DE3929514A1 - Miniature inductive component for HF and VHF range - has axis of wound wire vertical to base support of plastics material to allow surface mounting - Google Patents

Abstract

A miniature inductive component comprises a plastics base plate (2) and a hollow body (1), perpendicular to the base plate, which supports a helical wire (3). Flat metal strip contacts (5.2) disposed on the base plate (2) protrude from the components transverse to the axis (A) of the coil (3). A flat metal plate (4) on the base plate (2) between the contacts (5.2) and one end (3.1) of the coil (3) has a curved portion which determines the adjustment resistance of the component. The component is automatically stamped out from a metal bar such that apertures are punched out enabling the length and or breadth of the curved portion, and therefore the impedance value, to be varied. ADVANTAGE - Simple construction. Can be made in totally automatic process. Inexpensive.

Description

The invention relates to an inductive miniature Component for high and very high frequencies with the Features from the preamble of claim 1.

Such a component is for example in the DE-PS 31 46 168 described. The well-known inductive Components of this type have the disadvantage that they are not easily surface mountable.

In modern surface mounting technology, construction elements that are as small and light as possible in particular should be flat. Farther these components should be so simple that they in large numbers at low cost can be produced as far as possible in automatic production.  

Another requirement for such components is that none within the device May be soldered so that e.g. with reflow Soldering the connection is not destroyed.

A miniature inductive component is known (DE-PS 35 10 638) that in a fully automated Process is producible, in which in a band Metal openings are punched, using the Strip-shaped connecting contacts connected to the opening edge stop. On strip sections this connection contacts a core is opened with its end face sticks, then the core is wrapped and covered with an umman overmolded. Finally, the component from Ribbon cut off by cutting off the strip sections from the opening edge.

The Her used in this known component the application procedure is not readily applicable to Components for high and very high frequencies, at for example on so-called helix filters.

The invention has for its object an inductive Miniature component for high and very high frequencies with the features according to the preamble of the patent Say 1 so that it is very simple  is and in a simple way in a fully automated Method can be produced, wherein during the Her position procedure through simple work steps high and very high frequencies extremely critical on position of the adaptation vaccine arranged in the component danz should be possible.

This object is achieved with the invention a component that characterize the features from the has the part of claim 1. Beneficial Further developments of the component according to the invention described in claims 2 to 14.

The invention also relates to methods of manufacture of the device according to the invention, which in the claims 15 to 18 are described.

The basic idea of the invention was that fully automated known from DE-PS 35 10 638 Remodeling procedures in a way that a very simply constructed miniature inductive component arises in which in a particularly simple and automatic during the manufacturing process arranged in the base plate of the finished component neten flat metal strips given matching impedance is adjustable. This is done according to the fiction moderate procedure by putting on the wire helix or at least before embedding the wire helix in the Carrier body, for example by extrusion coating Punching out certain recesses in the metal leaf-limiting bridges a desired adaptation wi the state is reached. This procedure has the meaning Tending advantage that the metal strips or tape  cuts on which the component is built in one for all different matching resistances same basic shape can be manufactured or obtained and only during the manufacturing process it needs to be decided which bridges are be punched and what adjustment resistance with it is set. This is with fully automated Procedures where, if necessary, in close succession Batches of components with very different Properties to be made of great Importance. The inductance of the arcuate Ab cut also affects the adjustment resistance other properties such as bandwidth, transmission loss and selection.

Further possibilities of fully automatic production are due to the very simple structure of the fiction moderate component favored. So through ent speaking measures when molding the cavities between the wire coil and the shielding cup more or less with that representing a dielectric Plastic material to be filled in and thus the Tuning frequency changed within certain limits will. Furthermore, one can easily from above vote through the shielding cup element, for example a tuning screw, so attached be arranged that the voting element more or less near the top of the wire coil. These Capacity change is used for frequency tuning. For this purpose, the structure can be used in a particularly advantageous manner of the component so that the wire coil is always the has the same axial height even with different Length of the electrical wire forming the wire coil ters. This is achieved in that shorter Conductor length the slope of at least one turn of the Wire coil is enlarged. In this way, a great unification of the construction of the construction  elements assigned to different frequency ranges are achieved and the frequency tuning through the change in capacity of the tuning element becomes relative kept the same even though the number of turns of the Wire helix is different. The tuning element can made of metal or a dielectric material consist.

