CS217086B1 - Induction position scanner - Google Patents

Description

BACKGROUND OF THE INVENTION The present invention relates to an induction inductance inductive sensor.

The inductive sensors used hitherto contain at least three elements in a differential arrangement, for example three coils or two coils and a ferromagnetic, the coils being either spous or their axes parallel. The functional principle is based on changing the impedance by shifting the ferromagnetic or changing the induced voltage by shifting the ferromagnetic or the third coil.

The disadvantage of the solution with the ferromagnetic ratio is the relatively high weight of the device, with the use of three coils, the difficulty and precision of production are difficult to achieve, because it is difficult to achieve a completely linear sensor run over a wide range.

An advantage of the inductive encoder according to the invention is the possibility of small and small design for given linearity at relatively low production costs.

The principle of the inductive position sensor according to the invention is that the excitation coil connected to the excitation voltage source and the sensing coil connected to the evaluation device are mounted side by side such that the aces of both coils are on each other and sliding shortening threads on the excitation coil.

An exemplary embodiment of an inductive alarm sensor according to the invention is shown in the drawing showing the wiring diagram.

In the drawing, the excitation coils 1 are not connected to the excitation voltage source 2. Next to it is an animation coil 6 connected to the evaluation device and the excitation coil 1 is not dragged freely

a short-circuiting thread which is movable by means of a mechanism (not shown).

The sensor consists of a position differential transformer with two coils X, 2. The excitation coil 1 is not soldered from the source J of the excitation voltage, that is from the AC generator and produces *

around eebe electromagnetic field. The sensor coil 2 is located outside the excitation coil at the center of its length and at a constant distance from its axis. The sensor coil thread axis 2 is perpendicular to the excitation coil thread coil 1. It uses the electromagnetic field intensity component outside the excitation coil 1 for interconnection between the two coils 1, 2 and e. When the coil animation is placed in the middle of the excitation coil length and the symmetry is not broken for any other reason; then the electromagnetic field intensity component outside the excitation coil 1 intersects the coils of the pickup coil 2 in opposite directions so that no voltage is indicated in the coil and the coil 2.

If ae breaks this equilibrium by shifting the coils χ relative to each other, 2 the sensing amplitude of the indicated voltage is created in coil 2. Its magnitude will depend on the longitudinal offset of the phase angle relative to the excitation voltage 0 * or 180 * according to the direction of coil displacement.

For optimum use of the length of the coils due to linearity, the length of the coil 1 is twice the length of the coil 2, with the length of the coil 2 being the dimension parallel to the coil 1 of the coil.

The coils may be 1.2 b _u d without a ferromagnetic core may optionally naleděny to resonance. The coils are interchangeable with respect to DC power supply and sensing.

The inductance sensor of the plow according to the invention can be and advantageously used wherever it is necessary to evaluate the dimensions of the position, even in environments where the sensors with ferromagnetic would change the sensitivity depending on the temperature.

Claims (1)

SUBJECT MATTEREtttt Inductive position sensor comprising excitation and induced voltage coils, characterized in that the excitation coil (1) connected to the excitation voltage source (3) and the sensing coil 12) connected to the evaluation device (4) are fixed side by side with the flow Xl, 2) joou ns self perpendicular o on coil (1) exciter is not dragged sliding torsion thread (5) ·