DE9100042U1 - Adjustable electrical coil - Google Patents

Description

Description

&bgr; Tunable electrical coils

8 The invention relates to an adjustable electrical coil, e.g. a

β line resonator, an electrical filter or the like.

11 Such adjustable electrical coils are part of a

12 resonance circuit 115, whose frequency can be set to a certain value,

13 is supposed to be "adjustable". Without mechanical intervention in the

14 Resonance circuit 115, i.e. without changing the number of turns of the

15 resonance coil 114, namely a coil present in the resonance circuit 115, the adjustment is conventionally carried out by changing the relative position of the ferrite i7 (108) with respect to the resonance coil. This change in the

The relative position is conventionally determined by rotating the essentially

The rod-shaped ferrites. Structurally, this is achieved in such a way that the ferrite as

μm threaded bolt. The carrier of the corresponding nut thread,

21 e.g. part of an insulating housing, is also a carrier of the resonance coil

22. The permanent change in position of the ferrite relative to the

23 Resonance coil is adjusted by simply turning the ferrite

24 accomplished.

26 The object of the invention is to determine the change in the ferrite-based

27 Magnetic effects without changing the position of the ferrite 108 compared to the

28 resonance coil 114.

30 The solution is that the change in the ferrite body 108

si outgoing magnetic effects used for adjustment by a

32 the ferrites 108 acting control circuit 113 with a

33 corresponding input frequency, for example with the frequency of a

34 locally received transmitter is achieved. The adjustment of this 3s control circuit 113 is carried out with a diode 102, which is

3β control current coil 101 of the control circuit 113 is connected in parallel.

37 Adjustment effect is achieved by changing the frequency of the input

38 specific control circuit 113. The

January 4, 1991

&igr; variable control voltage is the input frequency of the control circuit

2 superimposed or superimposable.

4 The functionality is now as follows: The input frequency determined

5 Control circuit 113 is adjusted by setting or changing the

β Control voltage for the diode 102 of the control circuit. This changes

7 the ferrite 108 is acted upon by the control circuit 113

β magnetic field. This also increases the magnetic field transmitted from the ferrite 108 to the

β resonance coil 114 is changed. This change in the

10 Secondary magnetic field of the ferrite 108 causes the desired adjustment

11 of the resonance or working group 115.

13 It can change the control voltage of the control circuit 113

μm existing diode 102 also automatically according to a certain program

is carried out. It is also possible to use the control circuit 113

ie automatically and automatically a continuous readjustment of the resonance coil

&igr;/ 114 also during ongoing operations. This is in a sense a

is the principle of self-adjustment.

20 In summary, the mechanical rotation of the

21 conventional ferrite screw or ferrite threaded bolt replaced by

22 a stationary ferrite 108, whose force acting on the resonance coil 114

23 Secondary magnetic field by a superimposed magnetic field controlled by a control circuit

24 outgoing primary magnetic field is varied or modified. The measure

25 The variation or modification is adjustable by the control voltage at

26 of the diode 102 present in the control circuit 113, which is used to

27 108 acting control coil 101 is connected in parallel.

2β By programming the control voltage of the diode 102 in the control circuit

so 113 the adjustment in the resonance or working circuit 115

si automated. For example, in a car radio, this can ensure

32 that so-called transmitter migrations, i.e. changes in the

33 Reception frequency of the transmitter in the resonance circuit e.g. processor-controlled

34 can be automatically adjusted by setting a constant frequency

35 is maintained.

37 The subject matter of the invention is illustrated by the figures. They show:

4 January 1991

&igr; Fig. 1 a circuit diagram of the adjustable electrical coil

2 Fig. 2 a suitable form of physical training.

4 The essential electrical functional parts of the subject matter of the invention are

5 a control current coil 101 which creates a magnetic field when energized and

β a parallel-connected coil in the space surrounded by the control current coil,

7 in particular in the control current coil 101 when energized

β; built up magnetic field positioned diode 102. The control current coil 101

The current supplying β can be applied via the contact pieces 103,104. They are

ω the ends of the control current coil 101. The diode 102 is thus

ii the contact pieces 103,104 can be energized.

13 Carrier of the control current coil 101 and the diode 102 surrounded by it is

u an electrical insulation body 107, which due to its mechanical

is strength and its good thermal conductivity preferably made of ceramic

ie exists. Ceramic is also a good heat conductor. However, it is

&igr;? It is also conceivable to manufacture the insulating body 107 from glass.

19 The insulation body is connected to an additional ferrite body 108 to form a

µm composite body 109. Insulation body 107 and ferrite body 108 can

21 can be sintered or glued together. The

22 Ferrite body has the function of a magnetic field amplifier. Ferrite has

23 has a high inductance and permeability. However, it is fragile and

24 Its amplifying effect is temperature dependent. According to the invention, the

25 Insulation body 107 is a ceramic body, the heat dissipation

26. The composite body is thus characterized by the maintenance

27 of a largely constant temperature level of the ferrite body.

