FR2646537A1 - Method and device for regulation, by microwave radiometry, of an installation for drying a flat material in crossing movement, especially textile - Google Patents

Abstract

The invention consists in measuring the emissivity of the material 4 in the microwave range upon its passage through a set of slotted waveguides 1 placed within the enclosure 11 and of a slotted guide 1' situated at the output of the enclosure 11, in continuously following the curve representing the change in the emissivity of the material along its journey and in controlling the heating means 16 or the crossing movement means 17 in such a way that the value of the emissivity measured in the guide 1' situated at the output of the enclosure 11 is constantly at the minimum of the curve.

Description

METHOD AND DEVICE FOR REGULATION BY HICROWAVE RADIOHETRY
OF A DRYING INSTALLATION & ION OF A FLOWING FLAT SIDE MATERIAL,
ESPECIALLY TEXTILE
The present invention relates to the drying of a planar material in movement in a suitable drying installation, for example a fabric or a fabric in a drying tunnel or ream.

It relates more particularly to the regulation of such drying, based on the emissivity of said material in the range of microwaves.

 We know from French patent NO 2,572,176 an installation for regulating the temperature of a planar moving material based on the emissivity of the material. In such an installation, the planar material passes through a split microwave propagation guide, associated with an amplifier receiver which measures the emissivity of the material during its stay in the waveguide. The amplifier receiver acts on the heating means or on the engine means of the installation as a function of the emissivity measured. To implement this regulation, two versions are proposed. According to a first version, the receiver has been calibrated beforehand according to the material, knowing that according to the composition of the material its loss factor will vary differently with temperature and the value has been determined. of the emissivity on which the regulation is based. According to a second version, the regulation is a function of the measurement of the differential emissivity between the first waveguide and a second waveguide identical to the first, crossed by the same material, but placed in an enclosure brought to temperature on which regulation is based. This second version makes it possible to get rid of the preliminary calibration, however it requires the implementation of a regulated enclosure and on the other hand it requires to know with precision the regulation temperature.

 Now we have found and this is what is the subject of the invention a method of regulating a drying installation which overcomes the aforementioned drawbacks in that it does not require. regulated enclosure or precise knowledge of the regulation temperature.

 According to the invention, the method consists in measuring the emissivity of the material in the range of microwaves during its movement in different points located inside and at least one point located at the outlet of the drying chamber. , to permanently follow the curve representing the evolution of the emissivity of the material along these different points and to control the heating means of the enclosure or the means of movement of the material such that the value of the emissivity measured at the point located at the exit of the enclosure is constantly at the minimum of the curve.

 The regulation of the drying is no longer based as in the process described in patent NO 2,572,176 on the temperature of the material at the outlet, but on the evolution of the emissivity of the material during drying. Indeed, it has been found that during the drying of a material its emissivity was a function not only of its temperature but also of its water content. Much more during the drying of a moving material in an enclosure the temperature of the material remains substantially constant in the first part of the enclosure, while the emissivity decreases until reaching a minimum value. This decrease of 1 emissivity corresponds to the progressive evaporation of water to a certain content beyond which the temperature of the material increases and correspondingly the emissivity. Thus, in accordance with the invention, the material is maintained in the drying enclosure so that the emissivity is minimal at the outlet of the enclosure, whereby drying is carried out under the best conditions, since the material retains its content in equilibrium water, overdrying.

 Preferably, the curve representing the evolution of the emissivity of the material along the different points is continuously followed continuously by calculating the differences in emissivities for each group of two successive points and the heating means or the scrolling means are controlled in such a way that the differences observed for the last two groups are constantly zero.

It is another object of the invention to protect a device specially designed for the implementation of the above method. This device is of a type known by the French patent
NO 2.572.176 in that it comprises at least one microwave propagation guide, splits "into two openings intended to allow the material to pass through, the two openings being made so that they practically do not cut the
current lines present on the walls of the guide and that the plane passing through them is in a maximum field area, parallel to the electric field in the guide propagation mode, an amplifier receiver connected to the guide and capable of measuring the emissivity of the material remaining in the guide and of the means for controlling the means for heating the enclosure or the means for passing the material. According to the invention, the device
understands
a) a set of waveguides of this type traversed by the material during its scrolling from the entry to the
exit from the enclosure, comprising at least three guides to
inside the enclosure and a final guide outside outside
near the exit of the enclosure,
b) means of calculation able to follow the curve representing
the evolution of the emissivity of the material in the different guides
actuating the control means so that the emissivity of the
material in the last guide is constantly at the minimum of the curve
Preferably, the calculation means calculate the deviations of the
emissivities for each set of two successive guides and
operate the control means so that the gaps for the
last two games are constantly zero.

