FR2653940A1 - Layer having magnetic or dielectric anisotropy and its method of manufacture - Google Patents

Abstract

The layer according to the invention consists of contiguous (touching) fibres (4, 6) which are hot compacted, parallel to a given direction, and consist of a sheath (18) made of thermoplastic polymer enclosing a magnetic or dielectric pulverulent charge (20), the cohesion of the fibres of the layer resulting from melting of the polymer.

Description

 The present invention relates to a layer with magnetic or dielectric anisotropy intended for the manufacture of a laminated composite material, having absorbent electromagnetic properties, as well as its manufacturing process.

 In particular, this material can be used as a microwave absorber in a wide wavelength range. It can be used as material for coating an anechoic chamber (chamber without echo), as an electromagnetic filter or as electromagnetic shielding used in particular in the fields of telecommunications and computer science (shielding of complex circuits, computers, etc. .) but also in microwave ovens.

 In the application to microwave ovens, the material of the invention is intended to be placed inside the oven door.

 Composite materials make it possible to obtain materials with magnetic permeability and electrical permittivity suitable for each type of application.

 The microwave absorption materials currently known are in the form of thin layers, of thickness less than a few centimeters, made with dense materials such as ferrite or from the dispersion of these materials in an appropriate organic binder.

 The subject of the invention is a new method for manufacturing layers with magnetic or dielectric anisotropy, the layers obtained being intended for the manufacture of a composite material absorbing electromagnetic waves of the thin layer type.

More specifically, the subject of the invention is a method for manufacturing a layer with magnetic or dielectric anisotropy comprising the following steps:
a) - coating of a magnetic or dielectric charge in a thermoplastic polymer sheath to form fibers,
b) - winding of the fibers on a flat support,
c) - cold compaction of the winding obtained in b) to form a layer of fibers,
d) - first hot pressing of the layer obtained in c) in the temperature zone of the rubber pseudoplate of the polymer, then
e) - second hot pressing of the layer obtained in d) at a temperature causing the polymer to melt.

 As thermoplastic polymer used in the constitution of the sheath, mention may be made of polyamides, polyesters, polyphenylenes, polypropylenes, polyethylenes, silicones, etc.

 Depending on the applications envisaged, the dielectric and / or magnetic fibers can receive structural reinforcement in order to improve their mechanical strength.

As reinforcing means, it is possible to use either powder, or fibers, or yarns of glass, carbon, polymer, etc.
Preferably, the coating of magnetic or dielectric charges in a polymeric sheath is done by coextruding a thermoplastic polymer and the respectively dielectric or magnetic charge and, if necessary, the reinforcing means. In particular, the magnetic and dielectric charges are in the form of powder of 10 to 50 micrometers in size.

 The function of the polymeric sheath is to maintain magnetic and dielectric charges, to allow these fibers to be transformed into a thin layer and to impart anisotropy to the properties of the charges.

 The first hot pressing allows the manufacture of a continuous layer of fibers and the second pressing the welding of the polymer sheaths. This hot pressing in two stages makes it possible to maintain the polymer sheaths around the load and thus to keep the magnetic or dielectric anisotropy of the layers, fixed by the orientation of the fibers constituting them.

 The invention also relates to a thin layer with magnetic or dielectric anisotropy obtained by this method.

By stacking layers according to
The invention according to a certain order, it is possible to produce a laminated composite material with absorbing electromagnetic properties.

 This laminated composite material comprises at least two stacks of layers according to the invention assembled, a first stack consisting of a layer of first dielectric fibers, oriented parallel to a first direction, and a layer of first magnetic fibers, oriented parallel to a second direction perpendicular to the first direction, and a second stack consisting of a layer of second dielectric fibers, oriented parallel to the second direction, and of a layer of second magnetic fibers, oriented parallel to the first direction.

 The alternation of the layers with magnetic and dielectric properties on the one hand and the alternation of the direction of magnetic and dielectric anisotropy on the other hand, due to the change of direction of the fibers from one layer to the other, make it possible to reestablish for the composite material an isotropy of electromagnetic behavior.

