NL8401361A - Distortion detector for pipelines, building materials etc. - uses optical fibre placed along object so that distortion causes change in transmission characteristics - Google Patents

Abstract

An optical fibre (3) runs along the component (1) to be monitored. At intercals it is fixed to the component. Between fixing points (4), the fibre is bent over obstacles (2). The obstacles may be ridges or protrusions from the surface or sides of the component (1). Pulses of light from a monochromatic laser are sent along the fibre, and the light reflected by ebd bends, kinks or breaks is compared with the transmitted pulses. Changes in the form of the component cause changes in the characteristics of the reflected light pulses. Such changes are used to locate the position of the distortion.

Description

I t

Lx 84 5003 Mm / Tg

Protection of pipes, construction parts, etc.

There is often a need for means for monitoring pipes, construction parts and the like against inadmissible temperature increases, deformations, etc. This applies, for example, to pipelines, in particular in refineries, etc.,.

5 hard-to-reach construction parts of aircraft, large structures (such as bridges, oil rigs, etc.), electric cables and the like

It is known per se that the radiation conduction in optical fibers depends on the deformation state, and also on the temperature. A change in the attenuation of the transmitted radiation can be determined with the aid of a transfer measurement.

In practice, however, difficulties arise with regard to the sensitivity of such measurements. First, the location of the failure is not known unless the fiber has been processed or attached in some way to respond to local failures, and only a point measurement is possible. Secondly, a reliable determination can only be obtained in the event of a serious disturbance such as breakage, but then the fiber must always be replaced.

From backscattering and reflection, in particular from pulse-shaped radiation, data with regard to disturbances that occur can be derived, whereby the location of the disturbance can sometimes also be determined within certain limits. Such a measurement provides a continuous picture of the course of the damping or reflection in the fiber, but here too the sensitivity to small changes is usually small.

The object of the invention is to provide an assembly for such purposes, which is characterized by protrusions fixed or to be fastened on the pipe or construction part portion to be monitored, and by a zigzag line guided around this protrusion 8401361 - 2 - and optical fiber attached thereto, which is bent or curved at the location of these protrusions, which fiber is connected at one end to a radiation source, and at the same and / or the other end is connected to means for determining changes in the radiation transfer through this fiber.

When the portion to be monitored changes shape, the curvature of the fiber around the respective protrusions also changes, leading to a change in the backscatter or radiation transmission. After all, the radiation conduction through the fiber takes place by reflection against the outer wall of the fiber or by deflection near this wall, when the fiber has an outwardly decreasing refractive index, but on curvature of the fiber the rays, which are not completely reflected , can come out. In addition, a general low back-radiation occurs through Rayleigh back-scattering, which detects small irregularities in the fiber. By a suitable choice of the mutual distance between the protrusions in the longitudinal and transverse directions of the part to be monitored, a clearly measurable change in the properties of the fiber upon deflection or other deformation of the part to be monitored can be obtained, while in addition, at a sufficiently small distance in the longitudinal direction, the effect is multiplied when a larger number of projections are located in the deformed part. Since the length thereof also changes when a part to be monitored is heated, a temperature change can also be determined in this way. Furthermore, since the effect increases with increasing distortion, a timely warning may be given when approaching an allowable limit.

In particular, these projections form part of a strip which is or can be fixed on the part to be monitored, which strip can be pre-fiber-coated in a considerable length, which means that the assembly is placed on a part to be monitored facilitates.

8401361 - 3 -

With significant temperature drops, relatively large deformations will occur in the part to be monitored, which can be determined with sufficient sensitivity in this way. However, when the allowable temperature drops are relatively small, this sensitivity may become too small for practical purposes. In that case, the protrusions can be connected to the part to be monitored by means of parts whose dimensions change with the temperature, for which purpose, in particular, bimetal parts can be used.

In a practical embodiment, use is made of a bimetal strip provided with projections and connected or connected to the part to be monitored, the mutual distance between the projections depending on the condition of this bimetal strip.