The supporting and fixing the wire coil in the component The carrier body can be used in different ways be designed. With a particularly advantageous off The form of guidance are the wire helix and the ver tied flat metal strips with a plastic mat rial overmolded, so that the base plate and support body are integrally connected. Because that used Plastic material has a certain temperature resistance because of the soldering processes when placing the component on must have a circuit board and also be is supposed to have dielectric properties proved to be advantageous as a plastic material Liquid crystal polymer based on thermoplastic shear, thermotropic fully aromatic polyester to ver apply, which is known per se and for example under the trade name "VECTRA" offered in the trade becomes.

But it is also possible to invent the wire helix component according to the invention within a hollow body to arrange, such as in DE-PS 31 46 168 is described, or a ceramic as a support body to use tubes with a conductor material in Helixform is coated. In this case the Carrier body with the base plate in a different way, for example by gluing or clamping.  

The component according to the invention can be a single-circuit or multi-circuit filter, depending on how many of those from the wire coil, the support body and the base plate existing units in a building element can be summarized. The units are in appropriately designed shield cups summarized and with multi-circuit filters, the coupling between the resonators manufactured in that in the partition walls arranged between the units desired coupling factor appropriate openings be cut. The component according to the invention is preferably for use in the frequency range between 400 to 2000 MHz.

The following are based on the attached drawings two embodiments of an inductive miniature Component according to the invention and the method for Manufacturing explained in more detail.

The drawings show:

Figures 1 and 2 in a plan view a portion of a metal strip for use in building an inductive miniature construction element in two different imple mentation forms.

FIGS. 1.1 and 2.1 show the metal strip according to FIG. 1 and FIG. 2 after punching out the bridges;

Figure 3 is a plan view of an inductive miniature component before placing the shielding cup.

. Fig. 4 is a section through the device of Figure 3 along the line IV-IV;

5 shows a section through the device of Figure 3 along the line VV..;

FIG. 6 shows a representation of the component analogous to FIG. 5 with a shielding cup with a tuning device attached; FIG.

Fig. 6.1, a variant of the tuning according to Fig. 6.

The following is what is shown in the drawings Component described using the manufacturing process ben.

The starting point of the manufacturing process is a for example, metal tape wound on a roll made of a copper-containing alloy.

Fig. 1 shows a portion 7 of the tape, which is provided at its edge with holes 9 for engaging Transportvorrichtun conditions and punched into the openings 8 , wherein within each opening 8 connected to the edge of the opening 8 portions of the tape remain. In the embodiment according to FIG. 1, the remaining portion that occurs twice in each of the openings 8 is composed of a metal sheet 4 , which is connected to the edge of the opening 8 by a total of three strips 5.1 , 5.2 and 5.3 , the strips 5.1 and 5.2 serve as connection contacts in the finished component, while the strip 5.3 only serves to stabilize the holder of the metal sheet 4 . The shape of the metal sheet 4 can be described as a rectangle, from which in the right corner a triangular part D is removed and from which a circular sector-shaped part K is removed, with an arcuate strip section 4.1 joining the rectangle, the inner edge of which follows the contour of the circular sector K and is connected to the contact strip 5.2 . Openings 4.2 , 4.3 , 4.4 , 4.5 and 4.6 are punched into a circular arc parallel to the edge of the circular sector K.

The metal sheet 4 represents the adaptation resistance of the component to be built, the impedance of which depends on the length and width of the arcuate strip section 4.1 . This length can be changed by punching out the bridges between the openings 4.2 to 4.6 . This opens up the possibility, in the manufacture of each component, of the same configuration of the parts 8 of the strip arranged in the opening 8 of the metal strip 7 , in order to then produce the desired matching resistance during a subsequent production step by targeted punching out of the bridges. Fig. 1.1 shows a possible punch. In the next process step, a wire coil is placed on the metal sheet 4 so that its longitudinal axis is perpendicular to the plane of the band 7 . The lower end of the wire coil is connected by a weld 6 or 6.1 - depending on the winding direction of the wire coil - to one end of the arcuate section 4.1 . The wire coil is not shown in Fig. 1. Its design and arrangement can be seen in FIGS. 3 to 6. A slightly different starting point is the metal strip 7 'shown in Fig. 2' with holes 9 'on the edge for transport and openings 8 ', in which punch a metal sheet 4 'after punching out, the contact strips 5.1 ' and 5.2 'with Kon Edge of the opening 8 'is connected. The two parallel to each other, the contact strips 5.1 'and 5.2 ' are connected to each other via arcuate strip sections 4.1 'and 4.3 ', between which there is a crescent-shaped opening 4.2 '. The arcuate strip sections 4.1 'and 4.3 ', which have different widths and lengths, represent the adaptation resistance of the component to be built and are at the same time to be understood as the bridges mentioned above, by punching out the impedance can be changed.

