| JPH08213801 | HIGH FREQUENCY BOARD MOUNT DEVICE |
| NO161770B | 1989-06-12 | |||
| EP0045877A1 | 1982-02-17 | |||
| EP0158876A2 | 1985-10-23 | |||
| DE2945533C2 | 1983-11-03 |
| 1. | A device having a laminar conductive pattern with conductive means and a dielectric, characterized in that the conductive means is supported by a support frame (2) having a window (3) in which one or more, for instance etched conductors (1) of the conductive means are arranged, said conductive means being arranged at one surface of a plate or sheet (11) of a dielectric material or between two such plates or sheets (11, 8). |
| 2. | A device according to claim 1, wherein the conductive means are arranged at one surface of a plate or sheet of dielectric material to form a microstrip circuit, characterized in that the surface of the sheet, which is opposite to the surface, with which the conductive means is engaged, is covered by a metal layer to form a ground plane. |
| 3. | A device according to claim 1, wherein the conductive means (1) is arranged between two plates or sheets (11, 8) of a dielectric material to form a stripline circuit, characterized in that the outer surfaces, which are turned away from said conductive means, of the sheets (11, 8) are covered by metal layers (5, 6) to form ground planes. |
| 4. | A device according to any of claims 13, characterized in that the support frame (2) is made of plastics. |
| 5. | A device according to claim 4, characterized in that the window (3) in the support frame is cut by means of a laser beam or a water jet. |
| 6. | A device according to any of the claims 13, characterized in that stabilizing fingers (4), which project from the support frame (2) into the window (3) , are arranged at suitable distances in order to support the conductor (1) or the conductors. |
| 7. | A device according to any of the claims 13, characterized in that the dielectric is air and that the ground plane or planes are arranged at a certain distance from the conductive means by the use of distance means (7) . |
| 8. | A device according to any of the claims 13, characterized in that said dielectric is made from ceramic material. |
| 9. | A circuit board having a pattern of conductors (1) located adjacent to one side of a dielectric substrate board (11) , SUBSTITUTE SHξET characterized in that said pattern of conductors (1) is located immediately on top of a support frame (2) , which is thin compared to said substrate board, and that the assembly of conductor pattern and support frame (2) is arranged directly on said one side of the substrate board (11) . |
| 10. | A circuit board according to claim 9, characterized in that on its other side, the assembly of conductor (1) pattern and support frame is arranged directly on one side of another substrate board (8) and that the support frame (2) is thin also compared to this support board (8) . |
| 11. | A circuit board according to one of claims 9 10, characterized in that windows (3) or apertures are made in the support frame (2) and that parts of the conductor pattern pass over these windows or apertures. |
| 12. | A circuit board according to one of claims 9 11, characterized in that the side of the substrate or substrates, which is opposite to the side adjacent to said assembly, have a layer of metal arranged thereon and that these metal layers are intended to be connected to a ground or reference potential when the circuit board is used in electronic equipment. SUBSTITUTE SH ETT. |
Field of the invention
The present invention is related to a device comprising laminated conductive patterns and dielectrics which can be selected more freely than what is now possible.
Background of the invention
In the manufacture of electrical circuit boards one usually starts from a laminate of copper foil and plastics. The surfaces of the copper foils are coated with a resist in a certain pattern, which resist may be photosensitive, i.e. a photo¬ resist, or by means of silkscreen printing. Subsequently, the exposed copper surfaces are etched in order to leave a conductive pattern on the surface of the plastics board. In circuits which are to be used at high frequencies, for instance for radio frequencies, often the conductors are arranged on one side of the plastics sheet and a ground plane is located on the other side. The ground plane usually is a metal foil without any patterning and covering the entire side on the plastics sheet, where it is located and it will in use be coupled to ground voltage or some reference voltage. In this way an electric signal in the conductor is inductively coupled to the ground plane and this is called microstrip technique. In the similar way the conductor may be enclosed by plastics and ground planes on both the top side and the bottom side and this is stripline technique. In this way circuit functions, including inductances and capacitances, may be accomplished which can be used for instance in frequency filter structures. The characteristics of these circuits are dependent on the plastics material on which the circuit pattern is arranged. Thus the electromagnetic losses, the dimensional tolerances and the dielectric constant of plastic material are determinative of the characteristics of said circuits and the variations of said characteristics.
In conventional circuit board technique often the characteristics of the dielectric must be adjusted in such a way, that the lamination, often with a high pressure, to a copper foil will be possible. Further, the characteristics of the dielectrics must be such, that the dielectric will be relatively easily manipulated in the process for patterning the
copper coating.