 This arrangement of magnetic and dielectric fibers makes it possible to obtain composite materials with suitable magnetic permeability and electrical permittivity, the values of which are equivalent to the arithmetic means of the values of the components of each layer, weighted by the thicknesses of these layers.

 In such a configuration, the first layer stack behaves like a polarizer and the assembly is therefore isotropic. Thus, an electromagnetic wave in contact with this first stack can be strongly attenuated and the reflection of this wave can be zero if the impedance agreement is made with the propagation medium of the wave.

 Similarly, the second stack plays the role of a polarizer, this polarizer being crossed at 900 relative to the first polarizer.

 By playing on the values of the electrical permittivity and the magnetic permeability of each layer of fibers, it is possible to obtain this agreement in impedance with the propagation medium as well as a strong absorption of this wave.

 To do this, magnetic materials and dielectric materials are used which have the general relationship E => i, that is to say having an impedance equal to that of the vacuum.

 In addition, the impedance agreement between the propagation medium and the composite material is also achievable if the medium located in contact with the composite material has an impedance different from that of the vacuum.

 Thus, the electrical permittivity respectively of the first and second dielectric fibers is approximately equal to the magnetic permeability respectively of the first and second magnetic fibers and, on the other hand, the magnetic permeability respectively of the first and second dielectric fibers is approximately equal to the electrical permittivity first and second magnetic fibers respectively.

 To simplify the manufacture of the composite material, use is preferably made of first and second dielectric fibers made of the same material although it is possible to use different materials for these first and second dielectric fibers.

Likewise, it is preferable to use the same magnetic material to constitute the different magnetic layers, although it is possible to use different materials from one layer to another.
The double condition above is a priori easier to achieve by the use of two different materials, one having a high electrical permittivity 1 and a low magnetic permeability p1, the other material having a low electrical permittivity t2 and a high magnetic permeability u2.

 The presence in Equations of and y of high and equal imaginary parts makes it possible to obtain a significant absorption of the waves.

As a material couple satisfying the global equation E = j ', mention may be made of magnetic ferrites and dielectric ceramics such as titanates and in particular the ferrite couple of nickel and barium zincititanate. We can also use the couple SiO -Co Nb Zr (with x ranging from 80 to 95 and
2 xyz y + z equal to 100-x) or the FeNiCo-SiO2 couple.

2
Other characteristics and advantages of the invention will emerge more clearly from the description which follows, given by way of illustration and not limitation, with reference to the drawings in which:
FIG. 1 schematically represents in perspective a composite material made up of layers in accordance with the invention,
FIG. 2 illustrates the principle of absorption of microwaves by the material of FIG. 1,
FIG. 3 schematically represents in section a magnetic or dielectric fiber according to the invention,
FIG. 4 gives the theoretical pressure / temperature cycle as a function of the time used for the manufacture of the composite material consisting of layers according to the invention, and
- Figure 5 gives the absorption efficiency values of a material consisting of layers according to the invention as a function of the frequency of the incident wave.

 This laminated composite material consists of an alternation of anisotropic thin dielectric and magnetic layers, made integral either by bonding using an electrical insulating adhesive film of the epoxy or polyester adhesive type, or using a frame. insulating. The number of layers stacked depends on the intended application. In general, this number is a multiple of four. The total thickness of the material can vary from 0.6 to 6 mm.

 The composite material shown in FIGS. 1 and 2 comprises a first thin layer 2 of dielectric fibers 4 oriented parallel to the direction x of an orthonormal system xyz. This layer of dielectric fibers 2 is associated with a thin layer 6 of magnetic fibers 8, oriented parallel to the direction y.

 In Figure 1, the fibers of the different layers are shown non-contiguous so as to better see the structure of the material, although in practice these fibers are contiguous. In addition, these layers are arranged in contact with each other.

 The dielectric fibers 4 have a high electrical permittivity t1 and a low magnetic permeability rl. At the same time, the magnetic fibers 8 have a high magnetic permeability 2 and a low electrical permittivity # 2.

