WO2009015780A1

WO2009015780A1 - Optical proximity sensor for measuring a distance to a magnetic material

Info

Publication number: WO2009015780A1
Application number: PCT/EP2008/005854
Authority: WO
Inventors: Peter Paul Deimel; Andreas Prücklmeier; Thomas Pistner
Original assignee: Eads Deutschland Gmbh
Priority date: 2007-07-31
Filing date: 2008-07-17
Publication date: 2009-02-05
Also published as: DE102007036269A1

Abstract

The invention relates to a proximity sensor (1) for optically measuring the distance to a magnetic material. Said proximity sensor comprises a sensor evaluation unit (2) for providing and coupling light into an optical fiber (3) and at least one optical system arranged inside a sensor housing (4). Said optical system comprises: a lens (5) that can be used to collimate the light emitted by the fiber (3) towards an optical axis (6), a polarization filter (7) for polarizing the light, a Faraday element (8) for rotating the polarization of the light under the effect of a magnetic field (9) and a mirror element (10), arranged at the end of the optical system, for reflecting the light along the optical axis (6) to couple the light back into the optical fiber (3). The invention is characterized in that at least one deflection element (11, 12) for deflecting the magnetic field (9) is arranged in the sensor housing (4) to amplify the effect of the magnetic field (9) on the Faraday element (8).

Description

Optical proximity sensor for measuring a distance to a magnetic material

The present invention relates to a proximity sensor for the optical measurement of the distance to a magnetic material, with a sensor evaluation unit for providing and coupling of light into an optical fiber, at least one arranged in a sensor housing optical system comprising a lens with which from the Fiber can be coordinated in the direction of an optical axis, a polarizing filter for polarizing the light, a Faraday- body for rotating the polarization of the light under the action of a magnetic field and an end-mounted mirror element for reflecting the light along the optical axis for re-coupling in the optical Has fiber.

A generic proximity sensor is already known from US Pat. No. 6,498,654 B1. The proximity sensor is adapted to sense a distance to a magnetic body. In this case, the effect is used that is rotated by the magnetic field, which is generated by the magnetic body, the polarization direction of the light which passes through the Faraday body through it. This light is first coupled into the fiber by the encoder evaluation unit. This is connected only by the fiber with the proximity sensor. The light passes through the fiber into the proximity sensor, where it is decoupled at the fiber end. Through the lens, the light is collimated in the direction of an optical axis, which simultaneously represents the central axis of the proximity sensor. The collimated light then passes through a polarizing filter, which is arranged directly behind the lens plane-parallel to this. Due to the polarization filter, the light is linearly polarized, so that the light wave trains oscillate only in a certain oscillation plane. Adjacent to the polarizing filter is the Faraday body arranged so that the light passes through the Faraday body in a polarized state. Behind the Faraday body, a mirror element is arranged so that the light is reflected at this and again passes through the Faraday body, the polarizing filter and the lens, and is coupled back into the fiber through the lens.

By the action of the magnetic field of the magnetic body on the Faraday body, the polarization direction of the light is rotated. In this case, the light experiences a first rotation when passing through the light in the direction of the mirror element and a second rotation adding to the first rotation during the return of the light back into the optical fiber. The stronger the magnetic field, the greater the angle through which the polarization direction of the light is rotated. Due to the changed polarization direction of the light, the polarization filter again filters out the light wave trains which do not oscillate in the predetermined direction of the polarization filter. Consequently, a further portion of the light is deflected out of the optical axis by the polarizing filter. Therefore, the stronger the magnetic field, the lower the proportion of the light which is coupled again into the fiber and detected by the encoder evaluation unit. The difference in the light output between the emitted light and the returned light can be measured by the encoder evaluation unit, so that after a calibration, a measured value is generated which provides information about the distance of the magnetic body to the proximity sensor.

In the known embodiments of the proximity sensor for measuring a distance to a magnetic material, the problem arises that the magnetic field, which passes through the Faraday body is formed very weak, especially at greater distances from the magnet body. This results in only small power differences between the output and the detected light in the encoder evaluation unit, so that the sensitivity of the optical proximity Herungssensoren is limited. Frequently, such proximity sensors are used for doors, particularly for aircraft cabin doors, so that a signal is provided about the opening or closing state of the door. The measurement signal, which is supplied by the proximity sensor or the encoder evaluation unit, however, is often very weak due to the weak output signal of the proximity sensor, so that reliable information about the opening or closing state of the aircraft cabin door can not be provided.