28 In addition, it significantly increases its stability and compensates for its 2β fracture sensitivity.

31 The diode 102 is arranged on the side facing away from the ferrite body 108,

32 attached drawing upper outer surface of the insulation body 107

33. It is embedded in the outer surface of the insulating body 107

34. The embedding of the diode is preferably flush with the

35 Outer surface of the insulating body 107.

37 The composite body 109 consisting of insulation body 107 and ferrite body 108 is a

38 elongated support body with at both longitudinal ends

January 4, 1991

&igr; flange-like thickenings 110. The composite body 109 has in

2 essentially the shape of a cuboid with at the longitudinal ends over the

3 cuboid-shaped, protruding longitudinal walls

4 flange ends 111,112. Due to the cuboid shape of the flange ends 111,112

5 the entire component can be easily mounted on circuit boards or similar.

βgr;. The flange ends 111,112 are used as supports for the contact pieces 103-

7 106 for the control current coil 101 and for the resonance or

&bgr; working current passage. In the embodiment, the

s Contact pieces 103-106 on the side of the

io insulation body 107 at the side corners of the flange ends 111,112, i.e. in

π are arranged at the extreme regions of the dimensions of the composite body 109.

12 The contact pieces 103-106 can also be mounted on the ferrite body 108 of the

13 composite body 109 or distributed over both composite body parts.

is The composite body 109 is between its flange ends 111,112 as

The winding carriers for the control current coil 101 and for the resonance or

&igr;? Working coil 114 is formed. In addition, it carries the diode in this area

20 The composite body 109 is characterized by miniaturized dimensions.

21 For example, L = 3.2 mm is the total length. Its flange ends 111,112 have a

22 width B = 1.6 mm and height H = 1.2 mm.

24 After completion, the subject matter of the invention will be processed in accordance with the enclosed

25 Illustration by complete encapsulation by casting in a

26 Insulating material protected against mechanical damage from outside, so

27 that only the contact pieces 103-106 for the control current coil 101 and for the

28 Working Group 115 are accessible from outside.

µ A further advantage of the subject matter of the invention is that it

31 a very similar structure to the motionless relay according to the

32 Utility model application with the internal reference number 901409-1 of

33 Applicant of 21 December 1990 (official reference number still unknown)

34 is feasible. Production can be carried out in a very similar way on the same

35 production machines.

4. Jexjar 19S1

List of reference symbols

101 Control current coil

102 Diode

103 Contact piece

104 Contact piece

105 Contact piece

106 Contact piece

107 Insulation bodies

108 Ferrite bodies

109 composite bodies

110 Thickening

111 Flange end

112 Flange end

113 Control circuit

114 Resonance or working coil

115 Resonance or working group

4.Jmuar1M1

Claims (1)

&igr; 1/24-91003
2 4 January 1991 5 Claims
&bgr; &bgr; 1. Adjustable electrical coil, e.g. line resonator, electrical filter, etc. &bgr; the like with a control circuit (113) and with a control current coil io (101) of the control circuit induced ferrites (108) for balancing a π a resonance or working coil (114) provided with resonance or 12 working circuit (115). The adjustment of the control current coil (101) is contained control circuit (113) is carried out by a control current coil µ (101) parallel connected diode (102) in the control circuit (113). ie 2. The change in the control voltage of the control circuit (113) U Diode (102) is controlled by a processor according to a predetermined program is controllable. 20 3. Adjustable electric coil with a magnetic field when energized 21 building up control current coil (101) and with a 22 connected in parallel. Within the magnetic field is a diode (102) 23, which are connected via contacts (105,106) to a resonance or 24 working circuit. The carrier of the control current coil (101) and 25 of the diode (102) surrounded by it is an electrically insulating body 26 (insulating body (107)), in particular a ceramic or glass body. The 27 Insulating body (107) is paired with an additional ferrite body (108) or has the magnetic properties of a ferrite body (108). µ 4. Insulation body (107) and ferrite body (108) are joined together to form a composite body si (109) are connected to each other. 33 5. Insulation body (107) and ferrite body (108) are sintered together or 34 glued together. 36 6. The insulating body (107) and ferrite body (108) 37 Composite body (109) is designed as an elongated support body with at both longitudinal ends 38 existing flange-like thickenings (110). January 4, 1991 (UrVANi91003-1.TXT) &zgr; 7. The composite body (109) has essentially the shape of a cuboid with 3 at its longitudinal ends protruding beyond the cuboid longitudinal walls 4 cuboid flange ends (111,112). &bgr; 8. The flange ends (111,112) are designed as carriers of contact pieces (103-106) 7 for the control current coil (101) and for the working coil (114). β 9. It is essentially irrelevant whether the contact pieces (103-106) on the ω insulating body (107) or on the ferrite body (108) of the composite body &eegr; (109) are fixed. 13 10. Arrangement of the diode (102) on the side facing away from the ferrite body (108) u Surface of the insulating body (107). is 11. Embedding the diode (102) in an outer surface of the insulating body (107). 18 12. Flush embedding of the diode (102) into a surface or the outer surface of the insulating body (107). 21 13. Between the flange-like thickened ends of the 22 composite body (109) as winding carrier for the control current coil (101) 23 and the working coil (114) and as a carrier for the diode (102). 25 14. Miniaturized dimensions of the composite body (109), e.g. L = 3.2 mm ze total length; dimensions of the flange ends (111,112): B = 1.6 mm width 27 and H = 1.2 mm height. 28 15. Final consolidation of the entire component by complete encapsulation µ (by casting) in an insulating material, so that only the contact pieces 31 (103-106) for the control current coil (101) and for the working current circuit (115) 32 are accessible from outside. January 4, 1991