When the influence of the ambient temperature has to be compensated, a second radiation conductor can be arranged next to the first, but which is not subject to the influence of the part to be monitored.

The invention will be explained in more detail below with reference to a drawing; herein shows; 1 and 2 show diagrammatic perspective views of two embodiments of a strip-shaped part according to the invention to be secured to a body to be monitored; Figures 3 and 4 show other embodiments of the part 25 according to the invention; Fig. 5 shows a schematic representation of the basic arrangement of a security assembly according to the invention; and FIG. 6 is a graphical representation for explaining the operation of a preferred embodiment of the invention.

Fig. 1 shows an elongated strip 1, which is provided with button-shaped projections 2 at regular distances. An optical fiber 3 is alternately passed left and right around successive projections 2, and a suitable adhesive bond is secured thereon at 4 using 8401361-4. The fiber is thus curved or kinked at each protrusion.

When the strip 1 is bent or stretched, the distance between the successive projections will change accordingly, and the curvature of the fiber 3 around the projections 2 also changes in the curvature or stretch region. As a result, the portion of the radiation which can leave the fiber (or at least the portion which conducts the radiation there) will also change, which has an influence on the backscattered or transmitted portion of the radiation, and thus on one end. of the fiber can be determined.

It is possible per se to fix the protrusions 2 to the body to be monitored, but this is usually too complicated. It makes more sense to use a strip 1 of such elastic projections made of an elastically flexible and stretchable material, which strip should be attached to the body to be monitored in such a way that the deformation of this body is followed. Such a strip can for instance be manufactured from plastic or metal, and must of course be able to withstand the occurring temperatures.

Such a strip can for instance be manufactured in great lengths and provided with a glass fiber, and in particular it can be rolled up, which considerably simplifies transport and application.

Already with a relatively small deformation of the strip 1, a noticeable change in the backscattering or transmittance of the radiation will occur, whereby, when radiation pulses are used, the location of such a change can be determined from the back-radiation measurements, as will be explained in more detail below. Such strips 1 can be arranged in certain important parts of the body to be monitored, so that a further location of a malfunction may be superfluous. It is also possible to use such a strip along a considerable 8401361

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- to install a part of the body or assembly to be monitored, in which case a further location of a malfunction may be desirable.

The deformation of the strip 1 can be the result of elongation or bending of the body to be monitored, on which this strip is fixed, while already a slight deformation of this body will lead to a clearly measurable change in the fiber behavior. Such a strip is therefore very suitable for providing a timely warning before an inadmissible deformation of the body is reached.

Even when a body to be monitored is heated, a deformation thereof occurs, so that a temperature change, and in particular the approaching of an impermissible temperature change, can also be determined with a strip according to Fig. 1, the location of this temperature change also being possible. are determined.

Such a determination is, of course, usually only suitable for significant temperature changes; an embodiment suitable for smaller temperature changes will be further described.

By a suitable choice of the number of protrusions 2 per unit length of the strip 1, a considerable sensitivity increase can be obtained. In practice, distances of about 25 mm between successive protrusions have proven suitable, the protrusions being knurled cylindrical knobs with a thickness of about 2 mm.

Fig. 2 shows a slightly modified embodiment, the projections being formed by horizontal half cylinders 2 ', while the fiber 3 is anchored at intermediate points 4' on the strip 1. The operation substantially corresponds to that of the strip healed in FIG. 1, but the influence of deflection may be stronger in the case of FIG.

Fig. 3 shows a strip 1 'with lateral protrusions 2 ", wherein the fiber 3 is to be passed alternately around a left and a right protrusion. The intermediate projections can of course also be omitted, but the illustrated embodiment is simpler because of the symmetrical embodiment.

When the strip 1 'is in the form of a bimetal strip, it will warp more or less when the temperature changes, so that the distance between the protrusions 2 "also changes. Since this change will be greater than that due to the deformation of the monitor body, this embodiment is particularly suitable for detecting relatively small temperature changes.