It is therefore the object of the present invention to provide an optical proximity sensor which has improved sensitivity.

This object is achieved on the basis of a proximity sensor according to the preamble of claim 1 in conjunction with the characterizing features. Advantageous developments of the invention are specified in the dependent claims.

The invention includes the technical teaching that at least one deflection body for deflecting the magnetic field is arranged in the sensor housing in order to amplify the magnetic field for acting on the Faraday body.

The invention is based on the idea of integrating into the sensor housing at least one deflection body, which deflects the magnetic field in such a way that the magnetic flux in the Faraday body is increased. Thus, a stronger rotation of the polarization direction of the light is made possible both in the first and in the second passage of the light through the Faraday body. Consequently, the sensitivity of the proximity sensor is increased, since the measurable by the encoder evaluation unit difference in the power of the emitted and detected light is greater. Does the distance of the magnetic body relative to Proximity sensor, so does the strength of the magnetic field in the Faraday- body, and the distance to the magnetic body or a change in the distance can be detected with a higher sensitivity.

An advantageous embodiment of the deflecting body has a material which has a high magnetic conductivity. Such a material may be, for example, a μ-material and / or a permalloy material. Such materials are formed from soft magnetic nickel-iron alloys and have a high magnetic permeability. In principle, in the context of the present invention, any known material can be used which is characterized by a high magnetic permeability and can serve to reinforce the magnetic field in the Faraday body.

According to an advantageous embodiment, a first deflecting body is arranged in front of and a second deflecting body behind the Faraday body along the optical axis. The front and rear side arrangement describes the region along the optical axis, which on the one hand is formed on the fiber side in front of the Faraday body and on the other side on the mirror element side behind the Faraday body. The magnetic field is concentrated by the first deflecting body therein, and exits the deflecting body on the side of the Faraday body. After the magnetic field has passed through the Faraday body, the magnetic field enters the second deflection body, so that a bundling effect is generated between the two deflection bodies, so that the Faraday body is arranged in the region of the bundled magnetic field between the two deflection bodies.

Advantageously, the first deflecting body is sleeve-shaped, and encloses at least the lens and the polarizing filter. In this case, the first deflecting body adjoins the Faraday body in the direction of the optical axis. By this adjacent arrangement of the baffle maximizes the concentration of the magnetic field in the Faraday body.

The second deflecting body is cylindrical and arranged in the direction of the optical axis on the side facing away from the arrangement of the Faradaykörpers side of the mirror element. The direct arrangement of the second deflecting body on the rear side of the mirror element allows a further optimization of the concentration of the magnetic field in the Faraday body, in that the second deflecting body also has a minimum distance to the Faraday body. Notwithstanding the cylindrical design of the second deflecting this may also be executed cube-shaped or annular, wherein the mirror element may be included in the second deflecting.

A further advantageous embodiment of the deflecting body has a conical shape, wherein the respective conical shape tapers in the direction of the Faraday body. The first deflecting body, in which the lens and the polarizing filter are accommodated, has a small outer circumference in the region of the polarizing filter adjacent to the Faraday body, the outer circumference enlarging conically in the direction of the optical fiber. With respect to the second deflecting body, this has a small outer circumference in the region of the mirror element, wherein the outer circumference increases conically in the direction of the measuring side of the proximity sensor with increasing distance from the Faraday body. By the respective conical shape of the deflecting a further optimization of the concentration of the magnetic field in the field of Faraday body without increased use of material of the deflecting and without weight gain of the proximity sensor 1 can be achieved.

According to a further advantageous embodiment of the invention, the sensor housing and / or the first deflecting body and / or the second deflecting body by a round or a square, preferably a square cross section. Following the cross section of the sensor housing, the cross section of the first and second deflecting bodies can also be round or rectangular.

According to an advantageous development of the proximity sensor according to the invention, a hollow-cylinder-like shielding body made of a material with a high magnetic conductivity such as a μ-material and / or a permalloy material is introduced in the sensor housing. This shielding against lateral magnetic fields can be achieved in order to avoid a falsification of the measurement result concerning the distance of the magnetic body to the proximity sensor. The hollow cylindrical shielding body extends concentrically with the sensor housing along the optical axis either over a partial length or over the entire length of the sensor housing. Depending on the maximum outer diameter of the first and second deflecting body, the sleeve-like shield body can adjoin the first and opposite to the second deflecting body, so that the length of the shielding body is limited by the arrangement of the deflecting bodies.

