DE1260802B - Transmitter - Google Patents

Description

Measuring transducer The invention relates to a measuring transducer, consisting from a mechanical probe body and an electrical transducer, the at least two alternating current resistors, which can be changed by the probe body and switched into a measuring circuit contains, which can be changed by the probe body and influencing the resistance value Air gaps are assigned, each separating a pair of poles, one of which is on the pole with the movable probe body connected to the movable pole carrier and its other Pole sits on the stationary pole carrier of the transmitter, with a Movement of the probe body of the pole spacing of a pole pair in opposite directions to the pole spacing of another pole pair changes.

For the electrical measurement of mechanical measurands, such as forces, Pressure, expansion, changes in length, etc., transducers are used that consist of one mechanical probe body and an electrical transmitter. Small movements of the mechanical probe in the circuit of the electrical transducer corresponding electrical changes in state. The known transducers are based generally on an inductive or capacitive basis. Your sensitivity is ever very different depending on the structure. The previously known highly sensitive transducers deliver unambiguous measured values only with a small and limited measuring path. You require therefore switches that activate the measuring instrument when the permissible measuring range is exceeded switch off.

The known inductive transducers often contain two pot core coils, between which a plate-shaped one connected to the mechanical probe body Armature is movably arranged. The sensitivity of this system depends on the Size of the air gap between the armature and the pot coil. The gap is to Regulation of the sensitivity adjustable, which, however, is a considerable constructive one Requires effort. There is also a major disadvantage of this known design in that the anchor when the permissible gap path is exceeded on one of the two Pot core coils strikes, which can lead to considerable damage.

Other known measuring transducers also have this last-mentioned disadvantage with a capacitive transducer, with a capacitor plate between two fixed capacitor plates is movably arranged.

A so-called "free lift" with the mechanical probe To create connected movable element, one also has inductive Transmitters developed with an iron core inside two in a row arranged air coils is moved. The iron core is much shorter than the total length of the coil assembly. As a result, he forms with each other facing ends of the two coils two pairs of inner poles. This arrangement of the coil core now allows an unimpeded displacement of the iron core in the direction of the Coil axis.

However, a major disadvantage of such a design is the relatively low sensitivity of the feeler and the ambiguity the measured value, since the characteristic curve reverses when a certain distance is exceeded and runs through zero again.

The invention is therefore based on the problem of avoiding these shortcomings of the known designs have a transducer of the type mentioned above To create a type that has a free lift, delivers unambiguous measured values and at least has a high sensitivity in part of its measuring range.

This object is achieved according to the invention in that the distance between the outer edges of two associated pole faces of one pole carrier approximately equal to the distance between the inner edges of the corresponding pole faces of the other pole carrier is.

As long as the pole faces of one pole carrier are approximately in the area of the pole faces of the other pole carrier (i.e. with smaller movements of the mechanical probe body around its rest position), there is a high sensitivity of the transmitter. The probe body of the transducer according to the invention can, however also perform movements of any size; he then only comes into one area decreased sensitivity. The transmitter according to the invention thus combines the Benefits a free stroke and a high sensitivity in the main measuring range.

Some embodiments of the invention are illustrated in the drawing. It shows F i g. 1 shows a longitudinal section through a first embodiment of the invention Converter, F i g. 2 shows a characteristic curve of the transducer according to FIG. 1, FIG. 3 one Longitudinal section through a second exemplary embodiment of the invention, FIG. 4 shows a cross section through a third embodiment, FIG. 5 to 8 cuts through further embodiments the invention.

The transmitter shown in Fig. 1 includes a mechanical one Probe body 1 and an electrical transducer which has two pole carriers 2 and 3. The outer pole carrier 3 is provided with two coils 4 and 5 and has on his Each end has a narrow pole 7 or 8 and a wide one in its central area Pole 6 open.

The poles 9 and 10 of the pole carrier 2 contain pole faces that together form two air gaps with the pole faces of the two narrow poles 7 and 8.

According to the invention, the distance between the outer edges 2a, 2b of the two pole faces of the pole carrier 2 approximately equal to the distance between the inner ones Edges 7 i, 8 i of the corresponding pole faces 7, 8 of the other pole carrier 3.

