FR2879828A1 - HYPERFREQUENCY CIRCULATOR WITH CONNECTING PLATES - Google Patents

Abstract

The field of the invention is that of the connection of electronic components and more specifically of the microwave electronic components used in particular for producing insulators or circulators. The miniaturization of the printed circuit boards has resulted in the appearance of components of a larger size. in addition reduced. Thus, a circulator is mounted in a housing whose dimensions are of the order of 1 to 2 centimeters. The transfer of such components on the printed circuit then makes use of automated techniques that require having components whose geometry is The circulator (10) according to the invention comprises mechanical positioning aids (133) integrated with the connection pads (130), to minimize mounting problems and to obtain better reproducibility between circulators. More specifically, each stud comprises a central conductive core (131) connected to the electronic circuit, an electrical insulator (132) surrounding said central core (131) and a mechanical centralizer (133) having positioning means. (9) component the circulator is mounted in stress in its mechanical housing (110, 111). This provides a clipped housing at a reduced cost compared to traditional housings.

Description

HYPERFREQUENCY CIRCULATOR WITH CONNECTING PLATES

  The field of the invention is that of the connection of electronic components and more precisely of the electronic microwave components used in particular for producing insulators or electronic circulators.

  In a microwave system, the circulators are three-port systems for guiding the signal from a first port to one of the two other ports in a privileged manner as illustrated in FIGS. 1 and 2. In FIG. E symbolized by a first arrow arc from the port 1 of the circulator 10 is thus guided to the port 2. Conversely, the received signal R symbolized by a second arrow arc from the port 2 is guided to the port 3. This eliminates, without excessive losses, the emitted signal E of the received signal R. Several solutions are possible to carry out the guidance of the signals. Generally, the separation is carried out by a non-reciprocal effect. It is known that certain physical effects such as the Faraday effect do not respect the reversibility of time, that is to say that an electromagnetic wave does not have the same behavior according to its direction of propagation. Magnetic materials of ferromagnetic type have their susceptibility which has this feature. The value of the susceptibility depends on the direction of propagation of the wave. We can also say that the susceptibility is different depending on whether the wave is polarized circularly left or circularly right. It is this effect that is used to obtain efficient circulators. It is then possible to separate without significant losses the transmitted and received signals which are necessarily of different meanings.

  Conventionally, a circulator 10 essentially comprises, as indicated in FIG. 3: E 'A resonant electromagnetic cavity 9 which is a volume filled with a dielectric material 12 limited by electric or magnetic type walls. In general, for circulator applications, the cavity is in the form of a flat circular disk, said cavity comprising: a central electronic circuit 13 essentially comprising: coplanar lines; o connection tracks of the microwave circuit located at 120 degrees from each other and protruding from the cavity; two ferrite elements 14 located above and below the central electronic circuit 13; two ground planes located above and below the ferrite elements; o The assembly consisting of a first ground plane, a first ferrite, the electronic circuit, the second ferrite and the second ground plane being mounted between two permanent magnets 16; o Other elements, not shown in Figure 3, ensure the homogeneity of the fields by means of pole pieces or heat compensation or mechanical maintenance.

  A mechanical housing 11 of protection.

  The ever-increasing miniaturization of printed circuit boards has resulted in smaller and smaller components. Thus, a circulator is mounted in a housing whose dimensions are of the order of 1 to 2 centimeters. The transfer of such components to the printed circuit boards then makes use of automated techniques which require having components whose geometry is defined with great precision.

  Given the frequencies at which the circuit of a circulator operates, any deviation in the position of the connection points of the circulator relative to the tracks of the circuit on which it is mounted results in: E risks of embrittlement of the weld which adversely affect the reliability of the assembly; 10 15 20 É risks of a circuit-to-circuit between the active tracks and the electrical ground; É impedance breaks that result in significant losses in the circuit.

  In addition, the connecting track elements protruding outside the metal frame are fragile. These elements can in particular bend, bend or break during the various manipulations of the circulator before its final assembly on its printed circuit, leading to the loss of the component.

