DE3527442C2 - - Google Patents

Description

The invention relates to a coil, in particular an oscillator coil an inductive proximity switch.

DE-AS 13 02 191 is an inductive proximity switch known, with the coil, the approach magnetizable and can determine electrically conductive body. It exists the possibility of differentiating between ferromagnetic, conductive material of non-ferromagnetic, conductive material. The criterion used is the by the change in inductance of the coil-related frequency shift a resonant circuit.

In conventional inductive proximity switches, the criterion is caused by the approach of conductive material Damping the coil used. A distinction from ferromagnetic, conductive material and non-ferromagnetic, conductive material is not possible. If you bring a coil into the electromagnetic field a non-ferrogmatic, conductive material such as B. Al, Cu or brass etc., instead of a ferromagnetic, conductive material such as Fe, so it turns out qualitatively the same damping effect of the coil.

An analogous course was found for the quality Q of the electromagnetic coil. The quality Q of the coil is defined as follows:

Q = ω L _R / R _R ,
where ω is the angular frequency of the applied alternating current, L _{R is} the series inductance of the coil and R _{R is} the series equivalent resistance of the coil.

If you e.g. B. builds a transistor oscillator with such an electromagnetic coil, it is found that its current consumption or its vibration amplitude is in a first approximation proportional to the quality Q of the coil. This is done at a constant frequency.

Taking into account the aforementioned aspects the invention has for its object a coil and in particular an oscillator coil of a conventional inductive proximity holder to be interpreted in such a way that by means of the qualitative change in the set quality of the electromagnetic Coil a material selection, especially in With regard to ferromagnetic and non-ferromagnetic, electrically conductive material can be taken.

This object is achieved by the features of characterizing part of claim 1 solved.  

It was determined based on empirical studies that the output quality of the coil after pre-damping or the current of a transistor oscillator consumed in this phase, when introducing a ferromagnetic material decreased, i.e. decreased, while when a non-ferromagnetic material in the air clearance at close range an unexpected increase in the current consumption of the coil or improvement in the quality of the coil occurred.

The experimental investigations were carried out on an electromagnetic Coil found in a half-shell core was made of ferrite. With predamping the free end faces of the half-shell core, e.g. B. the center pin and / or the peripheral edge areas of the outer web the ring wall of the shell core, was made when approaching a non-ferromagnetic material such as B. aluminum, a strong increase in quality, which goes up to the damping layer remained qualitatively the same.  

However, the latter phenomenon did not occur when the Predamping was omitted.

Depending on the setting of the coil quality after the stationary Predamping, you can now depend on the vertical distance to the front of the coil or to the coil in general, another Damping the coil when introducing a ferromagnetic Material and a damping of the coil when introducing a non-ferromagnetic material, e.g. B. Al or Cu. This phenomenon, which has not yet been clarified in detail, allows Proximity initiators or oscillator coils to be interpreted so that a selection of the material brought into close range or material can be hit.

This makes it z. B. possible with machine tools, whether a non-ferromagnetic to be processed Workpiece already placed in the machining area has been. This failed or was only at a very high level Effort to determine, because the iron material of the machine tools themselves led to falsifications of the measurements.

An oscillator coil constructed according to the invention therefore opens in terms of safety, a new quality of reliability. For example, now with greater reliability the closing or opening of elevator doors is detected inductively if nonferromagnetic as approximate materials Materials are used. It is possible with this Security initiators to be interpreted so that only one address specific, specific material.

The phenomenon of material selection shown above was made especially for one consisting of a ferrite Shell core half determined. The phenomenon of the opposite Damping behavior can also affect others Coil shapes are transferred. Predamping can suitably depending on the application and degree of damping only over a partial surface area of the coil core be performed. For example, the same thing was achieved Result when applying a thin layer of material on the end face of a central pin of a half shell or by applying a reverse axial section L-shaped covering on the peripheral edge area the ring wall of a shell core half. Predamping can, depending on the degree of coverage of the end faces Half of the shell or the covering thickness and the material can be set.

The approach of the material to be detected is approximately vertical to the outlet surfaces of the coil for the magnetic field lines can depend on the output sensitivity the coil and the corresponding pre-attenuation can be set. Preferably thin Materials used that are roughly the diameter of the Have half of the shell core. However, the effect is too with smaller sized materials and with different Entry angles to the end face of the core noticeable.

The invention is described below with the aid of schematic drawings explained in more detail. Show it:

Fig. 1 shows a qualitative diagram of the course of the coil quality factor as a function of distance from the coil end face, taking into account two different materials;

FIG. 2 shows a diagram, comparable to that of FIG. 1, with different settings of the output quality of the coil; and

Fig. 3 is a schematic axial section through a coil with a half-shell core, taking into account applied pads for pre-damping.

In the example according to FIG. 1, the qualitative course of the quality Q of an electromagnetic coil is shown as a function of the distance x of a material or a material vane introduced into the electromagnetic field. The distance x = 0 stands for the end face of a half-shell core, which form the exit or entry faces of the magnetic field lines. In the example according to FIG. 1, the coil is pre-damped so that an output quality Q _{1 is} present at a distance x ₂ .

If a material flag made of Fe or a corresponding alloy is brought closer to the coil, a gradual decrease in the quality Q of the coil can be observed. Is used as a parameter e.g. B. the current consumed by a transistor oscillator operating with this coil is evaluated, this decreases z. B. from 0.5 mA to 0.4 mA up to the range of the distance x ₁ .

In the example, location x ₁ marks approximately the thickness of the material covering that is applied to parts of the end face of the core used for pre-damping. On the other hand, the distance x ₁ can also correspond to the wall thickness of a protective housing surrounding the coil. In a device in which the pre-damped coil is arranged in a surrounding protective housing, the material flag can then only be approached up to a distance x ₁ .

