EP2095084A2

EP2095084A2 - Optical pressure sensor having at least two optical fibers

Info

Publication number: EP2095084A2
Application number: EP07816272A
Authority: EP
Inventors: Adrian Kummer; Marco Gnielka; Axel Bertholds
Original assignee: Kistler Holding AG
Current assignee: Kistler Holding AG
Priority date: 2006-11-27
Filing date: 2007-11-26
Publication date: 2009-09-02
Also published as: US20100064785A1; WO2008064506A3; JP5345547B2; JP2010511146A; US8074501B2; WO2008064506A2

Abstract

The invention relates to an optical pressure sensor based on light intensity measurements, comprising at least one membrane 8 and two parallel optical fibers 1, 4. At least one first fiber 1 has a fiber end 2 and a light emission surface 3, 3' for emitting light 10 in the direction of the membrane 8, and at least one second fiber 4 has a fiber end 5 having a light admission surface 6, 6' for receiving and transmitting the light 10 reflected on the membrane 8. The concept underlying the invention is characterized in that the light emission surface 3, 3' and the light admission surface 6, 6' of the two fibers 1, 4 are disposed facing away from each other. This changes the optical path of the light 10 during use such that the light portion received by the receiving fiber 4 greatly depends on the membrane position.

Description

OPTICAL PRESSURE SENSOR WITH AT LEAST TWO OPTICAL FIBERS

Technical area

The invention relates to an optical pressure sensor based on light intensity measurements, comprising at least one membrane and at least one first optical fiber and a light exit surface, and at least one second optical fiber arranged parallel to the first optical fiber, and a light entry surface, wherein a light beam from the first fiber can be passed over the light exit surface to the membrane and reflected at this, and wherein the reflected light beam can penetrate via the light entry surface in the second fiber and can be transported in this further.

State of the art

Optical sensors of this type are used for example for engine pressure measurements and installed for this purpose, for example in standard spark plugs. Other models are used, for example, in miniaturized nozzle pressure sensors. In such sensors, light is emitted from a first fiber to a membrane. This membrane is at a different position, ie nearer or farther away from the emitting fiber, depending on what pressure is applied to it from the other side. The light is now reflected on the membrane. Part of the reflected light impinges on the second fiber, which forwards the light to a meter in which this light intensity of the light is measured. Based on the measured light intensity can finally be closed to the position of the membrane with respect to the optical fibers and thus to the prevailing at this time of measurement pressure on the membrane. A disadvantage of such systems is that a small signal is superimposed on a huge offset. Smallest disturbances of this offset therefore result in massive errors in the measured pressure signal.

Presentation of the invention

Object of the present invention is to provide an optical pressure sensor of the type described above, which is less sensitive to load change drift, thermal shock and drift.

So that sensors can be used for example in standard spark plugs, a small diameter is required. The targeted miniaturization of the entire sensor diameter of <2mm, soon already <1.5mm or <lmm, thus represents a continuing challenge.

The object is solved by the characteristics of the independent patent claim.

The idea underlying the invention is that the light exit surface and the light entry surface of the two fibers are arranged facing away from each other. The radiation path of the light is changed in such a way that, in use, the proportion of light received by the receiving fiber 4 depends strongly on the position of the membrane.

In addition, thanks to the favorable beam path, the membrane can be arranged close to the fiber ends, so that a greater proportion of the light intensity can be used. This increases the dynamics of interference. In addition, the variance of the light intensity is linear to the applied pressure. The simplest way to achieve the invention is by a roof grinding of a ferrule which contains these two fibers, wherein the light exit surface and the light entry surface are arranged on a respective roof side of the cut.

Brief description of the drawings

The invention will be explained in more detail below with reference to the drawings. Show it

1a is a schematic representation in section of an optical sensor in the region of the sensor head according to the prior art;

FIG. 1b shows a perspective schematic illustration of a prior art optical sensor in the region of the fiber ends of the light guides; FIG.

