DE2850290A1 - Transformer with split winding - is used to vary transformer characteristics each part of winding being wound around different core cross=section - Google Patents

Abstract

The transformer has at least one of its windings (16) divided into two parts (22, 24) which are wound around respective parts of the core of differing cross-sectional area. The two winding parts (22, 24) can be wound in the same sense or in opposite senses with the number of turns of at least one of them varied for adjustment of the transformer parameters with the ferromagnetic core being untouched. The electromagnetic characteristics of the transformer may be finely adjusted by varying the number of turns of each winding part, so that the total windings number remains constant. The core (12) may be split into two spaced cylinders (18, 20) lying coaxially, o ne transformer winding (14) wound around both and the other in two parts (22, 24) respectively wound around both core cylinders (18, 20) and only one of them. The transformer can be used as a distributor in community antenna systems.

Description

Trans formator device

The invention relates to a transformer device dit a ferromagnetic Core body on which at least one connection winding is wound.

In the known transformer devices, each of the terminal windings is each wound onto a winding area of uniform core cross-sectional area. To the electromagnetic properties of such a transformer device with the core body unchanged, it is possible to change the number of turns to change at least one connection winding. As the electromagnetic properties but are extremely sensitive to the number of turns (the inductance of a elongated Solenoid, for example, is proportional to the square of the number of turns), it is not possible by changing the number of turns to modify these properties in fine gradations.

In contrast, the object of the invention is to provide a transformer device provide, whose electromagnetic properties are targeted in fine gradations. can be adjusted.

This object is achieved by the inventive feature that at least one of the connection windings has two partial windings, which on two Winding areas of different core cross-sectional area are arranged.

The electromagnetic properties of a transformer device are only relatively weakly dependent on the core cross-sectional areas (the inductance the solenoid coil already mentioned, for example, is only linear from the Cross-sectional area dependent). A fine gradation of the electromagnetic properties can be achieved, for example, by the number of turns of both partial windings changes so that the sum of the number of turns remains constant.

By having the two partial windings of a connection winding in the same direction or winds in opposite directions, you can see a large or small inductance of the connection winding received, which are further graded by corresponding changes in the number of partial windings can be.

According to a feature of the invention, the core body is one inside the other transitional, mutually stepped core sections are formed, which form the winding areas form. This core body has a particularly simple structure and is mechanically stable.

In an advantageous embodiment of the invention, the core body comprises a cylinder body formed with an axial extension, the partial windings a connection winding like a cylinder coil on the cylinder body or on the axial Extension are wound.

In a further embodiment of the invention, the core body comprises a tube core which is provided with a slot, the partial windings of a Connection winding like a toroidal coil on one that extends over the full length of the tube core Winding area or on a leading through the slot, only over one Part of the tube core length extending winding area are wound. Such a Core body is particularly inexpensive to manufacture.

Attaching the partial windings is particularly easy, when the slot is arranged in the axial direction of the tube core and after a The end of the pipe is open.

According to a further advantageous feature of the invention comprises the Core body two, spaced apart core parts, one of the Partial windings of a connection winding are only wound around one of the core parts and the other partial winding around both core parts, enclosing them, or only is wrapped around the other core part.

In the non-winding area between the core parts, a magnetically ineffective intermediate layer can be provided, which is also used as a common Can serve for the core parts. This gives a mechanically stable, simply structured arrangement.

It is advantageous to use tube cores, two-hole cores or for the core parts Use cylinder cores, the latter can also be parts of a frame core.

The effect of a change in the number of turns of the partial windings on the electromagnetic properties of the transformer device can be added by influencing the magnetic properties of the core sections or the core parts, in particular due to different permeability or shear different from each other. This also allows the frequency behavior to be determined electromagnetic properties, such as the inductance of a connection winding, influence.

A particularly strong frequency dependence of the inductance of a Terminal winding is obtained by considering the magnetic properties of the core sections or the core parts so that the induction flux density of one of the core sections or core parts - at low frequency, adjacent to one of the connection windings Voltage in particular in the range from 0 to 100 Hz is greater than that of the other Core section or core part and in the case of high-frequency voltage, especially in the area from 10 to 109 Hz is approximately the same as that of the other core section or Core part.

The inductance of this connection winding at low-frequency voltages is particularly high, only to drop off sharply at higher frequencies when one Core section or one core part in the case of low-frequency voltages essentially of the entire magnetic flux and, in the case of high-frequency voltages, only a part this magnetic flux is penetrated, and if the other core section or the other core part in the case of high-frequency voltages essentially from the rest Part of the magnetic flux is permeated.

