FR2569851A1 - METHOD FOR DETECTING ADHERENCE DEFECT - Google Patents

Abstract

METHOD FOR DETECTION OF ADHESION DEFECTS OF A COATING ON A SUBSTRATE. IT CONSISTS OF: -TRANSFERING HEAT TO THE COATING; -MEASURE DIFFERENTIALS OF THE COATING TEMPERATURES IN SELECTED POSITIONS; -COMPARE WITH A REFERENCE OF THE TEMPERATURES SELECTED AMONG THE TEMPERATURES MEASURED. APPLICATION TO GAS TURBINE ENGINES.

Description

The present invention relates to the detection of adhesion defects (ie

  ie the detection of bubbles or "bad connections") in a coating applied to a surface. The turbine blades of a gas turbine engine are struck by hot gases and, as is well known, the hotter the gases, the higher the efficiency of the engine's thermodynamic cycle. However, the high

  temperatures tend to degrade the vanes of tur-

  bine. This is why we generally cover the blades with a coating forming a thermal barrier of protection

(RBT).

  A type of protective thermal barrier coating consists of a layer having a thickness

  between 0.076 and 0.41 mm of stabilized zirconium oxide

  made with 8% yttria (Y203). To be effective, it

  must be firmly bonded to the dawn, that is,

  that is to say does not present any bubbles, or lack of adhesion as is the case of FIG. 1. In this figure, a part 3 does not adhere to the metal substrate 6 of the blade in a zone 9. adhesion are unfortunate because a non-adherent material 12 crumbles and detaches from the dawn,

  leaving the metal of zone 9 unprotected.

  Consequently, when applying a coating

  As a protective thermal barrier, it is often

  - 2 - to detect the zones of adhesion defects of the

  coating, that is to say bad fixing thereof.

  The present invention relates to an improved device for measuring the adhesion of a coating to a

S surface.

  Another object of the present invention is a provision

  improved system for the detection of adhesion failure in a thermal barrier coating of a blade of

gas turbine engine.

  In a embodiment of the present invention,

  tion, after heat transfer to a layered material,

  measures temperature differentials at certain

  parts of the material. A defect present in the strat-

  will be revealed by a difference between the temperature at the fault location and the

other places.

  The remainder of this description refers to

  annexed figures which respectively represent:

  Figure 1, a lack of adhesion 12 in a machine

laminated material; -

  Figure 2, an embodiment of the present invention; Figure 3, the path 39 followed by the laser beam 18 of Figure 2 when scanning a target 23; FIGS. 4A-4L of the curves of the temperature as a function of the position of the target 23 of FIG.

  values being taken at intervals of 0.10 seconds.

  FIG. 2 represents an embodiment of

  the present invention, in which a laser 15, preferably

  A YAG laser, such as Model No. 512Q from Control Laser Coporation, Orlando, Florida, produces a laser beam 18 which is projected onto a scanning mirror 21, which reflects the beam onto a target 23. FIG. target 23 as a block but this one

  may consist of a gas turbine engine blade.

  The target 23 comprises a metal substrate 6 supporting a protective thermal barrier coating 23A. An infrared scanning radiometer 24 (referred to as an infrared photography apparatus) such as Model No. 525 of the so-called Inframetrics Company, Bedford, Mass., Is pointed at the target 23 so as to receive the image therefrom. As a result of the movement, represented by the arrows 27, of the mirror 21, the

  laser beam 18 scans the target 23.

  When the laser beam 18 strikes a zone 30 of FIG. 1 (this beam is not shown in FIG. 1), zone in which the thermal barrier coating

  protection is correctly attached, this coating is

  heated. However, as a result of the good adhesion to

  6, there is a rapid transfer of heat and the heat imparted by the laser beam 18 to the coating is dissipated by the substrate 6. In contrast, when the laser beam 18 strikes the area 9 exhibiting a lack of adhesion, the absence of a good fixation in this zone prevents a good transfer of the heat to the substrate 6. More specifically, the coating -formant protective thermal barrier, being made of a ceramic with a low coefficient of heat transfer , tends to

  keep the heat that the laser beam has given it.

  But, if the coating is in contact with the metal substrate-6, whose heat transfer coefficient

  is much higher (possibly from 2 to 3 orders of magnitude

  -deur), the metal substrate then dissipates the heat. The differential heating of the zone 30 having good adhesion to the poorly fixed zone 9 can be detected by the infrared camera. We will now proceed to the discussion of an example of a detection of

this type.

  Target 23 of FIG.

  a 13 cm2 substrate made of an alloy known as Hastelloy X (the

  telloy is a registered trademark of the so-called Cabot Cor-

  Poration, Kokomo, Indiana.). On the 3.2 mm thick substrate, a NiCrAlY alloy 15- to 20-micronmetre bonding layer was pulverized under vacuum plasma followed by a coating. zirconium oxide (ZrO 2) plasma spray

  bilized with 8% Yttria (Y203). Artificially produced

  ciellement adhesion defects 33 and 36 (Figure 3) by applying a solder inhibitor called in the art of soldering "masking product". Misalignment 33

  had a diameter of 6.4 mm and the defect 36 of 9.5 mm.

  The laser beam 18 reflected by the scanning mirror 21 of Fig. 2 scanned along the line 39 of Fig. 3. The size of the laser scan point (beam diameter striking the protective thermal barrier coating) was 4 mm and the laser was operating at a power of about 50 watts. The scanning of the surface of the coating by the point of the laser beam

  was performed at a speed of about 25 mm per second.