The transmitter is in the neutral position shown thus the mentioned edges 2a and 7i or 2b and 8i of the two pole carriers exactly opposite. If the probe body 1 moves up or down, the pole spacing changes of one pair of poles (for example, poles 7 and 10) opposite to the pole spacing of the other pair of poles (in the case under consideration, poles 8 and 9). This will the alternating current resistance of the two coils 4 connected in a measuring circuit and 5 changed in the opposite sense, resulting in the movement of the probe body 1 corresponding electrical signal results.

F i g. 2 shows the characteristic of the transducer according to FIG. 1. It illustrates the dependence of the amplitude of the electrical measured value signal as a function of the movement of the probe body 1 in the direction of the axis x-y. You can see that with movements of the probe body around the neutral position a strict proportionality and a high Sensitivity is present. Only with larger deflections from the neutral Middle position results in a disproportionate dependence of the measured value signal on the movement of the probe body and a reduced sensitivity.

The distance between the outer edges (e.g.

2 a, 2b) of two associated pole faces of one pole carrier (z. B. 2) should according to an expedient embodiment of the invention at most by so much of the distance between the inner edges (e.g. 7i, 8 i) of the corresponding Pole faces (e.g.

(7, 8) of the other pole carrier (e.g. 3) differ so that every change in the air gap when the probe body 1 moves as a measured variable change on the steep, straight line Part of the calibration curve of the transmitter (see Fig. 2).

In the embodiment according to Figure 3, an outer ring-shaped Sleeve 17 as a coil-less pole carrier around an inner one provided with coils 11, 12 ren Pole carrier arranged around, which consists of a core 13, a middle, wide pole 14 and two outer, narrow poles 15 and 16. The two pole carriers are displaceable in the axial direction relative to one another, with either the inner coil occupied Fixed pole support and the sleeve-shaped outer pole support is movable, or vice versa.

In this embodiment, too, the distance between the outer edges 17 a, 17 b of two associated pole faces of one pole carrier 17 approximately equal to the distance between the inner edges 151, 161 of the corresponding Pole faces of the other pole carrier.

In the embodiment according to FIG. 4 is one pole carrier as a coil-free rotor armature 18 and the other pole carrier as one with coils 19, 20 occupied stator 21 formed. In this embodiment, too, is the same as in the previously explained variants of the distance between the outer edges 18 a, 18 b of two associated pole faces of one pole carrier 18 approximately equal to the distance between the inner edges21el, 21b of the corresponding pole. surfaces of the other Pole carrier 21.

The embodiment according to FIG. 5 corresponds in its fundamental Structure of the embodiment according to FIG. 1. The one connected to the movable probe body 1 However, in addition to the central, wide pole 29, the pole carrier contains two related, narrow outer pole pairs 30, 31 and 32, 33. The following applies to each of these two pole pairs However, that the distance between the outer edges (z. B. 32a, 33 a) of two related Pole faces of the movable pole carrier approximately equal to the distance between the inner ones Edges 7i, 8i of the corresponding pole faces of the fixed pole carrier 3 is.

The calibration curve of a transmitter according to FIG. 5 points as a result two spaced areas of high sensitivity on (and in each case in the zones in which one of the two pole pairs [z. B. the pole pair 32, 33] with its edges [e.g. B. 32a, 33a] in the area of the corresponding counterparties 7i, 8i of the fixed poles are located).

In the one in FIGS. 6 and 7 in the form of a longitudinal and cross-section Another embodiment shown is one pole carrier with the middle one Pole 36 and the outer poles 37, 38, 39 and 40 formed in a cross shape and in two mutually perpendicular directions with respect to the fixed pole carrier with the Poles 34 and 35 can be moved.

As in the exemplary embodiments explained above, the Distance between the outer edges (z. B. 34a, 34b) of two related Pole faces of a pole carrier (z. B. 34) approximately equal to the distance between the inner edges (e.g.

38a, 40b) of the corresponding pole faces (e.g. 38, 40) of the other Pole carrier.

While the previous embodiments inductive transducers included, Fig.8 shows a variant with a capacitive transducer, both the inner pole carriers 41 as well as the two outer pole carriers 42 and 43 have pronounced Pole. Here, too, the distance between the outer edges (e.g. 42a, 43a) is two associated pole faces of the outer pole carriers 42, 43 approximately equal to the distance between the inner edges (e.g. 41 a, 41 b) of the corresponding pole faces. of other, inner pole carrier 41.