 The adjustment 2 = S1 and 1 2 of the fibers 8 and 4 makes it possible to produce a composite material, generally verifying the equation # = j ′, that is to say having an impedance equal to that of the vacuum.

Recall that tet p satisfy the equations
(1) t = # '+ j # "and
(2) p = # '+ j ".

 The presence in E and of a high and equal imaginary part makes it possible to obtain a significant absorption of an electromagnetic wave 11 striking the stack of layers 2-6.

All calculation made, one obtains a propagation factor a1 high in the direction x corresponding to 8 "and, u" high and a propagation factor a2 low in the direction perpendicular y, satisfying the following equations:
a1 = jw g 1. p2 '
a2 = jw @ # 2. 1
Under these conditions, an electromagnetic wave 11 striking layer 2 and then propagating in the stack of layers 2-6 is polarized and the components El and B2 of the electric and magnetic fields of this wave, respectively parallel to x and y, are strongly mitigated. Stack 2-6 plays the role of a polarizer.

To attenuate the other pair of components
E2 and B1 of the incident wave 11, respectively parallel to y and x, in the composite material, it suffices to add a second set of fibers.

 This second assembly comprises a thin layer 10 of dielectric fibers 12 parallel to each other but perpendicular to the dielectric fibers 4.

In other words, the dielectric fibers 12 are parallel to the direction y. In addition, layer 10 with dielectric anisotropy is arranged in contact with layer 8 with magnetic anisotropy.

 These dielectric fibers 12 are associated with a thin layer 14 of magnetic fibers 16 which are parallel to one another and in the direction x but perpendicular to the dielectric fibers 12 as well as to the magnetic fibers 8.

 The materials constituting the fibers 12 and 16 also satisfy the global relationship = p. The dielectric fibers 12 are made of the same material as the dielectric fibers 4 and the magnetic fibers 16 are made of the same material as the magnetic fibers 8.

 The stack of layers 10-14 constitutes a second polarizer crossed at 900 relative to the first polarizer 2-6.

 The dielectric 4 or magnetic 6 fibers consist, as shown in FIG. 3, of a thin thermoplastic polymer sheath 18 containing a pulverulent filler 20, respectively dielectric or magnetic, and reinforcing fibers 22.

 In particular, the sheath 18 is polyamide 12 of 0.010 to 0.015 mm thick containing glass fibers 22 and a powder 20 of barium titanate or of a nickel and zinc ferrite depending on whether these fibers are dielectric or magnetic . These fibers have an outside diameter of 0.2 to 0.7 mm.

 These fibers have mass loading rates greater than 50% and in particular 95% and volume loading rates of the order of 60X. The filler is in the form of a powder having a particle size of 10 to 50 micrometers.

 The production of each layer of dielectric or magnetic fibers is described below.

The dielectric or magnetic fibers of
The invention described in FIG. 3 are produced by coextrusion of the polymer, the filler and the reinforcing fibers. As a known coextrusion process which can be used in the invention, mention may be made of that described in Engineering techniques 3240-1 to 4 "Flexible prepreg with thermoplastic matrix (FIT)" from Ganga and
Bumblebee. This coextrusion allows fiber production, reproducible and adaptable to different load characteristics taking into account their particular flowability condition.

 The fibers produced are then shaped by contiguous winding on one or two thicknesses on flat mandrels. The plates obtained are then cold compacted under a pressure of 200 MPa in hydrostatic pressure tanks. Finally, the material is transformed in a press with heating plates.

 This last hot pressing step is carried out by plastic deformation of the polymer sheaths followed by a pressureless melting of the latter. The plastic transformation is an irreversible transformation carried out at constant pressure in the temperature zone of the pseudo rubbery plateau of the polymer constituting the sheath of the fibers.

 The thin layers of fibers obtained have a thickness of 0.2 to 0.5 mm depending on the initial diameter of the fibers and the number of layers wound on the mandrels.

