FR2666420A1 - Device for transmitting infrared radiation to an object for a controlled time period - Google Patents

Abstract

Device for infrared illumination of a controlled duration, which can be used especially for inspecting components using controlled infrared thermography, including a lamp (1) containing a filament through which an electrical current may pass, and a reflector mounted so as to rotate about an axis passing in the vicinity of the lamp, with means (11, 12) for driving the reflector in rotation at a speed calculated as a function of the desired irradiation duration and means (14) for absorbing the radiation emitted by the lamp and deflected by the reflector into a direction other than that of the object. Preferably, the reflector (6) is elliptical or parabolic, the filament (2) being close to its focus, and the absorption means comprising a casing cooled by liquid.

Description

 The present invention relates to a device for sending infrared radiation onto an object during a controlled time interval.

 The method of controlling metallurgical or other parts by the technique known as "stimulated infrared thermography" comprises-an-exposure of the part to be checked to a brief flow of heat. Known thermography methods then make it possible to detect surface, or deeper, homogeneity defects in the part.

Current technical means for providing the heat flow include either flash tubes or infrared emitting heating tubes.

 With the first type of heating element, the duration of the heat flash is short, of the order of a few milliseconds. This duration allows optimal exploitation of thermal phenomena, since the duration of thermal stimulation is less than the time of appearance of thermal contrasts linked to faults. However, the energy delivered, which is of the order of 5 kilojoule, is relatively low, while the power required, of the order of 1 megawatt, can lead to the degradation of certain materials, such as composites.

On the other hand, the necessary power supply calls for large and expensive capacitive systems.

 With the second type of heating element, the disadvantages are substantially opposite. In fact, the thermal inertia of the tungsten filament, which is the resistive element of the tube, involves relatively slow heating and cooling times.

However, the energy delivered is relatively high, of the order of 20 kilojoule and the electrical supply can be carried out using the sector, possibly with an additional transformer, and in any case in an inexpensive and space-saving manner. .

 The current technique therefore does not make it possible to control the duration of illumination at will in a simple manner and for a low price, while providing relatively large energy.

 The object of the present invention is therefore to provide a device which makes it possible to heat a room with an illumination duration which can be controlled, for example between 0.1 and several seconds, while being simple and inexpensive to produce.

 In addition, the system according to the invention must allow the most homogeneous heating of an extended surface, to be used with a high repetition frequency, to allow the heat source to be adapted to the heated surface by juxtaposing several modules side by side, to adapt the power of the heating flow to the material to be controlled.

 To obtain this result, the invention provides a device for sending infrared radiation onto an object during a controlled time interval, this device comprising a lamp containing a filament which can be traversed by an electric current, and a reflector intended to send the infrared radiation emitted by the lamp towards the object, this device having the particularity that the reflector is rotatably mounted about an axis passing in the vicinity of the lamp, in that means are provided for driving the reflector in rotation at a speed calculated as a function of the desired irradiation time, in that means are provided for absorbing the radiation emitted by the lamp and deflected by the reflector in a direction other than that of the object.

 By saying that the axis of rotation of the reflector passes close to the lamp, it is meant that it is placed close enough to the latter so that, in its rotation, the reflector passes from an illumination position, where it returns. the radiation towards the object, at a concealed position, where it is located between the lamp and the object, so that it then additionally behaves like a shutter, which stops direct radiation from the lamp towards the 'object.

 To allow exposure times as low as 0.1 seconds, the resistance to rotation of the shutter-reflector must be as low as possible, whether friction or inertial forces, which imposes various constraints to practical achievements.

 Preferably, the lamp is provided with a rectilinear filament, the reflector in the form of a fraction of cylinder with elliptical or parabolic section, a focus of the ellipse or the parabola being on the filament or close to that -ci, and said filament is on the axis of rotation of the reflector.

 This embodiment makes it possible to place the top of the reflector at a short distance from the filament, and consequently to reduce the inertial forces at equal power.

 Preferably also, the means for absorbing the unwanted radiation comprise a metal casing cooled by a circulation of liquid.

 Vigorous cooling makes it possible to produce a compact assembly, and consequently to reduce the dimensions of the reflector, which also reduces its inertia.

 If large radiation powers are desired while retaining the advantages resulting from the low inertia, it is advantageously provided that the device is comprised of several elementary devices, each comprising a lamp, a rotary reflector, means for absorbing the radiation. deflected and means for driving the reflector, the device further comprising means for synchronizing said means between them so that an object can be simultaneously illuminated by all the lamps.

The invention will be described in more detail with the aid of a practical example illustrated with the drawings, among which
Figure 1 is a longitudinal section along the line
II of Figure 2, of a device according to the invention.

Figure 2 is a cross section along the line Il-Il of Figure 1, and
Figure 3 is a view similar to Figure 2, but with the reflector shown in the closed position, and not the open position as in Figure 2.

 Figure 4 is a diagram, in perspective, of an apparatus formed of several devices according to the invention.

 The main element of the device described is a tube, or "lamp", formed of a straight tungsten wire 2, placed inside a transparent tube 3, also straight. Current supply terminals, not shown, are provided at the ends of the tube 1.

The latter is carried, near its ends, by supports 4, themselves mounted in a casing 5.