Depending on whether neither of the two strip sections, the strip section 4.1 'or the strip section 4.3 ' is punched out, there is a different impedance value. Fig. 2.1 shows an example of this. In the further course of the manufacturing process, a wire coil with an axis perpendicular to the plane of the band 7 'is placed in this embodiment and with its lower end by means of welded connections 6 ' or 6.1 ', depending on whether there is a right-hand or left-hand coil, on the contact strip 5.2 'or 5.1 ' connected.

The wire coil placed in the two embodiments according to FIG. 1 or FIG. 2 has a predetermined number of windings with the same winding diameter, but under certain circumstances a different pitch, which is dimensioned such that the upper end of the wire coil is always at the same height above the sea level allband 7 or 7 'lies.

The further course of the construction is now shown with reference to FIGS. 3 to 6.

The existing from the metal sheets 4 or 4 'and in Fig. 3 to 6 with reference number 3 wire coils existing units are extrusion-coated in the next manufacturing stage with a plastic material. This material can be, for example, a liquid crystal polymer, which has particularly good thermal and dielectric properties for this purpose. The encapsulation takes place in such a way that, as can be seen from FIGS. 4 and 5, the metal sheet 4 is enclosed in a base plate 2 in such a way that the contact strips 5.1 and 5.2 protrude laterally from the base plate and thus the later component. On the base plate 2 builds up with the base plate 2 integrally connected hollow body 1 , which contains the wire coil 3 completely. As can be seen in FIGS. 4 and 5, the lower end 3.1 of the wire coil 3 is connected to the contact strip 5.2 and the arcuate section 4.1 via a welded connection 6 , as already shown.

It is pointed out that the units composed of the metal sheets 4 , the wire coils 3 , the base plate 2 and the hollow body 1 are still on the belt 7 even after the extrusion coating and are thus fed to a further production station or also wound up on a roll can.

In the next manufacturing step, the units arranged on the belt 7 are provided with shielding cups 10 . In Fig. 6, a single-circuit component is shown with the shielding cup 10 accordingly. The existing within the shielding cup 10 in the form of the hollow body 1 plastic material, which is a Dielek trikum, affects the frequency of the Bauelemen tes, so that by introducing a more or less large proportion of this material, the frequency of the component can be changed within certain limits .

The shielding cup 10 is connected to the base plate 2 via tabs or beads.

In the manufacture of multi-circuit filters several units in a common shielding cup with one chamber each for one unit. At  Multi-circuit components are the coupling produced between the resonators in that in the Partitions cut openings between the units whose size is the desired coupling factor certainly.

In the upper part of the shield cup 10 , a tuning device is provided. In the illustrated Ausführungsbei game of FIG. 6, a guide is provided inside the hollow body 1, in which a metallic From tuning bolt 12, which is connected to the shield cup 10 conductive through a female thread part 11, a threadably that it approaches the upper end the wire helix 3 approaches or moves away from it. The change in capacity caused here leads to frequency tuning.

As shown in Fig. 6.1, the tuning device can also be designed as a circular disk 12 ', which touches the square cross-section from shielding cup 10 on the four inner surfaces and thus makes the conductive connection. The disc 12 'is attached to a bolt 12.1 ', which has a Bolzenge winch which can be screwed into a nut thread in the hollow body 1 , which thus takes over the leadership of this tuning device.

At the upper end of the tuning device there is a recess or opening into which an adjustment tool can be inserted. A corresponding recess or opening is also provided in the tuning device shown in FIG. 6.

The tuning device can also be designed in a manner not shown, for example, that the shielding cup 10 itself has a thread at an axial opening in the upper part, in which a cap-shaped arrangement is guided with the counter thread.