If you have the transformer device with a single connection winding provides an inductive resistor with a finely adjustable frequency dependent inductance. Such an inductive resistor can, for example as Frequency crossover can be used to separate HF voltages from LF voltages.

A transformer or transformer with finely adjustable, if desired The frequency-dependent transformation ratio is obtained by using the transformer device executes with two connection windings.

Transformer devices for broadband, directional, directional Transmission of high frequency signals, in particular; special branches or distributors for Community facilities have been known for a long time. These are with an entrance and two outputs are provided which are interconnected with four connection windings, whereby'eine first connection winding connects the input to a first output, a second A third connection winding connects the input to ground second output connects to a resistor connected to ground and a fourth Terminal winding connects the second output to ground, and where the ratio the number of turns of the first and fourth connection winding approximately equal is the ratio of the number of turns of the third and the second connection winding.

A number of requirements are made of such a device, their best possible fulfillment, especially with larger community antenna systems is of great importance. For example, certain attenuation values must be between the input, the first and the second output are complied with and the input and the outputs be adapted to the corresponding supply lines.

There has therefore long been a need to use the electromagnetic Properties of such a transformer device, referred to below as a directional coupler specifically to set a directional coupler that meets the requirements to obtain.

Attempts have already been made to solve this problem to get closer. From DE-AS 24 48 737 a directional coupler with a two-hole core is known, in which to improve the decoupling attenuation and the adaptation different Number of turns of the second and fourth connection winding were specified. The relationship however, the number of turns of the first and fourth connection windings is 1: 9 too different from the ratio of the number of turns of the third and the second Connection winding with 1: 7, so that the directional effect and thus the decoupling between the two outputs is badly deteriorated.

Another directional coupler is known from DE-OS 27 03 258 whose Terminal windings, however, not on a common core body, but on two separate core bodies are wound, their lengths to improve the throughput loss and the return loss are chosen differently. The use of two separate However, the core body complicates the structure of the directional coupler.

By using the directional coupler as a transformer device forms the features according to the invention listed above, receives the possibility of an exact adjustment of the electromagnetic values of the Directional coupler. For example, the one that depends on the ratio of the number of turns Adjust branch damping in extremely fine steps, with one of two partial windings existing connection winding a correspondingly weighted with the core cross-sectional areas, effective winding count can be assigned. Accordingly, also with different Number of turns of the second and fourth connection winding is the ratio of the number of turns the first and fourth connection windings and The relationship the number of turns of the third and the second connection winding are selected so that that you get high coupling loss and return loss at the same time.

Since the inductance of a connection winding is highly dependent on frequency is adjustable, the electromagnetic properties of the directional coupler also set strongly dependent on frequency.

It is advantageous if the two partial windings each have Connection windings through the second connection winding and / or the fourth connection winding are formed. The first connection winding can then go straight through the core body run, which results in low transmission loss.

A simply structured, compact arrangement is obtained when the core body at least two, through the connection windings to form a structural unit having connected core parts. Tube cores are preferably used for these core parts and / or two-hole cores are used.

The invention is illustrated below with reference to the drawing of several exemplary embodiments explained.

Figures 1 - 8 show transformer devices according to the invention, whose core bodies are wound with two connection windings.

In detail: Fig. 1 shows a core body made of two tube cores, which are wound in a first winding manner; Fig. 2 shows a core body made of two Tube cores wound in a second winding manner; 3 shows an in a first winding-way wound frame core; Fig. 4 a frame core wound in a second winding manner; 5 shows a wound, slotted cylinder core; 6 shows a wound cylinder core with an extension; Fig. 7 a wound, slotted tubular core; 8 shows a wound two-hole core; Figures 9a to 12c show transformer devices according to the invention, their Core bodies are each wound with a connection winding, with the with a designated figures, the transformer devices are shown in perspective and in the figures labeled b and c, the magnetic field line distributions at low-frequency resp.

high-frequency voltages are shown in greatly simplified form.

In detail: FIGS. 9a-9c show a wound tubular core with an axial Slot; FIGS. 10a-10c show a wound cylinder core with an extension; Fig. 11a - 11c a cylinder core with an air coil-like winding; Figures 12a-12c wound tube core with circumferential slot.