 In Figure 4, there is shown the last step of transforming the fibers into a thin layer for polyamide sheaths. This diagram gives the pressure and temperature variations expressed respectively in MPa and OC as a function of the time expressed in minutes.

 Zone A corresponds to a temperature rise from 0 to 1000C under a pressure of 20 MPa.

 Zone B corresponds to the plastic deformation zone of the fiber sheath at 1200C under a pressure of 20 MPa. This step allows the formation of a continuous layer while retaining its magnetic or dielectric anisotropy.

 Zone C corresponds to a temperature recovery from 100 to 1600C under a reduced pressure of 0.2 MPa.

 Zone D corresponds to a second level at a reduced pressure temperature of 0.2 MPa from 160 to 1800C. This step causes the polymer to melt and ensures the adhesion of the polymer sheaths of the layer.

Zone E represents pressureless cooling to limit the creep of the material, and The step
F represents a mold release at 1200C.

 The layers of dielectric and magnetic materials produced as described above are then stacked and then assembled to produce absorbent electromagnetic shielding screens, as described in FIGS. 1 and 2.

 This method of manufacturing layers with magnetic or dielectric anisotropy can be used for the production of materials other than that described in FIGS. 1 and 2. In particular, it can be used for the production of essentially magnetic or essentially dielectric shielding.

 The curve shown in FIG. 5 gives the Er / Ei ratio as a function of the frequency of the incident electromagnetic wave. Ei and Er represent the energy of the electromagnetic wave to be absorbed respectively incident and reflected by the material of the invention and the frequencies are expressed in logarithmic form.

 The curve of Figure 5 was obtained for a composite material consisting of 4 orthotropic layers, that is to say as shown in Figure 1, the dielectric charge being barium titanate and the magnetic charge a nickel ferrite and zinc.

 From this curve, it appears that the composite material has a maximum absorption efficiency value of 18 db at 1000 MHz and an efficiency of 16.5 db between 10 and 800 MHz.

 The materials made up of layers according to the invention are therefore capable of absorbing electromagnetic disturbances over extended bandwidths with sufficient efficiency to attenuate 90 to 99% of the incident wave.

Claims (11)

 1. Method for manufacturing a magnetic or dielectric anisotropy layer comprising the following steps  a) - coating of a magnetic or dielectric charge (20) in a thermoplastic polymer sheath (18) to form fibers (4, 6),  b) - winding of the fibers on a flat support,  c) - cold compaction of the winding obtained in b) to form a layer of fibers,  d) - first hot pressing (B) of the layer obtained in c) in the temperature zone of the rubber pseudoplate of the polymer, then  e) - second hot pressing (D) of the layer obtained in d) at a temperature causing the polymer to melt.  2. Method according to claim 1, characterized in that one coats, in addition, in the polymer sheath, reinforcing means during step a).  3. Method according to claim 1 or 2, characterized in that the coating step is done by coextrusion.  4. Method according to any one of claims 1 to 3, characterized in that the polymeric sheath (18) is made of polyamide.  5. Method according to any one of claims 1 to 4, characterized in that the dielectric charge is a powder of barium titanate.  6. Method according to any one of claims 1 to 5, characterized in that the magnetic charge is a powder of nickel and zinc ferrite.  7. Method according to any one of claims 2 to 6, characterized in that the reinforcing means (20) are in the form of fibers.  8. Thin layer with magnetic or dielectric anisotropy, characterized in that it consists of contiguous fibers (4, 6) compacted hot, parallel to a given direction Cx, y) and consisting of a sheath of thermoplastic polymer (18 ) containing a pulverulent filler (20) magnetic or dielectric, the cohesion of the fibers of the layer resulting from a melting of the polymer.  9. Thin layer according to claim 8, characterized in that the polymeric sheath (18) is made of polyamide.  10. Thin layer according to claim 8 or 9, characterized in that the dielectric filler (20) is a powder of barium titanate.  11. Thin layer according to any one of claims 8 to 10, characterized in that the magnetic filler (20) is a powder of nickel and zinc ferrite.