FIG. 2 a shows a schematic illustration in the section of an optical sensor according to the invention in the region of FIG

Sensor head;

2b shows a perspective schematic illustration of an optical sensor according to the invention in the region of the fiber ends of the light guides;

Fig. 3 is a schematic representation in section of a fiber;

4 shows a perspective view of an alternative embodiment of a sensor according to the invention in the region of the fiber ends; 5 shows a plan view of an alternative embodiment of a sensor according to the invention in the region of the fiber ends with a multiplicity of fibers;

FIGS. 6a-d are perspective views of alternative embodiments of differently shaped light exit and light entry surfaces;

7 is a schematic representation in section of an alternative embodiment of an optical sensor according to the invention in the region of the sensor head;

8 shows a schematic time-dependent sensor signal using a) a sensor according to the prior art and b) a sensor according to the invention.

Ways to carry out the invention

The reference numerals have been retained in all drawings.

1a shows a schematic representation in section of an optical sensor in the region of the sensor head according to the prior art. In a ferrule 11, a first photoconductive fiber 1 with its fiber end 2 and a first fiber 1 arranged parallel to the second photoconductive fiber 4 are shown with a fiber end 5. In operation, light 10 is emitted by the first fiber 1 at a light exit surface 3 in the direction of a membrane 8 and reflected at this. A part of this light beam 10 finally enters a light entry surface 6 of the second fiber 4 and is forwarded to evaluate the light intensity. The membrane 8 and the ferrule 11 with the two light-conducting fibers 1, 4 are held by a housing 9 in a given position. Depending on how high the pressure is from outside the Housing 9 acts on the membrane 8, the membrane 8 moves closer to the fiber ends 2, 5 of the fibers 1, 4. This changes the proportion of originally emitted by the first fiber 1 light 10, which is inserted into the second fiber 4 a occurs. On the basis of the forwarded by the second fiber 4 light intensity can be concluded that the currently prevailing pressure, since the irradiated by the first fiber 1 light intensity is known.

FIG. 1b shows the end of the ferrule 11 with the two fiber ends 2, 5, the light exit surface 3 of the first fiber 1 and the light entry surface 6 of the second fiber 4 in a perspective illustration according to the prior art. The

The end of the ferrule is ground flat as a whole, so that the light exit surface 3 and the light entry surface 6 are both in a plane that runs parallel to the membrane 8. "

In Fig. 2a the same arrangement as shown in Fig. Ia is shown, with the difference that the light entrance surface 3 and the light exit surface 6 are arranged facing away from each other. They are not, as in FIG. 1 a, on a plane that runs parallel to the membrane, but are inclined at an angle α to it. The emerging light beam 10 is refracted at the light exit surface 3 of the fiber 1 against the center of the ferrule 11 and reflected on the membrane 8 in the direction of the light entry surface 6. Since the entry angle is favorable, a light beam 10 reaching the light entry surface 6 is transmitted in the second fiber 4. But it is crucial that the amount of light of the incoming light beam 10 depends strongly on the membrane position and changes in proportion to this.

The two surfaces 3 and 6 are then facing away from each other when their inner surfaces face each other. Insbesonde- parallel surfaces are neither facing nor facing each other. Various examples are given in FIGS. 2, 4 and 6, which is to be understood as "averted".

By arranging the light exit surface 3 and the light entry surface 6 of the fiber ends 2, 5, the useful signal is amplified in comparison to the offset and the quality of the measurement is increased. The distance of the membrane 8 to the fiber ends 2, 5 and the angle α are optimized according to various aspects. On the one hand, the refractive indices on both sides of the light exit surface 3 and of the light entry surface 6 define the angle of the total reflection which sets a limit to the entry and exit angles. On the other hand, the difference caused by the different membrane positions of the light occurring at the light entry surface 6 should have the highest possible dynamics. This means that the intensity of the light 10 arriving in the second fiber 4 varies as much as possible by changing the position of the membrane 8.

2b shows the end of the ferrule 11 with the two fiber ends 2, 5, the light exit surface 3 of the first fiber 1 and the light entry surface 6 of the second fiber 4 in a perspective view in an embodiment according to the invention. The end of the ferrule 11 is ground in this embodiment in a roof joint, each of the fiber ends 2, 5 ends on a different roof surface. The fiber ends 2, 5 are arranged symmetrically with respect to a median plane 14 of the sensor. In this embodiment, the ridge of the roof Schliffs forms this central plane 14. Preferably, the fiber ends 2, 5 ^'are close to each other, if possible touching.

A further preferred embodiment consists in that the light exit surface 3 and the light entry surface 6 in two levels 12, 13 are located. These planes 12, 13 describe in Fig. 2b, the two roof surfaces of the roof cut.