  Many technical solutions have been tried: É Mixed solutions using dielectric bases of various shapes, and É Connection elements based on printed circuits.

  However, these solutions do not allow to simply carry out an automatic wiring surface mounting of the circulator. In particular, during the soldering of the component on the printed circuits, the temperature change is reflected in the case of assemblies having printed circuits by differential expansions resulting in excessive stressing of the device.

  The invention proposes to remedy these problems. The circulator according to the invention comprises mechanical positioning aids integrated electrical connection pads, to minimize mounting problems and to obtain better reproducibility between circulators.

  In the circulator according to the invention, the electronic part of the circulator is mounted in constraint in its housing. A clipped casing is thus obtained at a reduced cost compared with conventional casings whose assembly is achieved by means of holding parts requiring specific machining such as threads or tappings.

  In addition, the coaxial feedthroughs of this new solution make it possible to obtain a component that is easier to handle and transportable without particular precautions. This increases the reliability of the component while reducing its cost.

  Of course, the devices according to the invention are not limited to the field of microwave components of the circulator type and can be applied to any surface mount electronic component requiring precise positioning of the important electronic connectors.

  More specifically, the subject of the invention is an electronic component comprising a mechanical housing and an electronic assembly comprising at least one electronic circuit, and at least two electrical connection pads intended to ensure the electrical interconnection of the component with an external printed circuit, characterized in that the electrical connection pads comprise mechanical means to ensure their precise positioning in the housing.

  Advantageously, each stud comprises a central conductive core connected to the electronic circuit, an electrical insulator surrounding said central core and a mechanical centralizer comprising positioning means. In addition, the central core has a substantially cylindrical shape, the electrical insulator is an annular sleeve of substantially cylindrical shape and the mechanical centralizer is also an annular sleeve of substantially cylindrical shape, the axes of revolution of the different cylinders being merged.

  Advantageously, the mechanical centering device comprises at least one groove whose axis is parallel to that of the various cylindrical parts composing the stud and the housing comprises at least one slide in which the groove is housed.

  Advantageously, the mechanical housing essentially comprises a lower part and an upper part, the upper part being clipped in the lower part, the electronic assembly being held in tension between these two parts, the lower and upper parts of the casing being made of folded sheet metal. .

  The electronic assembly operates in particular in the microwave range, the component may be a circulator or a microwave isolator.

  Advantageously, the core, the insulator and the mechanical centering device of the stud are arranged so as to ensure continuity of impedance between the 5; coplanar lines of the electronic circuit and the conductive lines of the external printed circuit. Moreover, if sr is the electrical permittivity of the insulator, D its external diameter and its internal diameter, then the impedance Zc of the connection pad is substantially: Zc = 138.Log d V r J Thus, to ensure a impedance of 50 ohms in the microwave range, with a Teflon insulator, the ratio of the external diameter D of the electrical insulator to its internal diameter d is substantially equal to 3, the external diameter D is between 1.5 millimeters and 5 millimeters and the internal diameter d is between 0.45 millimeter and 1.5 millimeter.

  The invention will be better understood and other advantages will become apparent on reading the following description given by way of non-limiting example and with reference to the appended figures in which: FIGS. 1 and 2 represent the operating principle of a microwave circulator ; Figure 3 shows a simplified sectional view of a circulator; FIG. 4 represents an exploded view of a circulator according to the invention; FIG. 5 represents an exploded view of the mounting of a connection pad; Figures 6 and 7 show respectively a top view and a side view of the cavity 9 mounted in the lower part of the housing; Figures 8 and 9 show, in side views, the mounting of the upper part of the housing in its lower part.

  By way of non-limiting example, FIG. 4 represents an exploded view of a circulator 10 according to the invention. It essentially comprises: E an electromagnetic cavity 9; A mechanical housing 11 essentially comprising a lower portion 110 and an upper portion 111.

