made of non-magnetic points. In addition, there is a steel with mineral materials that is insulated against the high temperatures Cable 18 provided, which can be hermetically 15, the star piece 21 three flat is sealed in the end cap 11, the angled having rectangular legs which extend in the radial direction The locking ring 16 protrudes outward from a central axis between the transducer unit 8 and and the end cap 11 by means of a spiral spring 19, the legs being in planes that form the axis hold is what thermal expansions of the measuring include ι mc! against each other by 120 ° converter permitted. Ceramic tubes 20 lead the 20 are offset. In addition, a support rod 22 is made Ends of the winding of the unit 7 are provided by the one made of the same material from which the unit 8 to the connecting ring 16. Stand holder 6 exist. The star piece 21 is seated

When assembling the measuring transducer according to the finished measuring transducer on the innermost Fi s. 2, after all parts of the measuring transducer (with reference to the active end of the measuring circumference) are accommodated in the housing and after the end of the coil former 1 of the active measuring transducer, the end cap 11 is screwed on. Aluminum mer unit 7, whereby the legs of the star piece 21 powder into the still open active end of the measuring intermediate. the ends of the core pieces 4 lie, as shown in FIG. 4 by the converter through the center of the measuring converter. The support rod 22 is the unit 7. the buffer 12. the reference plate 13. until all the heat shields 10 and the other end are filled at cmem cavities, with the entire one end of the Stcrnstückcs 21 rests, the other means is constantly shaken to ensure that the end is supported on the partition 12, the no cavities remain free. The center of the measuring transducer unit 7, which is lumpy with the housing 9 of the measuring transducer, is then set with a superscript 35. The core pieces 4 of the bobbin 1, temperature binding agent and the heat shield 10, the star piece 21 and the support rod 22 are decided in such a way, with the end cap 11 measuring in place, that when the core pieces 4 are assembled by means of an electron welding under a high transducer, the core pieces 4 are not subjected to pressure is welded from vacuum. set s ^; nd, which is applied to the front surface of the measuring

The transmitter according to FIG. 2 can advantageously act 40 converter, this pressure by the

Support rod 22 and the star piece 21 are used as two branches of a bridge circuit

and then leads to a certain tempera- will, soft together -Vioo to 7u> o mm long sine

turkompensation, as long as both ^ measuring transducers as the core pieces 4. It is also preferable for the

7 and 8 are called a star piece 21 in the same temperature range, the compensation measuring transducer 8

are located. Because of the construction of the measuring transducer, 45 is provided around the two measuring transducer units

mers with high temperature resistant parts can be obtained as similar as possible, although the ·

this a continuous temperature in which is not necessary, since the reference unit 8 does not

Is subjected to pressure of the order of 600 ° C with temperature peaks. the on the voyage area

withstand up to 650 ° C. acts, as in the case of the transducer unit 8 de

It should be noted that a single transmitter 50 is the case. because the buffer wall 12 is the transducer

Unit, as shown in FIGS. la to Ig, in unit 7 protects. The star piece 21 is in the measurement

in the same way as two transducer units converter unit 8 fixed to the head of the bobbin

7 and 8 according to FIG. 2 can be encapsulated. cemented.

where the parts 7, 12, 13, 14, 15 of the measuring transducer are then closer to the shape of the connection

according to FIG. 2 can be omitted. 55 ringes 16 and the connections Γ attached to them

3 and 4 show a modified form in the modified embodiment of the measuring

a composite measuring transducer according to FIG. 2. wherein the transducer according to FIGS. 3 and 4 is closer. si

In these three figures the same reference numbers for ahn- it is noted that these parts are also modified:

borrowed parts are used. Because of the similarities. The basic cup shape of the connection

The two devices are related to the fact that the ring is retained, with the edge facing di

Writing of the measuring transducer according to FIG. 3 ends of the core pieces 4. as in the case of measuring transducers

and 4 only presses on the features of the transducer, according to FIG. 2, to the compensation unit

which differ from the relevant characteristics of the in their location. Own the connecting ring

Differentiate the transducer according to FIG. but in this embodiment four holes!