FIGS. 13-17 show directional couplers according to the invention with various Core bodies.

In detail: FIG. 13 shows a circuit diagram of a directional coupler; 14 shows a directional coupler with four tube cores; 15 shows a directional coupler with two Two-hole cores; 16 shows a directional coupler core body made of three tube cores, and FIG. 17 a directional coupler core body made of a two-hole core and a tubular core.

All transformer devices according to the invention shown in the figures in common is a core body, which is different with two winding areas Core cross-sectional area designed for two partial windings of a connection winding is. The core body either consists of a single cohesive one Part (Fig. 3 - 12c), which can also be rigidly assembled from several individual parts can (Fig. 3 - 5, 12a - 12c) or of several individual parts that are applied by the Connection windings connected to form a compact, sufficiently stable unit (Figures 1, 2 and 14-17).

The two winding areas can be in the direction of the winding axis be arranged one behind the other (Fig. 5 - 11c) or essentially next to one another, so that the core cross-sectional areas are approximately in the same plane (Fig. 1 - 4, 12a - 12c, 14 - 17).

In Fig. 1, a designated 10 transformer device is in Cross-section shown. On a ferromagnetic core body 12 are a first, undivided connection winding 14 and a second, subdivided connection winding 16 wound up. The turns of the first connection winding 14 enclose both tube cores 18 and 20 at the same time; the number of turns N is about 1.5. The wire of the second Terminal winding 16, however, is in a first partial winding 22 once around the second Tubular core 20 looped (number of turns n1 = 1) and then in a second partial winding 24 wound about 1 3/4 times around both tube cores 18 and 20 (number of turns n2 = 1.75).

The ratio of the inductances of the first terminal winding 14 and the second connection winding 76 can be set in a finely graduated manner, since the inductance of the second connection winding 16 is finely adjustable. This lies because the inductance of a coil arrangement only essentially depends less on the core cross-sectional area than on the number of turns (The inductance of a solenoid depends on the square of the number of turns, however only linearly from the cross-sectional area). For example, if you're one for both Tube cores 18 and 20 wound by one only around the second tube core 20 wound turns replaced (i.e. n2 decreased by 1 and n1 increased by 1), reduced one is the cross-sectional area of this turn, which is initially the sum of the cross-sectional area 2 of the first tube core 18 and the cross-sectional area 23 of the second tube core 20 consisted of the cross-sectional area 23, the total number of turns n1 + n2 unchanged remain.

The transformer device 10 can be used as a transformer or transmitter are designated. In the case of a conventional transformer, in which practically the total magnetic flux traverses both terminal windings is the ratio of on the voltages applied to the connection windings are equal to the unloaded transformer the transmission ratio, the latter being the ratio of the number of turns is defined. In the transformer device 10 described above however, the partial winding 22 of the second terminal winding 16 is only part of it permeated by the entire magnetic flux. One of the second connection winding The effective number of turns N 'assigned to 16 is therefore smaller than the total number of turns be n1 + n2.

By choosing the number of turns n1 and n2 and the cross-sectional areas accordingly 21 and 23, the effective number of turns N 'can be set and finely graduated. thus also the transmission ratio N to N '.

The clear distance a between the two tube cores 18 and 20 is dimensioned such that the between the two tube cores 18 and 20 guided turns (in Fig. 1, the piece of wire 26) just have space. The first Partial winding 2-2 is wound in the same way as the second partial winding 24 (Arrows in Fig. 1). The total inductance of the second connection winding 16 results therefore as the sum of the inductances of the first partial winding 22 and the second Part winding 24 plus a portion that is proportional to the mutual inductance between two partial windings 22 and 24 is. If the winding is in the opposite direction, however, it is subtract the part proportional to the mutual inductance.

Fig. 2 shows a transformer device 10 'in which the already in the transformer device 10 used core body 12 in a different way a second connection winding 16 'is wound. A first partial winding 22 'of this second connection winding 16 'is also only looped around the second tubular core 20; however, a second partial winding 24 'does not wrap around both tube cores 18 and 20, but only the first tubular core 18. The inductance of the second partial winding 24 'is therefore correspondingly lower and closer to the inductance of the first partial winding 22 'comparable. A change in the number of turns n11 and n2 'while the number of turns is constant therefore leads to a somewhat more gradual change in the total inductance the second connection winding 16 '.