Other characteristics and advantages of the invention
will appear more clearly on reading the description which follows
be made of an example of an installation of
drying equipped with a regulation device equipped with five
split waveguides connected to an amplifier receiver. This installation is illustrated by the appended drawing in which
Figure 1 is a schematic perspective view of a split waveguide
Figure 2 is a partial schematic sectional view along the median plane of the small faces of the guide of Figure
Figure 3 is a side view of the waveguide / coaxial transition
Figure 4 is a schematic view of the regulated drying installation according to the invention
FIG. 5 represents in the form of two curves the evolution of the emissivity (la) and of the temperature (19) of a fabric during its drying.

 Each microwave propagation guide 1 comprises two separate elements 2 and 3 of ninth dimensions in the form of a rectangular parallelepiped, placed on one side and the other of the planar material 4 in continuous movement. The first element 2, in solid lines in FIG. 1, is connected by a coaxial 5 to an amplifier receiver.

 The two elements 2 and 3 are positioned opposite one another by means not shown, leaving between them a free space 6 of the same width e, sufficient for. allow the passage of planar material 4.

 The assembly consisting of the first element 2, the intermediate space 6 and the second element 3 constitutes a rectangular waveguide, operating according to the TELL mode, whose short side b corresponds to the height of an element and whose long side a corresponds to the sum of the widths of the two elements2, 3 and the width e of the free space 6.

 The extreme parts of the two elements 2, 3 are terminated by fixed short circuits 7, 7 ′.

 The transition between the waveguide and the coaxial 5 is obtained by magnetic coupling. As shown in FIG. 2, the coaxial 5 which is a rigid conductive wire crosses the short circuit and enters the first element 2, where it forms a loop 8.

Figure 2 shows the field lines
magnetic in the waveguide, depending on the propagation mode
TELL. To make the loop 8, the end of the coaxial 5 is
folded, in an arc between 270 and 3600, in
a plane which forms with the large faces corresponding to the large
side a of the guide an angle.compris between 40 and 900. First
approximation, the coupling is based on the same principle of
operating as that of a transformer, the lines of
magnetic field passing through loop 8. We understand, at
seen from Figure 2, that magnetic coupling can be achieved
in good conditions by placing the loop 8 in offset by
relation to the median plane of the large faces of the guide, and thus the
split in the guide according to this median plane does not interfere with the
coupling.

In its connection to the amplifier receiver, the
coaxial 5 is surrounded by a sheath 19 of teflon.

In a specific embodiment, the large side has
guide was 22.5 mm, short side b 10 mm, width e of
the free space 6 between the two elements 2 and 3 of 2.5 mm, the
length of the two elements of 41 cm, the loop 8 had a
diameter of the order of 1 cm, and the plane of the loop made a
angle of 450 with the large face of the guide. The entry of the coaxial 5
in the first element 2 corresponded to the axis of symmetry of said
element, and the free end 20 of the loop 8 was flush with the
short circuit 7 in an area between the free space 6 and
the plane parallel to the small faces of the guide and passing through the
5.The coupling obtained in this embodiment is
particularly effective because the reflection coefficient is
using -lOdB on a bandwidth of 1.2 CH and -12dB
over a bandwidth of 0.5 GHz.

described have been put in place on a textile oar 1 1 drying a fabric 4i after it has been impregnated by passing through the scarf 12. The fabric 4 is held in width by metal pins 9 stitched into the lateral zones 10 of the fabric 4, corresponding to the selvedges. Four guides 1 are placed inside the train 11, while the last guide 1 'is placed outside the train 11, just at the exit of the latter.

 The five guides 1,1 'are all connected to the same amplifier receiver 13 via the flip-flop 14, so that the receiver 13 can only receive the thermal noise signals emitted by the fabric 4 from a single guide that time. The receiver 13 is connected to an electronic circuit 15 composed of microprocessors. This circuit 15 is connected either to the heating means 16 of the train 11 or to the engine 17 rotating the axis of the coil 1S receiving the fabric 4 after it has passed through the train 11.

 FIG. 5 shows the curve 21 representing the evolution over time of the permissibility of the fabric 4 during its drying, and opposite curve 22 representing the evolution over the same time of the temperature of the fabric. It was, for the curves represented, a woolen fabric dried at a uniform temperature of 27 "C. During a first period AB which varies according to the water content of the fabric, the temperature of the fabric remains constant. step AB corresponds to the evaporation of the water contained by the fabric; it lasts until the water content of the fabric corresponds to the water content of the drying air. Then the temperature - of the fabric increases until 'to reach the drying air temperature.

 By comparison between the two curves 21, 22 we note that during the first period AB the emissivity of the tissue decreases gradually to reach a minimum at the end of period B.

This is explained by the fact that the emissivity emitted corresponds for the same temperature, both to that of the fabric itself and to that of the water contained in the fabric. Once the water content has stabilized at its equilibrium value the emissivity increases due to the increase in the temperature of the material.

 The five waveguides have been placed on the path of the fabric as it passes through the train so that the measured emissivity corresponds substantially to points C, D, E, F for the first four guides 1 inside the train 11 and at point B for the last guide 1 'outside the train 11.