As can be seen from FIG. 4, there is a variation 65 (two of which are visible in FIG. 3), of which

runs of the transducer compared to that in Fig. 2 each has a connection in the form of a winding

«Ezei ° th transducers in the cross-sectional shape of spiral springs 25 made of non-magnetic material ar

the spacer 6, which receives in both units of the ordered spring, which so together

is pressed that their ends 26 engage in the hole of the connecting ring, the ends of the Spring are bent away from each other to set the spring 15 in the hole of the connecting ring, as this is shown in FIG. 3. The resilience of the springs 25 ensures that they are held in place in the Holes 24 of the connection ring 16. By inserting the lead of the wires of the two measuring transducers, d. H. of the active transmitter and the compensation transmitter, between the windings the connecting springs 25 a mechanical contact is obtained, which at high temperatures is not subject to deterioration or failure as is the case with welded or fcelöteten contacts of the transmitter according to FIG. 2 may be possible.

Finally, the measuring transducer according to FIGS. 3 and 4 differs from that according to FIG. 2 in the way in which the cable 18 insulated with mineral substances is attached to the measuring transducer. As shown in FIG. 3, the screwed-on end cap 11 has a hollow extension into which the cable 18 is inserted, an electron beam welding being carried out between the extension and the metal sleeve of the cable 18 at location 27. A sleeve 28 is then slipped over the cable and the end of the extension and electron welded onto the extension and welded to the cable at locations 29 and 30. Finally, an outer sleeve 31 is put on, which is welded to the end of the extension at 31 by means of electron welding. As a result of this configuration, the sealing of the cable on the measuring transducer is extremely reliable.

ίο If desired, the space within the End cap 11 can be filled with a temperature-resistant mineral wool before the end cap is opened the transmitter is attached. In addition, it is in the event that the items with appropriate Tolerances are made, no longer required, using the interior of the transmitter Fill in aluminum powder, although this can be done anyway.

The inductive transducers described can

can also be used in a high temperature environment. Because of the construction of the core of the transducer in the form of a number of spaced apart U-shaped flats Core pieces are reduced parallel displacement currents, which means the transmitter with higher Carrier frequencies can be operated.

For this purpose 2 sheets of drawings

109 587/177

Claims (8)

Patent claims: 1. Inductive electromechanical transducer with a cylindrical housing into which a hollow cylindrical coil is fitted coaxially, and with a magnetic core made of a plurality of U-shaped, electrically isolated core pieces, one leg in and one leg outside of the coil is, the free ends of the legs of all core pieces at the same end of the coil forming the active end of the transducer, characterized in that the U-shaped core pieces (4) each consist in one piece of unlayered flat material bounded by parallel surfaces and in Are arranged at a distance from one another around the coil (2) in such a way that said surfaces run radially and that between the outer legs of adjacent core pieces (4) around the outside of the coil (2) non-magnetic, electrically insulating spacers (6) are disordered, whose radial dimensions are larger than the radial dimensions of the outer legs of the core pieces (4) and the dimensions of which in the circumferential direction of the coil (2) are greater than the dimensions of the core pieces \ 4) in the circumferential direction of the coil (2). 2. M.3 converter according to claim 1 or 2, characterized by combining two essentially identical, coaxial with one another arranged Meßumfo mer (7, 8) in a common housing (9, 11) in which the a transducer (7) for detecting changes in an inductive coupling and the other transducers (8) to compensate for changes in temperature or other environmental conditions is provided. 3. Transmitter according to claim 2, characterized in that a reference plate (13) consists of the same material as the object to be monitored by the transducer between the two Mcßumwandlern (7, 8) is arranged. 4. Transmitter according to claim 3, characterized in that a spacer (14) consists of Ceramic between the reference plate (13) and the Kompcnsationsclement (8) is arranged to an air gap corresponding to the average working air gap of the active transducer (7) to simulate. 5. Transmitter according to one of claims 3 to 4, characterized in that a heat shield (10) \ before the active converter (7) and a Kompcnsiilionssdiild (15) made of the {!! oak material and the same dimensions in front of the KoiTipensiitionsclemenl (8 ) is arranged. 6. Transmitter according to one of claims 3 to S, characterized in that the housing (9, 11) has an integrally molded partition (12), on one side of which the active Transmitter (7) and on the other side of which the Kompensationselcment (8) is arranged. 7. Transmitter according to one of claims I to 6 for use under high ambient pressure, characterized in that the active end of the transducer (7) is closed by a non-magnetic membrane (10) and dulJ pressure-resistant support members (21, 22), which in Axial direction! Are longer than the core pieces (4), between the membrane (10) and that in the housing (9, 11) located partition (12) are provided. 8. Transmitter according to one of claims I to 7, characterized in that a connection block (IC) inside the housing (9, U) at the opposite end to the active end of the transmitter End is arranged and that connections (17) in the form of tightly wound coil springs (25) are provided, the ends (26) of which engage in holes (24) in the connection block (16).