 A reflector 6, in the form of a portion of cylinder with elliptical section, is mounted with its generatrices parallel to the wire 2. It is itself carried, at its ends, by two crowns 7, 8, themselves supported by the casing by by means of a roller bearing 9 and a ball bearing 10, concentric with the supports 4, so that the reflector can pivot around an axis of rotation coincident with the wire 2. If necessary, other types of bearings may be suitable, but the described arrangements are preferred which reduce friction as much as possible.

 Depending on the shape of the ellipse which forms the cross section of the reflector, and the position of the wire 2, the radiation reflected by the reflector can be parallel, convergent or divergent. In particular, if the ellipse approaches a parabola, and if the wire 2 is at the focus of this parabola, a reflected radiation will be substantially parallel. Slightly different arrangements can be chosen according to the problem which arises, either by modifying the shape of the reflector, or by moving it relative to wire 2.

 Inside the housing is also provided a drive motor 11, arranged so as to rotate the reflector at a speed chosen in advance by means of a drive belt 12. In another model, the drive is ensured by gears.

 The housing 5 is in two parts assembled in a removable manner by screws not shown: on the one hand, a motor housing 13, which contains the motor 11, the transmission 12, one of the crowns 7 and the corresponding bearing 9, and d on the other hand, a cowling 14, which carries the other crown 8 and the associated bearing 10. If it is desired to use a tube 1 of different length, it suffices to replace the reflector 6 and the cowling 14 by a reflector 5 and a cowling of suitable dimensions.

In practice, the device is suitable for supporting all the lamps of the PHILIPS "T3" type range and
GENERAL ELECTRIC. The cowling 14 further comprises a cooling chamber 15, supplied with a stream of water, or of another fluid, which circulates between an inlet nozzle 16 and an outlet nozzle 17.

In Figures 2 and 3, there is shown by arrows 18 the direction of the reflected radiation. In the case of Figure r the radiation 'escapes outward towards a workpiece 19, however, in the case of Figure 3, the reflector having rotated 1800, the workpiece 19 does not receive no more radiation.
It will be appreciated that it is possible, by varying the speed of rotation of the motor 11, to set the duration of illumination of the part 19 at will.

 The speed of rotation of the motor 11 can be uniform, but, in practice, it is rather provided that the motor is stopped for a variable time, which corresponds, for example, to the setting up or replacement of the part to be studied, the reflector then being in the situation in FIG. 3, then the motor is actuated to cause the reflector to make a complete revolution, at a defined speed, which illuminates the room for a determined time. At the end of this turn, the reflector returns to the position of FIG. 3 and stops there until a new operation.

 In a variant, the reflector makes a U-turn from the position in FIG. 3 and stops in the position in FIG. 2 for the desired illumination time. It then returns to the initial position by turning half a turn, either in the same direction or in the opposite direction. It can also cross the position of FIG. 2 at a reduced, controlled speed.

 Stepper motors lend themselves particularly well to such modes of use, for example a "Microstepping" motor from DIGIPLAN.

 The housing is made of light metal, so as to provide good heat dissipation, in conjunction with the coolant.

 In practice, this simple and very inexpensive device makes it possible to easily obtain illumination durations adjustable between 0.1 and 1 second or more.

 For the illumination of parts of large dimensions, or of non-regular shape, it is possible to associate several devices such as that which has just been described, provided that the motors are controlled synchronously. FIG. 4 shows how several devices, of which only the wires 2 and the reflectors 6 have been shown, are arranged to illnnine together a part 19 of large dimensions.

Claims (5)

 1. Device for sending infrared radiation onto an object during a controlled time interval, this device comprising a lamp (1) containing a filament which can be traversed by an electric current, and a reflector intended to send the infrared radiation emitted by the lamp towards the object,  characterized in that the reflector (6) is rotatably mounted about an axis passing through the lamp (1), in that there are means (11, 12) for driving the reflector in rotation at a speed calculated in depending on the desired irradiation time, in that means (14) are provided for absorbing the radiation emitted by the lamp and deflected by the reflector in a direction other than that of the object.  2. Device according to claim 1, characterized in that the lamp is provided with a straight filament (2), the reflector (6) has the shape of a fraction of a cylinder with elliptical or parabolic section, a focus of the ellipse or the dish located on or near the filament (2), and said filament is on the axis of rotation of the reflector.  3. Device according to claim 1 or 2, characterized in that the means for absorbing the unwanted radiation comprise a metal covering (14) cooled by a circulation of liquid (15-17).  4. Device according to one of claims 1 to 4, characterized in that it comprises a motor housing (5) which contains the drive means (11, 12) of the reflector, and on which is mounted, so removable, a cover (14) capable of absorbing the radiation from the lamp, the motor housing and the cover each carry a support for the lamp and a bearing for the reflector, so that it is possible to replace the lamp with a another of different length by replacing only the cowling and the reflector with similar pieces of suitable length.  5. Device according to one of claims 1 to 4, characterized in that it is composed of several elementary devices, each comprising a lamp, a rotary reflector, means for absorbing the deflected radiation and means for driving the reflector, the device further comprising means for synchronizing said drive means with one another so that an object can be simultaneously illuminated by all the lamps.