The embodiment according to Fig. 4 substantially corresponds to that according to Fig. 3, but now the strip 1 'is bent in a U-shape, whereby an amplification of the effect is obtained by a certain leverage effect. Here, too, the strip can be designed as a bimetal strip.

It is also possible to connect the protrusions 2 according to Fig. 1 separately to the strip 1 by means of a bimetal connection, but this is of course more complicated than the use of a bimetal strip according to Figs. 3 or 4.

FIG. 5 shows in principle an arrangement for determining the back radiation in an optical fiber 3. At one end of a fiber 3, a radiation source 5 is arranged, which can transmit a narrow beam into the fiber 3 through the intermediary of unspecified means. A partial mirror 6 is arranged between the source 5 and the end face of the fiber 3. Part of the radiation from the source 5 is sent to a first radiation meter 7. Radiation returning from the fiber 3 by backscattering or the like is transmitted by the mirror 6 to a second radiation meter 8.

The output signals of the two radiation meters 7 and 8 are fed to a comparator 9, which can determine a relationship between the two measuring results, while the output thereof is connected to a measuring and / or alarm device 10.

In a preferred embodiment, the radiation source 5 8401361 * - 7 - is an impulse-acting source of, in particular, mainly monochromatic radiation, for example a laser, while the comparator 9 is arranged to determine differences between the incoming and back-radiated pulses, which differ from the run-5 time from a radiation pulse to a back-radiating disturbance and back match.

Fig. 6 shows a simplified graph of the backscattering of a radiation pulse over time, i.e. the distance traveled in the fiber. As a result of transfer-10 losses, the backscatter will gradually weaken, as the dashed-line curve 11 indicates for a substantially straight fiber.

A peak 12 represents the echo of the pulse against the end of the fiber. The drawn curve 13 shows the case of a multi-kinked fiber 3. The jumps 14 indicate the location of the kink points.

When deformation of the fiber support occurs, the jump will increase (or decrease) as indicated at 14 '. After this jump, the curve again runs parallel to itself, as indicated at 13 '.

It will be clear that in the embodiment according to Fig. 1..4 the number of jumps 14 will be very much larger. Also a local change of state (in the dimensions, shape or temperature) of the carrier will involve a relatively large number of kink points, so that a corresponding number of jump changes in the curve 13 occur, and a summed shift of the portion 13 'can be This not only provides a sharper perception of a change in state, but also an equalization of spreads in the buckling effect.

When the influence of the ambient temperature has to be compensated, a second optical fiber, which is not subject to the deformation or temperature of the body to be monitored, but only to the local ambient temperature, can be arranged next to the fiber serving for the measurement.

84 0 1 3 6 1

Claims (8)

Assembly for monitoring pipes, construction parts or the like, characterized by protrusions (2,2 ') mounted or to be attached to the pipe or construction part part to be monitored, and by a zigzag line around these 5 protrusions (2,2' ) an optical fiber (3) lined and fixed thereon, which is bent or curved at the location of these projections (2,2 '), the fiber at one end of which communicates with a radiation source (5), which has the same and / or the other end is connected to means (6, 10) for determining changes in the radiation transfer through this fiber. Assembly according to claim 1, characterized in that the projections (2,2 ') form part of a strip (1,1', 1 ") which is or can be fixed on the part to be monitored. Assembly according to claim 2, characterized in that the strip (1,1 ', 1 ") is provided with a fiber (3) in a considerable length beforehand. Assembly according to any one of claims 1 to 3, characterized in that the protrusions (2) are connected to the part to be monitored by means of components whose dimensions change with temperature. Assembly according to claim 4, characterized in that the connecting parts are bimetal parts. 6. Assembly according to claims 2 and 5, characterized in that the strip (1,1 ") is a bimetal strip provided with protrusions (2 '), the distance between these protrusions (2') being the state of the bimetal strip depends. 7. Assembly as claimed in claim 2 or 6, characterized in that the strip in the main jaw is bent U-shaped. 8401361 -f ' Assembly according to any one of claims Ί..7, characterized in that a second radiation guide is arranged in the vicinity of the first (3) but outside the influence of the part to be monitored. 8401361