A vote by a cap-shaped arrangement a dielectric material such as ceramic or soldering temperature resistant plastic is also possible.

Claims (18)

1. Inductive miniature component for high and very high frequencies with a wire coil consisting of several turns of the same winding diameter, which is arranged and fixed in or on a carrier body made of electrically insulating material and is connected at least at one end to a connection contact led out of the component , characterized in that the carrier body ( 1 ) is connected to a base plate ( 2 ) made of plastic material such that the axis (A) of the wire helix ( 3 ) is arranged perpendicular to the base plate and each of the connection contacts (consisting of a flat metal strip) 5.1 , 5.2 ) arranged in the base plate ( 2 ) and in the transverse direction to the axis (A) of the wire helix ( 3 ) out of the base plate ( 2 ) and in the base plate ( 2 ) parallel to its base surface a flat metal sheet ( 4 , 4 ') is arranged, which has at least one arcuate section ( 4.1 , 4.1 '), the one end is connected to a Kontaktkon clock ( 5.1 , 5.1 '), while with the other end one end ( 3.1 ) of the wire coil ( 3 ) is connected by a welded connection ( 6 , 6 '). 2. Inductive miniature component according to claim 1, characterized in that the flat metal sheet ( 4 , 4 ') stamped recesses ( 4.2-4.6 , 4.2 ') has, or had before the manufacturing process of the component, which are arranged or were that the length and / or width of the arcuate portion ( 4.1 , 4.1 ') can be changed by punching out bridges delimiting the recesses. 3. Miniature component according to claim 2, characterized in that the recesses ( 4.2-4.6 ) along an edge of the arcuate portion ( 4.1 ) following line on the metal sheet ( 4 ) are arranged, or were. 4. Miniature component according to one of claims 1 to 3, characterized in that the carrier body as a hollow body ( 1 ) is formed from plastic material. 5. Miniature component according to claim 4, characterized in that the carrier body ( 1 ) by extrusion coating the wire helix ( 3 ) with plastic material and is integrally connected to the base plate ( 2 ). 6. Miniature component according to claim 4 or 5, characterized characterized in that the plastic material is a liquid Crystal polymer is used. 7. Miniature component according to one of claims 1 to 6, characterized in that wire helix ( 3 ) and carrier body ( 1 ) are arranged in a metallic shielding cup ( 10 ) which is completed on its underside by the base plate ( 2 ). 8. Miniature component according to claim 7, characterized records that several wire coils and carrier body in a common shielding cup are arranged on the the bottom is completed by the base plates and between the wire coils and the support body existing units metallic, with the shield cup-connected partition walls are arranged in which are provided with coupling openings of a predetermined size are.   9. Miniature component according to claim 7 or 8, characterized in that each wire coil ( 3 ) has a tuning device ( 11-12-12 ' ), as by the shielding cup ( 10 ) in the axial direction to the wire coil ( 3 ) guided and relative to the wire coil ( 3 ) movable tuning element is formed. 10. Miniature component according to claim 9, characterized in that the tuning element as a shield with the shield ( 10 ) conductively connected metallic tuning screw ( 12 ) is formed. 11. Miniature component according to claim 10, characterized in that the tuning screw ( 12 ) is guided in a nut thread arranged in the hollow body ( 1 ). 12. Miniature component according to claim 9, characterized in that the tuning element as a guided in the hollow body ( 1 ), with the shielding cup ( 10 ) conductively connected disc ( 12 ') is formed. 13. Miniature component according to claim 9, characterized records that the tuning element as a cap-shaped Arrangement formed from a dielectric material is. 14. Miniature component according to one of claims 1 to 13, characterized in that the wire coil ( 3 ) has turns of different pitch such that the axial height of the wire coil ( 3 ) remains constant in the case of components with different number of turns of the wire coil ( 3 ). 15. A method for producing an inductive miniature component according to claims 2, 5, 7 and 9, in which a band or band section made of metal is continuously provided with punched openings such that within each opening predetermined band sections are connected to the opening edge remain and the construction of the component is carried out by attaching further components to the remaining band sections in several successive process steps and after completion of the construction the component is separated from the band or band section by punching, characterized by the following further process steps:

• a) The openings ( 8 , 8 ') are punched in such a way that a flat metal sheet ( 4 , 4 ') remains, which has at least one arcuate section ( 4.1 , 4.1 '), of which at least one end with one as a connecting con clock-connecting strips ( 5.1 , 5.1, ) is connected and the recesses ( 4.2-4.6 , 4.2 '), which are arranged so that the length and / or width of the arcuate portion ( 4.1 , 4.1 ') is changeable;
• b) a predetermined number of the bridges limiting the recesses is removed by punching out;
• c) one end of a wire helix ( 3 ) is connected to the other end of the arcuate section by welding ( 6 , 6 ');
• d) the wire helices ( 3 ) and metal sheets ( 4 ) are in each case encapsulated with a plastic material such that each wire helix ( 3 ) is embedded in a hollow body ( 1 ) which is integrally connected to a base plate ( 2 ) such that the axis (A) the wire helix ( 3 ) is arranged perpendicular to the base plate ( 2 );
• e) the units consisting of wire helix ( 3 ) and hollow body ( 1 ) are provided with metallic shielding cups ( 10 ) such that their underside is closed off by the base plates ( 2 );
• f) a tuning device is used in each unit, which is designed as a tuning element ( 12 ) which is guided through the shielding cup ( 10 ) in the axial direction to the wire helix ( 3 ) and can be moved relative to the wire helix.

16. A method for producing an inductive miniature component according to claims 2, 4, 7 and 9, in which a band or band section made of metal is continuously provided with punched openings such that within each opening predetermined band sections are connected to the opening edge remain and the construction of the component is carried out by attaching further components to the remaining band sections in several successive process steps and after completion of the construction the component is separated from the band or band section by punching, characterized by the following further process steps:

• a) the openings are punched in such a way that a flat metal sheet remains, which has at least one arcuate n section, one end of which is connected to a terminal strip serving as a connection contact and which has recesses which are arranged in such a way that by punching out of the recesses limiting bridges the length and / or width of the arcuate section is variable;
• b) a predetermined number of the bridges limiting the recesses is removed by punching out;
• c) one end of a wire helix is connected to the other end of the arcuate section by welding;
• d) the wire coils are each inserted into a hollow body which is assembled from two halves, the plane through the flat contact surface of the halves containing the axis of the wire coil and the wire coil being fixed to the surface of the interior of the hollow body with the aid of ribs formed there and the metal sheets are encapsulated with a plastic material so that a base plate is formed, which is connected to the hollow body such that the axis of the wire helix is arranged perpendicular to the base plate;
• e) which consist of wire helix and hollow body, the units are provided with metal shielding cups in such a way that their underside is completed by the base plates;
• f) a tuning device is used in each unit, which is designed as a tuning element which is guided through the shielding cup in the axial direction to the wire coil and is movable relative to the wire coil.

17. A method for producing an inductive miniature component according to claims 2, 4, 7 and 9, in which a band or band section made of metal is continuously provided with punched openings such that within each opening predetermined band sections are connected to the opening edge remain and the construction of the component is carried out by attaching further components to the remaining band sections in several successive process steps and after completion of the construction the component is separated from the band or band section by punching, characterized by the following further process steps:

• a) The openings are punched in such a way that a flat metal sheet remains, which has at least one arcuate section, of which at least one end is connected to a connecting strip which serves as a terminal contact and which has recesses which are arranged in such a way that they are punched out the length and / or width of the arcuate section can be changed by bridges delimiting the recesses;
• b) a predetermined number of the bridges limiting the recesses is removed by punching out;
• c) a wire helix is applied to a ceramic support body and one end is connected to the other end of the arcuate section by welding;
• d) the metal sheets are in each case encapsulated with a plastic material in such a way that a base plate is formed which is connected to the carrier body in such a way that the axis of the wire helix is arranged perpendicular to the base plate;
• e) the units consisting of wire coils and carrier bodies are provided with metallic shielding cups in such a way that the underside is completed by the base plates;
• f) a tuning device is used in each unit, which is designed as a tuning element which is guided through the shielding cup in the axial direction to the wire coil and is movable relative to the wire coil.

18. The method according to claim 15, 16 or 17, characterized in that the recesses ( 4.2-4.6 ) on the metal sheet ( 4 ) along an edge of the arcuate section ( 4.1 ) following line are arranged.