Advantageously, the magnetic material is formed by a magnetic body, wherein the proximity sensor can be used for optically measuring the distance to the magnetic body in a door system in order to detect the opening and / or closing state. The door system may relate to an aircraft cabin door, cargo hold door or similar door having a safety function. In this case, the magnet body is inserted either in the door leaf or in the frame of the door, the proximity sensor being installed in the other part of the door system. When the door is closed, the magnetic body is arranged in the vicinity of the proximity sensor, so that the closed state of the door system can be detected by the encoder evaluation unit. If the door is opened, then the Magnet body again removed from the proximity sensor, so that the opening state of the door system is detected by the encoder evaluation unit.

Further measures improving the invention will be described in more detail below together with the description of a preferred embodiment of the invention with reference to the figures.

It shows:

Fig. 1 is a schematic representation of the proximity sensor, wherein a magnetic field is indicated by magnetic field lines;

FIG. 2 shows a schematic representation of the proximity sensor with cone-shaped deflecting bodies; FIG. and

Fig. 3 is a schematic representation of a proximity sensor with a built-in sensor housing shielding.

The proximity sensor 1 shown in FIG. 1 is designed for the optical measurement of a distance to a magnetic material, which is indicated by the magnetic body 14. The proximity sensor 1 therefore serves to sense the distance between the magnetic body 14 and the measuring side 15 of the proximity sensor 1. The proximity sensor 1 interacts with a transmitter evaluation unit 2, wherein between the encoder evaluation unit 1 and the sensor housing 4 of the proximity sensor 1 an optical fiber 3 extends. By the transmitter evaluation unit 2 3 light is coupled into the optical fiber, which is coupled out at the end of the optical fiber 3 within the sensor housing 4 from this again. The decoupled from the fiber 3 lights a light Lens 5, which collimates the outcoupled light, so that a parallel light beam is generated.

The parallel light beam passes through a polarizing filter 7, which is subsequently arranged along an optical axis 6 behind the lens 5. The light is linearly polarized by the polarizing filter 7, so that it passes through a Faraday body 8 arranged adjacent to the polarizing filter 7. A mirror element 10 is arranged behind the wavelike body 8 along the optical axis 6, through which the light is reflected, in order to couple it back into the optical fiber 3 through the Faraday body 8, the polarization filter 7 and the lens 5.

If a magnetic field 9 acts on the Faraday body 8, then the polarization plane of the light can be rotated. The rotation of the polarization plane of the light again filters out a portion of the light through the polarization filter 7, so that the power of the light coupled in again into the optical fiber 3 is further weakened. The stronger the magnetic field 9, which acts on the Faraday body 8, the stronger the power of the fed back light is weakened. The difference can be detected by the encoder evaluation unit 2 in order to obtain information about the distance between the magnetic body 14 and the proximity sensor 1. The magnetic field 9 is indicated by magnetic field lines, and is generated by the magnetic body 14.

In front of the Faraday body 8, a first deflecting body 11 is arranged, in which both the polarizing filter 7 and the lens 5 are introduced. Behind the Faraday body 8, a second deflection body 12 is arranged, wherein the magnetic field 9 is bundled by the deflection body 11 and 12 in the region of the Faraday body 8 and thus reinforced. Consequently, in an approximation of the magnetic body 14 to the sensor housing 4, the magnetic field in the region of the Faradaykörpers. 8 significantly increased, so that the sensitivity of the proximity sensor 1 is increased.

2, another embodiment of the proximity sensor 1 is shown. The introduced in the sensor housing 4 first and second baffles 11 and 12 have a conical shape, wherein the conical shape tapers in the direction of Faraday- body 8. In the first conical deflecting body 11, the lens 5 and the polarizing filter 7 is accommodated, wherein the first deflecting body 11 adjoins the Faradaykörper 8 with the tapered cone side. On the side of the large diameter of the conical shape of the first deflecting body 11, the diameter is formed such that it adjoins the inside of the sensor housing 4.

