DE4143120A1 - Tunable electric coil e.g. line resonator, filter - comprises resonant LC circuit with electronically variable inductor - Google Patents

Abstract

The electric coil comprises an LC circuit (115) with a ferrite-cored inductor (108, 114) incorporating a secondary control winding (101). Application of a dc control current to the secondary winding varies the magnetic flux in the ferrite core, altering the inductance of the primary winding (114), thus changing the natural resonant frequency of the LC circuit. A Variable capacitance diode (102) is connected across the secondary winding. USE/ADVANTAGE - Simple electronic method of varying natural frequency of resonant circuit.

Description

The invention relates to an adjustable electrical coil with the features of the preamble of claim 1. Such matching electrical coils contain a resonant circuit whose frequency is at a certain value adjustable, namely should be adjustable. Without mechanical intervention in the Resonance circuit, d. H. without changing the number of turns one in the reso resonance coil, the adjustment is conventional by changing the relative position of the ferrite with respect to the resonance coil performed. This leads to a change in the inductance of the resonance coil and consequently also to the desired frequency change.

In terms of construction, the rotation is accomplished in such a way that the ferrite acts as a threaded bolt is trained. The carrier of the associated mother thread, e.g. B. Part of a Isoliergehäuses, is simultaneously designed as a carrier of the resonance coil. The permanent change in position of the ferrite relative to the resonance coil is accomplished by screwing the ferrite.

The mechanical adjustment is disadvantageous, however, because it is an additional, while the operation of the adjustable electrical coil is recurring and is therefore an annoying step. In addition, the mechanical adjustment is un exactly. The smallest changes necessary are made with a change of position of the Ferrites not reached. When trying to do so by means of mechanical balancing To compensate for small frequency changes is rather to be expected the deviation increased.

The screw and nut required for the mechanical adjustment winds also cause a higher and therefore very cost-intensive Manufacturing effort of some components of the adjustable electrical coil.

The object of the invention is to change the starting from the ferrite Magnetic effects without changing the position of the ferrite compared to the Reso to be able to make nanzspule.

This object is achieved by the combination of features of claim 1.  

The solution according to the characterizing part of claim 1 consists essentially Chen in that the change in the starting from the ferrite body to Ab Equation used magnetic effect by the generated in the control circuit and changed input frequency is determined. The material of the ferrite body is namely such that a changed input frequency also Permeability of the ferrite body changes. This continues to change the inductance of the resonance coil and thus to the desired changed Resonance frequency. The input frequency is controlled by a circuit applied control voltage determined. That way is the annoying one and inaccurate mechanical adjustment of the electrical coil by an im Comparison to more convenient and more accurate electronic control or Ju station replaced. Since the ferrite body is mounted in a fixed position, there are no longer any formed on him and in the resonance coil carrier. This simplifies the Manufacture of these components and is therefore also time and cost saving.

Another advantage is the significantly enlarged (about a factor of 100) Re resonance frequency spectrum of the resonance circuit. The ferrite body is so ma material that the resonant frequency spectrum of the resonant circuit compared to the input frequency generated with the aid of the control voltage spectrum of the control circuit is many times larger. With the same Circuit can be generated resonance frequencies that previously only by using another circuit with different dimensions Components, e.g. B. with that contained in the control circuit or resonant circuit Capacitance diode and the capacitor.

The change in the control voltage applied to the capacitance diode by A processor is particularly advantageous because setting a suitable one Input frequency thus automatically pre-selected according to a certain program can be taken. So it is when connecting a suitable peripheral Electronics possible, automatically and automatically by the control circuit constant readjustment of the resonance coil even during operation increase. In a way, this is a principle of self-adjustment. At for example, it can be ensured in a car radio that so called transmitter hikes, so changes in the reception frequency of the Transmitter in the resonance circuit are automatically adjusted.

An insulation body and the ferrite body form the control current coil and the resonance coil penetrating and supporting composite body ge  pairs. The ferrite body has the function of a magnetic field amplifier. This is because ferrite has a high inductance and permeability. Because the ferrite body at the same time part of the winding support for the control current coil and is the resonance coil, this has a material and cost saving effect on the otherwise necessarily as a complete composite body to be produced out.

The ferrite body is fragile and its reinforcing effect temperature dependent. However, according to the invention the insulation body is due its mechanical strength and good thermal conductivity Ceramic is produced, so the heat dissipation of the ferrite body will be favorable. The composite body is characterized by the maintenance a largely constant temperature level of the ferrite body. In addition, the ceramic body increases the stability of the composite body and compensates for the fracture sensitivity of the ferrite body.

The adjustable electrical coil contains for connecting electronic Peripheral contact pieces for the control circuit and for the resonance circuit. The contact pieces are on cuboid flange ends of the Composite body. These flange ends have one in comparison to the rest Area of the composite body outstanding construction height. So that's a good one Accessibility of the connections of the adjustable electrical coil to others electronic units and unproblematic contacting ge ensures.