The angle α between the surfaces of the roof cut and a plane parallel to the membrane 8 should be as steep as possible, but without total reflection occurring at the light exit surface 3 or the light entry surface 6. Angles between 20 and 40 °, in particular between 25 and 35 ° have proven to be particularly suitable.

8 shows schematically a time-dependent sensor signal, in the first region 18 without load and in the second region 19 with full load, wherein in a) a sensor according to the prior art according to FIG. 1 and in b) a sensor according to the invention, for example according to FIG has been used. The first area 18 shows an offset signal 20, the second area 19 a useful signal 21, which is superimposed on the offset signal 20.

It can be seen that the ratio of useful signal to offset signal in the arrangement according to the invention compared to the arrangement of the prior art could be improved by a multiple. As a result, the sensor according to the invention is greatly improved with regard to load change drift, thermal shock and drift.

Fig. 3 illustrates a light-conducting fiber in cross-section. The fiber consists of a light-conducting core 15 which is surrounded by a jacket 16. This jacket 16 is in turn surrounded by a protective layer 17. In the embodiment according to the invention, a fiber should be used whose core 15 constitutes at least 40% of the total area or 60% of the total diameter of the fiber.

In the figures other than FIG. 3, for the sake of simplicity, only the core 15 of a fiber 1, 4 is shown without Coat and protective layer. Contacting fibers 1, 4 therefore always have a spacing of twice the sheath thickness with the protective layer in the illustrations.

The fibers 1, 4 are guided in parallel, which simplifies their handling and processing and allows the miniaturization of the sensor. In a preferred embodiment, shown for example in FIG. 2b, the fibers 1, 4 are guided in a ferrule 11, which _, however, is not absolutely necessary for carrying out the invention. The symmetrical arrangement of the light exit surface 3 and the light entry surface 6 in the sensor is not absolutely necessary, but facilitates the assembly and the evaluation.

An alternative to Fig. 2b embodiment is shown in Fig. 4. In this embodiment, the ferrule 11 has a conical tip, similar to a sharpened pencil with two adjacent mines as fibers 1, 4.

A further alternative embodiment is shown in Fig. 5 as a plan view of a ferrule 11 with fiber ends 2, 5. In this embodiment, several or a plurality of first and second fibers 1, 4 are shown, wherein in operation the first fibers 1 are the transmitting and the second fibers 4 are the receiving fibers. These fibers 1, 4 are arranged on both sides of the median plane 14. All advantageous embodiments, described for Fig. 2, apply analogously to this arrangement with a plurality of first and second fibers 1, 4. In particular, all the light exit surfaces 3 and all light entry surfaces 6 may each be arranged in planes, preferably all the light exit surfaces 3 in a first plane 12th and all the light entry surfaces 6 lie in a second plane 13. These first and second fibers 4 can each be in a row as shown on both sides and close to the Center plane 14, preferably touching each other, be arranged. They can also be arranged in several rows or randomly on both sides of the center line.

Fig. 6 indicates further embodiments, in perspective view. The figures describe various cut shapes, each of which, as shown, only one fiber per non-planar surface 12 ', 13', or, as shown in Fig. 5, a plurality of fibers per non-planar surface 12 ', 13' may be arranged. The above-mentioned preferred arrangements and embodiments apply analogously.

In these representations, a concave cut is shown in FIG. 6a and a substantially convex cut is shown in FIG. 6b, in which the surfaces 3 and 6 are located. In Figs. 6c and 6d, the surfaces 3 and 6 are shaped to be concave (Fig. 6c) or convex (6d) segments of cylinders whose axes cross the median plane 14, or concave (Fig. 6c) or convex (6d) segments of spheres.

All of these cuts described herein are easy to make when the fibers (1, 4) are held by the ferrule (11). Without a corresponding stop, an inventive sensor would be difficult to produce, especially in the mentioned, required miniature version. Another advantage of the ferrule (11) is the protection of the fiber ends with strong vibrations, such as occur in motors.