The second deflecting body 12 has the shape of a truncated cone, wherein the mirror element 10 is arranged adjacent to the truncated cone. The deflecting body 12 is formed on the large diameter side corresponding to the diameter of the sensor housing 4, so that the bottom side of the second deflecting body 12 represents the measuring side 15 for measuring the distance to the magnet body 14. The axes of rotation of the conical baffles 11 and 12 lie in the optical axis 6.

Fig. 3 shows a further embodiment of the proximity sensor 1, in which a shielding body 13 is introduced. The shielding body 13 may consist of several elements, which are mounted on the inside of the wall of the sensor housing 4. According to the present embodiment, the shield body 13 has a sleeve shape and extends concentrically with the optical axis 6. Thus, the shielding body 13 encloses the optical system including the lens 5, the polarizing filter 7, the Faraday body 8, and the mirror element 10. Consequently external magnetic fields can not be applied to the Faraday act body 8, so that the result of the measurement of the distance of the magnetic body is not distorted.

The invention is not limited in its execution to the above-mentioned preferred embodiment. Rather, a number of variants is conceivable, which makes use of the illustrated solution even with fundamentally different types of use. In particular, the embodiment of the baffles 11 and 12 is not limited to a separate arrangement, so that the baffle can also be formed by a continuous cylinder body with a bore in which the elements of the optical system are used.

LIST OF REFERENCE NUMBERS

1 proximity sensor

2 encoder evaluation unit

3 optical fiber

4 sensor housing

5 lens

6 optical axis

7 polarization filter

8 Faraday bodies

9 magnetic field

10 mirror element

11 first deflecting body

12 second deflecting body

13 shielding body

14 magnetic body

15 measuring side

Claims

claims

1. proximity sensor (1) for optically measuring the distance to a magnetic material, comprising a transmitter evaluation unit (2) for providing and coupling light into an optical fiber (3), at least one optical system arranged in a sensor housing (4), comprising: a lens (5) with which the light emerging from the fiber (3) is collimatable in the direction of an optical axis (6), a polarizing filter (7) for polarizing the light, a Faraday body (8) for rotating the polarization of the light Light under the action of a magnetic field (9) and an end-mounted mirror element (10) for reflection of the light along the optical axis (6) for re-coupling into the optical fiber (3), characterized in that in the sensor housing (4) at least one deflecting body ( 11, 12) for deflecting the magnetic field (9) is arranged to amplify the magnetic field (9) for acting on the Faradaykörper (8).

2. Proximity sensor (1) according to claim 1, characterized in that the deflecting body (11, 12) is formed of a material having a high magnetic conductivity such as a μ-material and / or a permalloy Matehal.

3. Proximity sensor (1) according to claim 1 or 2, characterized in that along the optical axis (6) a first deflecting body (11) in front and a second deflecting body (12) behind the Faradaykörper (8) is arranged.

4. Proximity sensor (1) according to one of claims 1 to 3, characterized in that the first deflecting body (11) is sleeve-shaped and surrounds at least the lens (5) and the polarizing filter (7) and in the direction of the optical axis (6). adjacent to the Faraday body (8).

5. Proximity sensor (1) according to any one of the preceding claims, characterized in that the second deflecting body (12) is cylindrical and in the direction of the optical axis (6) on the side remote from the array of Faradaykörpers (8) side of the mirror element (10 ) is arranged.

6. Proximity sensor (1) according to one of claims 1 to 4, characterized in that the deflecting bodies (11, 12) are conical, wherein the conical shape tapers in the direction of the Faraday body (8).

7. Proximity sensor (1) according to one of claims 1 to 4, characterized in that the sensor housing (4) and / or the first deflecting body (11) and / or the second deflecting body (12) has a round or a square, preferably a square Have cross-section.

8. Proximity sensor (1) according to one of the preceding claims, characterized in that a hollow cylinder-like shielding body (13) made of a material having a high magnetic conductivity such as a μ-material and / or a permalloy material in the sensor housing (4) is introduced, to achieve a shield against lateral magnetic fields.

9. Proximity sensor (1) according to one of the preceding claims, characterized in that at least the first deflecting body (11) is designed to mechanically receive the optical fiber (3), the lens (5) and / or the polarizing filter (7).

10. Proximity sensor (1) according to any one of the preceding claims, characterized in that the magnetic material is formed by a magnetic body (14), wherein the proximity sensor (1) for optical measurement of the distance to the magnetic body (14) can be used in a door system to detect the opening and / or closing state.