  The cavity 9 is composed of: E A central electronic circuit 13 essentially comprising: coplanar lines 134 terminated by; o connection areas 135 of the microwave circuit located at 120 degrees from each other and protruding from the cavity; Two ferrite elements 14 located above and below the central electronic circuit 13; Two ground planes located above and below the ferrite elements 14; The assembly consisting of a first ground plane 15, a first ferrite 14, the electronic circuit 13, the second ferrite 14 and the second ground plane 15 being mounted between two magnetic assemblies comprising polar parts 17 and permanent magnets 16. The pole pieces make it possible to homogenize the magnetic fields of the permanent magnets; É A first mechanical part 18 makes it possible to ensure the thermal compensation of the cavity; É A second mechanical part 19 ensures the mechanical stressing of the cavity in its housing; Three lugs 130 provide the connection between the connection tracks of the electronic circuit and the printed circuit on which the circulator is mounted.

  The connection pads 130 make it possible to ensure a precise and reproducible electrical connection of the coplanar lines 134 of the circulator on a printed circuit.

  Figure 5 shows an exploded view of a connection pad. It comprises: E a conductive central core 131 connected to one of the connection zones 135 of the electronic circuit 13, É an electrical insulator 132 surrounding said central core and, É a mechanical centralizer 133 comprising positioning means 136.

  By way of example and as illustrated in FIG. 5, the central core 131 has a substantially cylindrical shape, the electrical insulator 132 is an annular sleeve of substantially cylindrical shape and the mechanical centralizer 133 is also an annular sleeve of substantially cylindrical, the axes of revolution of the different cylinders being merged, the core 131 being housed in the sleeve 132, said sleeve 132 being housed in the mechanical centralizer 133.

  The electrical contact between the pad 130 and a coplanar line 134 is achieved by means of the conductive core 131, one end of which is seated in a recess or orifice made in the connection zone 135 of the coaxial line 134 as indicated in FIG. 5, the other end being blocked by the insulating sleeve 132 trapped in the centraliser 133.

  To ensure the stability of the structure during its transfer to the printed circuit by welding, it is important that the assembly of the metal core in the connection zone is achieved by means of high melting point solders. For example, one can use a solder metal / metal electrical solder, type steel / steel whose melting point is located around 1200 degrees or brass / brass whose melting point is located near 600 degrees. This method assures an assembly on the printed circuit of high reliability insofar as the risk of breakage of these solders at the time of wiring in the passage furnace are very small.

  The mechanical centering device 133 comprises two grooves 136 whose axis is parallel to that of the various cylindrical parts composing the stud. Said grooves 136 take place in slides 113 formed in the lower part 110 of the metal casing. This arrangement makes it possible to position the connection pads 130 precisely in the plane of the printed circuit. The dimensions of the metallic core, the insulator and its centralizer serving as mass shielding are optimized so as to avoid an impedance break between the microwave conducting lines located on the receiver printed circuit and the coplanar lines constituting the conductive part of the circulator.

  The impedance of the coaxial feedthrough essentially depends on three main parameters which are: E the electrical permittivity Er of the electrical insulator 132; É the outer diameter D of the electrical insulator; É the internal diameter d of the electrical insulator.

  In the frequency range between a few hundred megahertz and 20 gigahertz, it is shown that, as a first approximation, the impedance Zc of the connection pad is: 138 D1 Zc = .Log-dJ Thus, if the electrical isolator is made Teflon, whose electric permittivity Er is about 2.1, to obtain an impedance Zc 10 close to 50 ohms, the ratio D / d must be close to 3.

  For frequencies of a few hundred megahertz, d and D are substantially 1.5 millimeters and 5 millimeters, for frequencies of a few gigahertz, d and D are substantially 0.9 millimeters and 3 millimeters, finally for frequencies equal to or greater than 10 gigahertz, d and D are substantially 0.45 millimeters and 1.5 millimeters.

  This design of the pads 130 makes it possible to connect the horizontal output tracks arranged parallel to the plane of the printed circuit and the circuit itself.

  The mechanical housing 11 essentially comprises a lower part 110 and an upper part 111.

  It ensures at the same time: the positioning and the maintaining in position of the microwave circuit, also called in English terminology strip line; The positioning and holding in position of the ferrites 14 of the circulator; Positioning and holding in position of pole pieces 17 and permanent magnets 113; Positioning and maintaining in position the thermal compensator 19 intended to ensure the stability of the component; É The mechanical rollover function of the component with looping magnetic field lines.