With an axial relative movement between the inner pole carrier 41 and the outer pole carriers 42, 43 changes the capacitance of the cooperating Element capacitors formed by pole faces, and a characteristic curve is again obtained according to FIG. 2.

It can also be useful if the calibration curve of the transducer in addition to a range of linear division, at least one range with a logarithmic division Contains division. In this way, with the advantage of a high reading accuracy in the linear range the preference for a logarithmic division, connect very large measuring range.

In order to achieve a particularly high sensitivity, it is still used expedient if each pole pair has at least one blade-like pole.

Finally, within the scope of the invention, the poles can also be provided by thread flanks are formed.

Claims (13)

Claims: 1. Transmitter, consisting of a mechanical Probe body and an electrical transducer, the at least two through the probe body contains changeable alternating current resistances connected to a measuring circuit, those air gaps which can be changed by the probe body and which influence the resistance value are assigned, each separating a pair of poles, one of which is on the one with the movable pole Probe body connected movable pole carrier and its other pole on the fixed Pole carrier of the transducer is seated, with a movement of the probe body the pole spacing of a pole pair is opposite to the pole spacing of another pole pair changes, thereby g e k e n n -z ei c h ne t, that the distance between the outer Edges (z. B. 2a, 2b) of two associated pole faces of one pole carrier (e.g. 2) approximately equal to the distance between the inner edges (e.g. 7i, 8i) of the corresponding pole faces (7, 8) of the other pole carrier (z. B. 3). 2. Transmitter according to claim 1, characterized in that the distance between the outer edges (e.g. 2 a, 2b) of two pole faces that belong together of one pole carrier (e.g. 2) at most by as much as the distance between the inner ones Edges (e.g. 7i, 8i) of the corresponding pole faces (e.g. 7, 8) of the other pole carrier (e.g. 3) deviates, that every change in gap is a change in the measured variable on the steep, rectilinear part of a calibration curve of the transmitter. 3. Transmitter according to Claims 1 and 2, characterized in that that in an outer pole carrier (3) provided with coils (4, 5) reel-less, inner pole carrier (2) is arranged, the two pole carriers in the axial direction are displaceable relative to each other. 4. Transmitter according to Claims 1 and 2, characterized in that that an outer annular sleeve (17) as a coilless pole carrier around one with coils (11, 12) provided inner pole carrier (11 to 16) is arranged around, wherein the both pole carriers are displaceable relative to one another in the axial direction. 5. Transmitter according to one of claims 1 to 3, characterized in that that the one pole carrier (36 to 40) is cross-shaped and in two to each other perpendicular directions relative to the other fixed pole carrier (34, 35) is. 6. Transmitter according to one of the preceding claims, characterized in that that a pole carrier contains more than one pole face pair (z. B. 30, 31 and 32, 33). 7. Transmitter according to one of the preceding claims, characterized in that that the calibration curve has several areas of high sensitivity which are arranged at a distance from one another having. 8. Transmitter according to one of the preceding claims, characterized in that that the one pole carrier as a coil-free rotor armature (18) and the other pole carrier is designed as a stator (21) occupied by coils (19, 20). 9. Transmitter according to one of the preceding claims, characterized in that that its calibration curve has at least one range in addition to a range with linear graduation with logarithmic division. 10. Transmitter according to one of the preceding claims, characterized characterized in that each pole pair (z. B. 7, 10 or 8, 9) at least one blade-like Has pole. 11. Transmitter according to one of the preceding claims, characterized characterized in that the pole carrier (e.g. 3) occupied by coils (e.g. 4, 5) is on at least one narrow pole each at its ends (e.g. 7, 8) and at its middle one Area has a wide pole (e.g. 6). 12. Transmitter according to claim 1, characterized in that in one capacitive design, both pole carriers (41 and 42, 43) provided with pronounced poles are. 13. Transmitter according to claim 11, characterized in that the Poles are formed by thread flanks. Considered publications: German Patent Specifications No. 732 851, 889 986, 911 664, 908 921, 872 643.