If an aluminum material flag is used, contrary to expectations, from a certain point x _{2, there is} a considerable improvement in the quality Q with an almost linear increase to a maximum value. This maximum value can be kept almost constant over a larger distance from the coil. It was found experimentally that this maximum value of the quality only drops sharply in the area of the pre-damping coating.

Similar qualitative courses as for an aluminum material flag were used for Cu, brass and other, non-ferromagnetic Materials found. Also for VA steel could compare a pronounced maximum with a normal material flag made of iron be determined, however, before the pre-damping coating already dropped.

In particular with regard to the selection of ferromagnetic and non-ferromagnetic materials, a pre-damping of the core of the coil was carried out in such a way that an output quality Q was achieved, which roughly represents an average between maximum damping with Fe and maximum quality with non-ferromagnetic material. This setting is shown diagrammatically in FIG. 2. With this setting of the output quality Q , it is now possible to have both a larger quality difference when a ferromagnetic material approaches smaller values of quality, and a sufficient change in quality to larger values when z. B. an Al flag.

Depending on the initial position of the pre-damped quality of the coil it therefore appears possible next to one shown in the diagram Selection between Fe and Al also other materials, e.g. B. special Fe alloys or other non-ferromagnetic Materials, selectively by their corresponding curves the quality of the coil.

Also in the example according to FIG. 2, an almost constant value for the quality is achieved in the vicinity of the coil when an Al flag is approached, while an Fe flag shows an almost continuous decrease or an increase in damping to saturation. The maximum of the quality drops in the area of the covering applied for the pre-damping or in the area of the point x ₁ to a maximum damping, similar to Fe.

Fig. 3 shows an axial section through a special embodiment of an electro-magnetic coil. The core is constructed as a half-shell core made of a ferrite material. As such a half-shell core z. B. a core half made of SIFERRIT® material N 22 can be used.

The shell core half made of ferrite shown in axial section has an E-shape and is rotationally symmetrical to the central axis. Accordingly, the electromagnetic coil 1 has a half-shell core 2 with a central pin 3 and outer webs 4 and 5 of the ring wall of the shell core 2 . In the intermediate area between the center pin 3 and the outer webs, the actual coil former 6 is provided in a conventional manner with the corresponding number of windings and winding taps. The windings lie in the annular recess of the half-shell core and do not protrude beyond the end face 9 of the core.

The coil former 6 can have intermediate taps with a number of turns of 18, 36 or the like.

The pre-damping of this electro-magnetic coil 1 can alternatively be provided solely on the end face of the central pin 3 . The corresponding covering preferably has a thickness in the range of 0.5 mm, whereby this can also be carried out with a material thickness of 0.3 or 1 mm, depending on the desired degree of pre-damping. The applied covering 15 , which can be both ferromagnetic and non-ferromagnetic, does not cover the entire end face of the central pin 3 . For example, with a diameter of 15.5 mm of the central pin, the covering applied for pre-damping can have a diameter of 14 mm.

As an alternative or in addition to the damping on the central pin 3 , an L-shaped material covering 7 can also be applied to the peripheral circumference of the outer webs 4 and 5 . This outer pre-damping covering 7 extends on the one hand slightly with an end covering 10 onto the end face of the coil and with a side covering 11 approximately parallel to the axis of the coil. Such an external pre-damping covering 7 can have a side covering with a length of 7 mm and a front covering 10 with an edge area of approximately 2.5 mm with a thickness of 0.5 mm. The outer diameter of the half-shell core can be 35 mm with an inner diameter of approximately 29 to 29.5 mm. The height of the coil core between the support surface and the end surface can be, for example, 10.5 mm.

It has been shown experimentally that the predamping of these Kind is independent of the material applied. Predamping However, is essential in order to change the Quality of the coil, differentiation and selection of the material to be reached when appropriate material flags are approached.

A relatively thin material flag 13 is just an example in Fig. 3, the z. B. can be moved in the axial direction to the end face of the electromagnetic coil 1 . Here, the qualitatively previously explained course is established. However, it is also possible to introduce such a material flag into the electromagnetic field parallel to the end faces of the coil, so that the material selection can be determined in a certain position due to the difference in the coil quality.

This established phenomenon is used particularly advantageously for oscillator coils of inductive proximity switches, since the reliability and safety of such switches are considerably improved by the selection criteria. In terms of circuitry, an electromagnetic coil 1 shown in the example in FIG . B. be used in an inductive proximity switch according to DE 24 00 723 C3. With reference to FIG. 1 there, the inductances L ₁ and L _{2 would be designed} by an electromagnetic coil according to FIG. 3 of this application, a corresponding coil tap being able to be led to the corresponding voltage divider. A corresponding metal flag can be approximated both in the axial direction to the axis of the core of the coil and also perpendicular to it.

The metal flag is usually touchless in the Airspace formed in the vicinity of the end faces of the coil brought in. Other media can be used instead of airspace be present, with only the output quality in such Training must be taken into account.

Claims (4)

1. Coil, in particular oscillator coil of an inductive proximity switch, characterized in that the coil ( 6 ) has a ferrite core ( 2, 3, 4, 5 ) and the end faces of the core are at least partially covered with an electrically conductive material. 12. Coil according to claim 1, characterized in that the coil ( 6 ) in a ferrite shell core half ( 2, 3, 4, 5 ) is arranged. 3. coil according to claim 1 or 2, characterized, that the assignment of the electrically conductive material on the outside frontal extent is performed. 4. Coil according to claim 2 or 3, characterized in that the assignment of the electrically conductive material is carried out on the front central pin ( 3 ).