  The camera 24 of Figure 2 has received

  an image of the scanning line 39 of FIG.

  trace 43 on its output control apparatus 42 (FIG. 2) of the coating temperature as a function of the

  position on the scan line. For example, the temperature

  Fig. 2 corresponds to point 46A in Fig. 3. The curve obtained varied with time as shown in Figs. 4A-4K. These figures illustrate the actual shape of the curves obtained at the times indicated by

the figures on the abscissa.

  At the instant t = 0.90 seconds, the curve looks

  to that of Figure 4A. The reader will notice an increase

  temperature in zone 75 at the right side of the curve. This increase is due to the fact that the scanning laser beam is about to enter the field of view of the camera,

  from the right. This effect is represented more clearly

-_ 5 _

  4B, where the laser beam has entered the

  field of the camera and is approximately

  Zone 77. An increase in temperature occurs in this zone 77. Figures 4C-4L illustrate the temperature changes that occur when the

  laser scanner scans the field of view of the camera.

  from the right to the left, the point of the beam occupying the approximate area represented by the dashed circle 77. At the point where the beam point

  laser leaves the field of view, there remain two peaks of

  their 80 in Figure 4L. These peaks correspond to the adhesion defects 33 and 36 of FIG. 3 and occur for

  the reasons discussed previously.

  We wish to underline the following three points.

  First, in the previous discussion, the heating of the protective thermal barrier coating was mentioned, an operation which was followed by the observation of the existence of differential cooling zones (i.e. that the tip 82 of Figure 4L has an appearance

  different from 85). However, the heating of the

  This is not necessary, but a cooling operation can be carried out, for example by applying a cold gas, which is followed by the differential heating zone constellation. Thus, the present invention imposes heat transfer to a system having a coating substrate, which is followed by zone detection having different temperatures. In the case of heating the coating, the heat transfer would be positive (in the algebraic sense of the term); it would be

  negative in the case of cooling.

  A temperature transient is the history of

  the temperature as a function of time of an area of the coating

  is lying. For example, points 87A-87L in Figure 4A-4L represent

  feel a temperature spike in the coating area

  23A to which they are associated.

  - 6 - Second, the previous discussion described

  the heating of the target 23 using a laser function-

  at a certain power, with a given size of

  point of the beam, and according to a certain speed of

  layage. Since one watt = one Joule / sec., A watt laser scanning at a 0.13 cm2 point at a rate of 25 mm per second provides a power of 235 Joules per cm2 per second. Thus, one can describe the heating in terms of projection of a power of 235

  Joules per cm2 per second on the bar-forming coating

  thermal protection. It should be noted that the power (ie the Joules per second) is measured at the laser law, whereas for the size of the scanning point and the scanning speed, the measurement is considered at the right of the laser.

  coating. Consequently, the foregoing description does not

  face not the efficiency of energy transfer between the

  laser and coating, although this performance is generally

quite high.

  Thus, the preceding discussion has focused on a comparison of the temperature of the areas of the coating that are physically isolated on the same scanning line of the laser beam. However, this does not need to be the case. We can see the temperature of a coating whose adhesion is correct and use it as a reference to

  instead of an area, such as area 85 of Figure 4L.

  We have just described an invention where the dissipation

  differential pressure of heat between a

  protective thermal barrier mantle with defects

  adhesion and a properly fixed coating is used to detect

  ter the non-adhering parts. A laser is used to heat both types of zones and uses an infrared scanning radiometer to measure the

  temperature of these two types of zone as a function of time.

  It has been found that the temperature of the areas exhibiting adhesion defects remains higher for a measurable time. The present invention uses this discovery

  for the detection of non-adherent areas.

  Many variations and modifications can be made without departing from the scope of the present invention. For example, it is not necessary to use a laser to heat; it can be replaced by a source of hot air or a radiating source of

  heat. In addition, in the previous discussion,

  stunned the coating of a turbo-engine dawn. The current

  invention is not limited to the detection of defects in

  herence in the only case of: blades, but allows such

  detection for others: engine components.

  In addition, the principles of the present invention can be extended to the detection of adhesion defects in

  general, present in any laminate material.

- 8 -

Claims (4)

  1. A method of detecting the absence of contact between a coating (23A) and a substrate (6), characterized in that it consists of: (a) transferring heat to the coating; (b) measuring coating temperature differentials at selected positions;   (c) compare against a reference of the time   selected temperatures among the measured temperatures.   2. A method for detecting a lack of adhesion between a thermal barrier coating (23A) and a component of a gas turbine engine, characterized in that it consists of:   (a) scanning a laser beam (18) on the coating   to heat the latter; (b) measure the temperature of the coating after   heating using a scanning radiometer at infra- red (24);   (c) find (42) the existence of a cooling differential effect of the coating.   3. A method for detecting a lack of adhesion between a coating (23A) forming a protective thermal barrier and a component of a gas turbine engine, characterized in that it consists in: (a) applying the energy to the coating (23A) so as to modify its temperature sufficiently to produce measurable thermal gradients on the surface of the material; (b) cease supplying energy to the coating; (c) controlling the temperature of the coating so as to detect differences in heating rates or   cooling in various areas of the coating.   4. Process according to claim 3, wherein   the heating of the coating is effected by projection of energy   laser (18) on the coating at a rate of about 235 235 Joules per cm per second. Joules per cm per second.