A large problem is that these requirements highly restrict the choice of possible dielectrics, this implying that material having the best possible electrical characteristics often cannot be selected. Another restricting factor in this context is the requirement that the mechanical dimensions of the conductive pattern should not be influenced too much by temperature changes, since this may cause detrimental stresses on the mounting of components and wire elongation effects in the conductors. Finally, the ambition practically always is that the manufacturing costs should be low and thus, the possibility of achieving low manufacturing costs will generally be restricted due to the restricted possibilities of material selection. Summary of the invention
The purpose of the present invention is to eliminate the drawbacks discussed above of the prior art and to provide a device having laminar conductive patterns and dielectric materials which can be selected more freely than before in regard of its binding ability to copper metal.
This purpose is achieved by a device according to claim 1. Thus in the device comprising laminar conductive patterns and a dielectric which can be selected there is a conductive means comprising a support frame of an isolating material and having a window, in or on top of which one or more etched conductors are arranged, said conductive means being arranged at one surface of a sheet of dielectric material or between two such sheets.
The device according to the invention is applicable for both microstrip and stripline circuits.
According to an advantageous further development of the device of the invention the support frame suitably is a thin frame of plastics and the windows in the support frame is suitably cut by means of a laser beam or a water jet.
According to another advantageous embodiment of the device of the invention stabilizing fingers are provided, which project from the support frame into the window and are located at suitable intervals in order to support or fix a conductor or the conductors if they are so long that they are no longer completely stable in shape.
Short description of the figures
An embodiment chosen as an example of a device according to the invention will now be described in more detail with reference to the accompanying drawing in which
Fig. 1 shows a plan view of a conductive means in the device according to the invention,
Fig. 2 shows a cross sectional view of a stripline circuit in the device according to the invention and
Fig. 3 shows a cross sectional view of a microstrip circuit in the device according to the invention,
Fig. 4 shows a cross sectional view of a device having air as a dielectric.
Description of the preferred embodiment
In the figures the thicknesses illustrated of the substrates and the foils are highly exaggerated in order to clarify the invention.
In Fig. 1 an etched conductor 1 is shown, which is laminated to a support frame 2 of thin plastics. In the support frame 2 a window 3 is cut, for instance by means of a laser beam, and the etched conductor 1 extends over or in the window 3. The material of the support frame 2 then will have to exhibit good characteristics in regard of its laminating ability to copper foil or being able to be easily coated with a copper or other conductive metal layer, such as by some deposition method.
If the conductor 1 is so long, that it is not any longer stable in shape, stabilizing fingers 4, which project from the support frame 2 into the window 3, can be arranged at suitable distances in order to support or fix the conductor 1. As is illustrated in the Figure, the window 3 may have an essentially rectangular shape and the strip or band shaped elongated conductor 3 extends centrally over the window 3 from one side of the rectangle to its opposite side, thus the conductor being located in parallel with the other sides of the rectangle constituting the window 3. The stabilizing or support fingers 4 thus project from these other sides of said rectangle, in the case illustrated from the centre of these sides, in a direction essentially perpendicular to said sides. The support fingers 4 may have a uniform width or they may be tapering, as shown, with the narrow end supporting the conductor 1.
In Fig. 2 is illustrated, in a cross sectional view, the
conductive means shown in Fig. 1 of an etched conductor 1 and a support frame 2 , which is clamped or otherwise arranged between two plastic sheets 11, 8. The plastics sheets 11, 8 have metal sheets or foils arranged on top thereof, which may constitute ground planes. The material of the plastics sheets or substrate boards 11, 8 may be chosen to have the best possible electrical characteristics without any consideration of their ability to have a copper or other metal layer coated on their surfaces. The cross sectional view in Fig. 2 corresponds to the central part of Fig. 1, where the fingers 4 support the conductor 1. In Fig. 3 is similarly to Fig. 2 illustrated, in a longitudinal cross sectional view, the conductive means shown in Fig. 1 of an etched conductor 1 and a support frame 2, which is clamped to or otherwise arranged on one side of a plastics sheet 11. The plastics sheet 11 has a metal sheet or foil on the other side and this metal layer may constitute a ground plane.
It is obvious that the device described above may be varied in several ways. Thus, the conductive means may naturally comprise more than one conductor, for instance extending in parallel with the first one and/or with each other, and supported by the same support fingers. In Fig. 2 a stripline circuit is shown and in Fig. 3 a microstrip circuit.
With the device according to the invention it is thus possible to select the material in the dielectric sheets which has the most suitable dielectrical and manufacturing characteristics without the restricting requirement that the dielectric material should be laminatable to a copper foil. Also air can form the dielectric, see Fig * . 4, the ground plane plates 5, 6 in this case being attached to the conductors 1 at a distance, for instance in the shape of thick frames 7 acting as distance means. The dielectric may also be made of ceramic sheets. The distance means 7 may be electrically conducting and in contact with the ground plates 5, 6 to form a closed shielding of the conductor 1.
The clamping means may, as is illustrated in Figs. 3 and 4, comprise screws 9 and nuts 10 tightened to press the various plate shaped parts of the device against each other.
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