 The regulation of the train is carried out as follows. The fabric impregnated with the bath contained in the scarf 12 enters the train 11, passes successively through the first four wave guides 1, leaves the train 11, passes through the fifth guide 1 'and is wound on the reel 18 The rocker 14 connects, according to an appropriate sequencing, the amplifier receiver 13 to each guide 1, 1 ′ taken in the order of movement of the fabric 4 in the train 1i. The receiver 13 measures the emissivity of the tissue, passing through the first guide 1, for a given time, transmits the corresponding information to the electronic circuit 15 which keeps it in memory, then the rocker links the receiver 13 to the second guide 1, during the same time, which measures the emissivity and transmits the information to circuit 15, which keeps it in memory. In addition, circuit 15 calculates the difference between the two information received * and so on until the last guide 1 '.

 In optimal operation, as shown in FIG. 5, the differences calculated by the circuit 15 between the third and the fourth, then between the fourth and the fifth guides are substantially zero. On the other hand, the differences calculated between the first and the second, then between the second and the third are positive.

 When we deviate from this normal operation, the circuit 15 activates either the heating means 16 or the engine 17. This is so when the difference in the emissivities measured between the fourth and the fifth guides is negative, this corresponds overdrying, in which case the circuit 15 controls either the reduction in heating or the acceleration of the movement of the fabric. This is also the case when the difference in emissivities between the fourth and the fifth guide is positive; this corresponds to insufficient heating, in which case the circuit 15 controls either the increase in heating or the decrease in the displacement of the fabric.

 The invention is not limited to the embodiment which has just been described by way of non-exhaustive example, but covers all its variants. In particular, the planar material in continuous movement can be a fabric or any type of textile material, for example a knitted fabric, or non-textile, for example a nonwoven or a paper.

Claims (8)

 1. Method for regulating an installation for drying a flat material in continuous movement, characterized in that it consists in measuring the semissivity of the material in the range of microwaves during its movement in different points located inside and at least one point located at the outlet of the drying chamber, to continuously follow the curve representing the evolution of the emissivity of the material along these different points and to control the heating means of the chamber or the material scrolling means so that the value of 1 emissivity measured at the point located at the outlet of the enclosure is constantly at the minimum of the curve. 2. Method according to claim 1 characterized in that the curve representing the evolution of the emissivity of the material is continuously followed along the different points by calculating the differences in emissivities for each group of two successive points and the means are controlled heating or scrolling means so that the differences observed for the last two groups are constantly substantially zero. 3. Device for regulating an installation for drying a planar material in continuous movement of the type comprising at least one microwave propagation guide (1), split through two openings intended to allow the material (4) to pass through. scrolling, the two openings being made in such a way that they practically do not intersect the current lines present on the walls of the guide and that the plane passing through them is in a zone of maximum field, parallel to the electric field in the mode of propagation of the guide, an amplifier receiver (13) connected to the guide and capable of measuring the emissivity of the material staying in the guide and of the means for controlling the heating means (16) of the enclosure or of the means (17 ) scrolling of the material, characterized in that it comprises a) a set of waveguides of this type traversed by the material during its scrolling from the entry to the exit of the enclosure (11), behaved t at least three guides (1) inside the enclosure and a last guide (1 ') outside near the outlet of the enclosure, b) calculation means (15) able to follow the curve representing the evolution changes in the emissivity of the material (4) in the different guides and in actuating the control means (15) so that the emissivity of the material in the last guide (1 ') is constantly at minimum of the curve. 4. Device according to claim 3 characterized in that the calculation means (15) calculate the deviations of the emissivities for each set of two successive guides and actuate the control means so that the deviations for the last two games are constantly zero. 5. Device according to claim 3 characterized in that each waveguide (1,1 ') being a rectangular guide operating in TEOl mode, terminated by two fixed short-circuits, the waveguide and the two short- circuits (7) are in two separate sections (2,3) corresponding to a section along the median plane of the two large faces of the guide and maintained in position facing each other with a spacing (e) making it possible to passage of the planar material (4) over the entire length of the guide and in that it comprises a magnetic coupling means mounted on one of the ends of one of the sections (2 or 3) and connected to the receiver (13) . 6. Device according to claim 5 characterized in that the magnetic coupling means consists of a rigid conductive wire (5), penetrating by one of the short circuits (7) in one (2) of the two sections of the guide wave and whose part (8) located inside the guide is curved in the form of a loop. 7. Device according to claim 6 characterized in that the conductive wire (5) enters the section (2) along the longitudinal axis of symmetry of said section (2); and in that the part (8) forming a loop is bent towards the short-circuit (7) according to an arc of circle between 270 and 3600. 8. Device according to one of claims 6 or 7 characterized in that the loop (8) is substantially in a plane which makes an angle of the order of 45 with the large faces of the guide.