7 shows a schematic representation in the section of an alternative embodiment of an optical sensor according to the invention in the region of the sensor head. Unlike in Fig. 2a are in this embodiment, the ends of the first fiber 1 and the second fiber 4 in the same plane, parallel to the diaphragm 8. Subsequently, at these fiber ends 2 ', 5', a light-conducting insert body 7 is arranged. This insert 7 fulfills the same function as the fiber ends 2, 5 of the arrangement in Fig. 2a, which are integrally connected to the two fibers 1, 4. In particular, the light exit surface 3 'and the light entry surface 6' of the insert body are arranged facing away from each other as in the other described arrangements. Thus, the beam path in this alternative embodiment is substantially the same as in the previously described arrangement and has the same advantages as described. The beam path in the region of the insert body is merely somewhat conical, since the reflective sidewalls of a light guide in the area of the insert body 7 are missing. All embodiments described above, in particular those described in Figures 4-6, can be correspondingly achieve with an insert body 7 with the same advantages described.

LIST OF REFERENCE NUMBERS

1 first fiber

2 2 'fiber end of a first fiber

3 3 'light exit surface 4 Second fiber

5 5 'fiber end of a second fiber

6 6 'light entry surface

7 light conductive insert body

8 diaphragm 9 housing

10 light, light beam

11 ferrules

12 12 'First level

13 13 'Second level 14 median plane

15 core

16 coat

17 protective layer

18 First range, no load 19 Second range, full load

20 offset signal

21 useful signal

Claims

claims

1. An optical pressure sensor based on light intensity measurements, comprising at least one membrane (8) and at least one first optical fiber (1) and a light exit surface (3, 3 ') _/ and at least one first optical fiber (1) arranged in parallel second optical fiber ( 4), and a light entry surface (6, 6 '), wherein a light beam (10) from the first fiber (1) via the light exit surface (3, 3') to the membrane (8) and can be reflected at this, and wherein the reflected light beam (10) can penetrate into the second fiber (4) via the light entry surface (6, 6 ^r ) and can be transported further in the latter, characterized in that the light exit surface (3, 3 ') and the light entry surface (6, 6') ) are arranged away from each other.

2. Sensor according to claim 1, characterized in that the light exit surface (3, 3 ') a fiber end (2) of the first fiber (1) and / or the light entry surface (6, 6') a fiber end (5) of the second Fiber (4) is.

3. Sensor according to claim 1, characterized in that between a fiber end (2) of the first fiber (1) and the light exit surface (3, 3 ') and / or between a fiber end (5) of the second fiber (4) and the Lichteintrittsflä - (6, 6 ') a light-conducting insert body (7) is arranged.

4. Sensor according to one of the preceding claims, characterized in that the fibers (1, 4) are guided in a ferrule (11).

5. Sensor according to one of the preceding claims, characterized in that the light exit surface (3, 3 ') and the light entry surface (β, 6') are arranged symmetrically in the sensor.

6. Sensor according to one of the preceding claims, characterized by a plurality of first fibers (1) for emitting light (10) and / or a plurality of second fibers (4) for receiving light (10).

7. Sensor according to claim 6, characterized in that each fiber end (2) of a first fiber (1) is arranged mirror-symmetrically with respect to a median plane (14) to a fiber end (5) of a second fiber (4).

8. Sensor according to one of the preceding claims, characterized in that each light exit surface (3, 3 ') and each light entry surface (6, 6') is in a plane.

9. Sensor according to one of the preceding claims, characterized in that all the light exit surfaces (3, 3 ') in a first plane (12, 12') and all Lichteintritts- surfaces (6, 6 ') in a second plane (13, 13 ') are located.

10. Sensor according to one of the preceding claims, characterized in that each fiber end (2) of a first fiber (1) close to a fiber end (5) of a second fiber (5), preferably contacting this, is arranged.

11. Sensor according to one of the preceding claims, characterized in that the light exit surface (3, 3 ') and the light entry surface (6, 6') an angle between 20 ° and 40 °, preferably between 25 ° and 35 ° to the membrane (8 ) exhibit .

12. Sensor according to one of the preceding claims, characterized in that each optical fiber (1, 4) comprises a core (15), a jacket (16) and a protective layer (17), wherein the surface of the core (15) at least 40% of the area of the entire fiber (1, 4).

13. Sensor according to one of the preceding claims, characterized in that the sensor diameter is smaller than 2mm, preferably smaller than 1.5 mm.

14. Sensor according to one of the preceding claims, characterized by the use in standard spark plugs and / or for engine pressure measurements.