An embedding of the capacitance diode and the capacitor in the insulation body has the advantage that for these components no additional height of the Composite body is required. The construction height is therefore only of the dimensions sionierung of the control current coil and the resonance coil dependent. The insulation body prevents accidental electri by its insulating effect Contacting the control current coil or the resonance coil with the Capacitance diode and the capacitor. It goes without saying that the Capacitance diode and the capacitor are electrically isolated from each other.

The surfaces of the composite body are also very suitable as carriers of Contact tracks or conductor tracks for connecting the capacitor or the Capacitance diode on the contact pieces. So the whole circuit is in or arranged at least directly on the composite body.  

Last but not least, the adjustable electrical coil is characterized by this miniaturizable dimensions. This enables the use of this coil wherever space-saving work is required, e.g. B. on circuit boards in of SMD technology.

An encapsulation of the adjustable electrical coil in a final solidification insulating material provides mechanical protection against damage like electrical contact protection of the coil.

Another advantage of the subject of the invention is that it with a very similar structure to the motionless relay according to Pa Tent registration can be realized with the official file number P 41 39 566.2 is. This allows manufacturing in a very similar way to the same product machines are made.

The subject matter of the invention is explained in more detail with reference to the figures. Show it:

Fig. 1 is a diagram of the trimmable electrical coil,

Fig. 2 is a perspective view of an appropriate physical training form.

The essential electrical functional parts ( Fig. 1) of the subject matter of the invention are the control circuit 113 and the resonant circuit 115 . The control circuit 113 includes an when energized, a magnetic field to be built control current coil 101 and a connected in parallel thereto, positioned in the region surrounded by the control current coil 101 space, in particular in the built-up of the control current coil 101 when current flows through the magnetic field capacitance diode 102nd The current flowing through the control current coil 101 can be applied via the contact pieces 103 , 104 . They are connected to the connections of the control current coil 101 . The capacitance diode 102 can thus also be electrically contacted via the contact pieces 103 , 104 .

The resonance circuit 115 contains the resonance coil 114 and the capacitor 116 connected in parallel therewith. The connections of the resonance coil 114 are connected to the contact pieces 105 , 106 . Likewise, the capacitor 116 is contacted with the contact pieces 105 , 106 via the contact tracks 117 , 118 .

Around the single-layer control current coil 101 there is, as it were, the second layer, the resonance coil 114, which is also wound in one layer.

The carrier of the control current coil 101 and the resonance coil 114 as well as the capacitance diode 102 and capacitor 116 surrounded by them is the composite body 109 containing the insulation body 107 and the ferrite body 108 .

The composite body 109 is an elongated support body with flange-like thickenings 110 present at the two longitudinal ends. The composite body per 109 essentially has the shape of a cuboid with also cuboid flange ends 111 , 112 protruding from the longitudinal ends at the longitudinal ends. Due to the cuboid shape of the flange ends 111 , 112 , the entire component can be mounted easily on printed circuit boards or the like. The flange ends 111 , 112 are designed as carriers for the contact pieces 103 to 106 for the control circuit 113 and the resonant circuit 115 . In the exemplary embodiment, the contact pieces 103 to 106 are arranged on the side of the insulating body 107 facing away from the ferrite body 108 on the side corners of the flange ends 111 , 112 , ie in the extreme regions of the dimensions of the composite body 109 . However, the contact pieces 103 to 106 can also be fixed on the ferrite body 108 of the composite body 109 or distributed on both composite body parts.

The composite body 109 is formed between its flange ends 111 , 112 as a winding carrier for the control current coil 101 and for the resonance coil 114 . In addition, the capacitance diode 102 and the capacitor 116 are arranged in this area on the side facing away from the ferrite body 108 , with respect to the upper outer surface of the insulation body 107 in FIG. 2.

At the flange ends 111 , 112 and on the elongated winding development carrier region of the composite body 109 , the contact tracks 117 , 118 , z. B. by vapor deposition of a conductive layer. The Kontaktbah NEN 117 , 118 connect the contact pieces 105 , 106 to the terminals of the capacitor 116 . The contact tracks 117 , 118 run in directions indicated by H, L, B ( FIG. 2). The composite body 109 is characterized by miniaturized dimensions. For example, L = 3.2 mm is the total length. Its flange ends 111 , 112 have a width B = 1.6 mm and a height H = 1.2 mm.

After completion, the subject of the invention is protected by complete encapsulation by casting in an insulating material against mechanical damage from the outside, so that only the contact pieces 103 to 106 for the control circuit 113 and the resonance circuit 115 are accessible from the outside.

To generate a certain input frequency of the Steuerstromkrei ses 113 , a control voltage is applied to the contact pieces 103 , 104 . The control voltage generates a specific capacitance at the capacitance diode 102 . This capacity is decisive for the input frequency. The ferrite body 108 is made of material such that the input frequency determines its permeability and thus the inductance of the resonance coil 114 . This inductance in turn is decisive for achieving a specific resonance frequency of the resonance circuit 115 . If the inductance of the resonance coil 114 has to be changed during operation in order to balance the resonance circuit 115 , this is done via the changed control voltage. A feedback electronics can, for. B. from the deviation of the resonance circuit 115 from the desired resonance frequency generate the necessary control voltage for adjustment and apply to the control circuit 113 . A processor can also do this work. The relationship between the control voltage and the desired resonance frequency is known.