  Figures 6 and 7 show respectively a top view and a side view of the cavity 9 mounted in the lower part 110 of the housing. The coplanar lines 134 are connected to the cores 131 of the connection pads 130 by means of the connection zones 135. The cores 131 are isolated from the mechanical centralizers 133 by the insulators 132. The centralizers 133 are positioned in the various slides 113 of the lower part. 110 of the housing.

  The height of the cavity 9 slightly exceeds the plane PP represented by a dashed line in FIG. 7 corresponding to the height of the lower part 110 of the housing so that it is kept in compression when the upper part 111 is mounted in the lower part 110.

  The structure chosen for the metal casing 11 is a structure based on pre-formed mechanical claw plates which thus avoid the use of screws, which makes it possible to limit assembly costs. The folded sheet construction also allows a substantial saving compared to a grooved steel case by machining.

  Figures 8 and 9 show the principle of the engagement of the upper portion 111 of the housing in the lower portion 110. The lower portion has a bottom and first flanges 112. The upper portion 111 has a cover and side portions having second flanges 113 which are housed under the first flanges 112. as shown in the detail view circled of Figure 9. The portion 111 is then held in compression between the flanges 112 and the cavity 9 as indicated by the white arrows of the Figure 9. The side portions of the upper portion 111 are thinned at their center so that the upper portion 111 has sufficient flexibility to easily snap into the lower portion 110.

Claims (11)

  An electronic component (10) comprising a mechanical housing (11) and an electronic assembly (9) having at least one electronic circuit (13), and at least two electrical connection pads (130) for providing the electrical interconnection of the component (10) with an external printed circuit, characterized in that the electrical connection pads (130) comprise mechanical means (133) to ensure their precise positioning in the housing (11).   2. Electronic component (10) according to claim 1, characterized in that each stud (130) comprises a conductive central core (131) connected to the electronic circuit, an electrical insulator (132) surrounding said central core (131) and a centralizer mechanical mechanism (133) having positioning means (136).   3. Electronic component (10) according to claim 2, characterized in that the central core (131) has a substantially cylindrical shape, the electrical insulator (132) is an annular sleeve of substantially cylindrical shape and that the mechanical centralizer ( 133) is also an annular sleeve of substantially cylindrical shape, the axes of revolution of the different cylinders being merged.   4. Electronic component according to claim 3, characterized in that the mechanical centralizer (133) comprises at least one groove (136) whose axis is parallel to that of the various cylindrical parts constituting the stud (130) and that the housing ( 11) comprises at least one slide (113) in which the groove is housed.   5. Electronic component (10) according to one of the preceding claims, characterized in that the mechanical housing (11) essentially comprises a lower part (110) and an upper part (111), the upper part being clipped. in the lower part by coupling means (112, 113), the electronic assembly (9) being held in tension between these two parts.   6. Electronic component (10) according to claim 5, characterized in that the lower (110) and upper (111) of the housing are made of folded sheet.   7. Electronic component (10) according to one of the preceding claims 10, characterized in that the electronic assembly (9) operates in the microwave range.   8. Electronic component (10) according to claim 7, characterized in that the component is a circulator or a microwave isolator.   9. Electronic component (10) according to one of claims 7 or 8, characterized in that the core (131), the insulator (132) and the mechanical center (133) of the stud (130) are arranged so to ensure continuity of impedance between the coplanar lines of the electronic circuit and the conductive lines of the external printed circuit.   10. Electronic component according to claim 9, characterized in that, if Er is the electrical permittivity of the insulator (132), D its outer diameter, d its internal diameter, then the impedance Zc of the 138 iD connection pad (130) is substantially: Z (. = - Log \ d 11. Electronic component according to claim 10, characterized in that the ratio of the outer diameter D of the electrical insulator (132) to its internal diameter d is substantially 3 and that said external diameter D is between 1.5 millimeters and 5 millimeters and said internal diameter d is between 0.45 millimeters and 1.5 millimeters.