Reference symbol list

101 control current coil
102 capacitance diode
103 contact piece
104 contact piece
105 contact piece
106 contact piece
107 insulation body
108 ferrite body
109 composite body
110 thickening
111 flange end
112 flange end
113 control circuit
114 resonance coil
115 resonant circuit
116 capacitor
117 contact track
118 contact track

Claims (21)

1. Adjustable electrical coil, e.g. B. line resonator, electrical filter or the like

• a control circuit ( 113 ) containing a control current coil ( 101 ),
• - a resonance circuit ( 115 ) containing a resonance coil ( 114 )
• - And one of the windings of the control current coil ( 101 ) and the resonance coil ( 114 ) passing through ferrite body ( 108 ),

characterized in that the ferrite body ( 108 ) is made of material such that its permeability is determined by the input frequency applied to the control circuit ( 113 ). 2. Adjustable electrical coil according to claim 1, characterized in that the control circuit ( 113 ) consists of the control current coil ( 101 ) and a capacitance diode ( 102 ) connected in parallel therewith. 3. Comparable electrical coil according to claim 2, characterized in that for generating a certain input frequency a control voltage on contact pieces ( 103 , 104 ) for connection to the control circuit ( 113 ) is present. 4. Comparable electrical coil according to claim 3, characterized, that the change in control voltage is controlled by a processor is. 5. Comparable electrical coil according to claim 3 or 4, characterized,  that the adjustable electrical coil is adjusted by means of the control voltage chen and readjusted. 6. Adjustable electrical coil according to claim 1, characterized in that the resonance circuit ( 115 ) consists of the resonance coil ( 114 ) and a capacitor connected in parallel ( 116 ). 7. Comparable electrical coil according to one or more of the preceding claims, characterized in that the carrier of the control current coil ( 101 ) is an electrically insulating body (insulating body ( 107 )), in particular a ceramic or glass body. 8. Comparable electrical coil according to one or more of the preceding claims, characterized in that the insulating body ( 107 ) with the ferrite body ( 108 ) is paired. 9. Comparable electrical coil according to one or more of the preceding claims, characterized in that the insulation body ( 107 ) and the ferrite body ( 108 ) are connected to one another to form a composite body ( 109 ). 10. Comparable electrical coil according to claim 9, characterized in that the insulation body ( 107 ) and the ferrite body ( 108 ) tert aufeinandergesin or glued to each other. 11. Comparable electrical coil according to claim 9, characterized in that the best of the insulating body ( 107 ) and the ferrite body ( 108 ) existing composite body ( 109 ) is formed as an elongated support body with flange-like thickenings ( 110 ) present on both longitudinal ends. 12. Comparable electrical coil according to claim 9, characterized in that the composite body ( 109 ) has essentially the shape of a cuboid with cuboid flange ends ( 111 , 112 ) projecting beyond the cuboid longitudinal walls at its longitudinal ends. 13. Comparable electrical coil according to one or more of the preceding claims, characterized in that the flange ends ( 111 , 112 ) are designed as carriers of contact pieces ( 103-106 ) for the control current coil ( 101 ) and the resonance coil ( 114 ). 14. Comparable electrical coil according to one or more of the preceding claims, characterized in that the contact pieces ( 103-106 ) on the insulating body ( 107 ) or on the ferrite body ( 108 ) of the composite body ( 109 ) are fixed. 15. Comparable electrical coil according to one or more of the preceding claims, characterized in that the connections of the capacitor ( 116 ) via on the composite body by ( 109 ) arranged contact tracks ( 117 , 118 ) with the contact pieces ( 105 , 106 ) contacted are. 16. Comparable electrical coil according to one or more of the preceding claims, characterized by an arrangement of the electrically separate capacitance diode ( 102 ) and the capacitor ( 116 ) on the ferrite body ( 108 ) facing away from the surface of the insulation body ( 107 ). 17. Comparable electrical coil according to one or more of the preceding claims, characterized by embedding the capacitance diode ( 102 ) and the capacitor ( 116 ) in an outer surface of the insulating body ( 107 ). 18. Comparable electrical coil according to one or more of the preceding claims, characterized by a part between the flange-like thickened ends of the composite body ( 109 ) as a winding support for the control current coil ( 101 ) and the resonance coil ( 114 ) and as a carrier for the capacitance diode ( 102 ) and the capacitor ( 116 ). 19. Comparable electrical coil according to one or more of the preceding claims, characterized by miniaturizable dimensions of the composite body ( 109 ) (z. B. L = 3.2 mm total length) and miniaturizable dimensions of the flange ends ( 111 ; 112 ) (B = 1 , 6 mm wide and H = 1.2 mm high). 20. Comparable electrical coil according to one or more of the preceding claims, characterized by a final consolidation of the adjustable electrical coil by complete encapsulation, for. B. by casting in an insulating material so that only the contact pieces ( 103-106 ) for the control current coil ( 101 ) and for the Re sonanzspule ( 114 ) are accessible from the outside.