In Fig. 3, a transformer device 40 is shown, whose Core body is formed by a frame core 42. This consists of a U-part 44 with a middle part 46 and legs protruding at both ends at right angles 48. The legs 48 are formed by two transverse parts 50 and 50 parallel to the central part 46 52 connected, of which a first transverse part 52 in the area the free Ends of the legs 48 is arranged and the second transverse part 50 at a small distance b runs from the first transverse part 52 between the latter and the central part 46. A first Terminal winding 54 is looped around the central part 46 .. A second terminal winding 56 is wound around both transverse parts 50 and 52, with a first partial winding 62 only wraps around the first transverse part 52; while a second partial winding 64 is wound around both cross members 50 and 52 at the same time. Accordingly, the Core cross-sectional area of the first partial winding 62 equal to the rectangular cross-section of the first transverse part 52, whereas the core cross-sectional area of the second partial winding 64 equal to the sum of the rectangular cross-sectional areas of the two transverse parts 50 and 52 is.

The clear distance b between the two transverse parts 50 and 52 is dimensioned so that the first partial winding 62 is located in between.

While the cross-sectional areas of the cross members 50 and 52- of the frame core 42 in Fig. 3 are approximately the same size and therefore a somewhat coarse gradation the total induction of the second terminal winding 56 when changing the. Number of turns is obtained, is the otherwise identically constructed frame core 42 'of the transformer device shown in FIG 40 'with different cross-sectional areas of the corresponding transverse parts 50' and 52 'formed The first connection winding 54' is not here on the middle part 46 'of the U-part 44', but wound onto the second transverse part 50 '.

Here, too, the first partial winding 62 'is only around the first transverse part 52 ', while the second partial winding 64' includes only the second transverse part 50 '.

In Fig. 5, a transformer device 70 is shown with a cylindrical core body 72, which in the region of its center by a longitudinal slot 74 is enforced.

The core body 72 itself consists of two ferromagnetic cylinder parts 78 and 80, which are arranged parallel to one another at a distance c from one another are and thereby 'surface on the main surfaces of two intermediate layer parts 85 and 87 issue. The intermediate layer parts 85 and 87 of a thickness c are in the axial direction arranged at a clear distance d from one another and delimit the slot 74 in the axial direction. The cylinder parts 78 and 80 are integral with the interlayer parts 85 and 87th. For example, connected by flat bonding, so that the core body 72 forms a stable unit.

The cross-sectional areas 81 and 83 of the cylinder parts 78 and 80 are circular segment with parallel tendons.

On the core body 72 is above the slot 74 (see Fig. 5) a first terminal winding 84 is wound which includes both cylinder parts 78 and 80. A second connection winding 86 is divided into two partial windings, one of which a first partial winding 92 on the core body 72 below the slot 74, both Cylinder parts 78 and 80 is wound around and the second part winding only the cylinder part 80 encloses in the region of the slot 74. How changes the number of turns of the partial windings 92 and 94 affect the inductance, is basically already in connection with the transformer devices 10 and 10 'treated in the foregoing.

In Fig. 6, a further transformer device 100 is shown, whose circular cylindrical core body 102 has an axial extension 105 with a circular segment Has cross-sectional area 103. The extension 105 can, for example, by grinding out a corner region 107 can be produced inexpensively. A first connection winding 104 is on the lower. Part (see Fig. 6) of the cylindrical Core body 102 wrapped. A second terminal winding 106 is with a first partial winding 112 wound onto the cylindrical core body 102 below the corner area 107 and wound onto the extension 105 with a second partial winding 114. The core cross-sectional areas both partial windings 112 and 114 are therefore of different sizes.

In Fig. 7, a transformer device 120 is shown, which also can be used as part of a directional coupler. As the core body 122 is here a tubular core is provided, currently provided with a stepped longitudinal slot 125, which runs from the upper edge to approximately the middle of the length of the tube core 122. A first Terminal winding 124 is straight to form a straight pipe core 122 which runs axially through it Head degenerate with an insulating tube 127 to fix its position within of the tube core 122 is sheathed.

A second connection winding 126 has two sub-windings 132 and 134 wound around the jacket of the tube core 122 in the manner of an annular coil. The first partial winding 132 wraps around the jacket of the tube core 122 in its full length, while the second partial winding 134 is passed through the slot 125 and there on a step 129 rests. The step 129 has a semicircular recess 131 for fixing the position of the winding 134 is provided.

Due to the width of the slot 125, the second partial winding 134 can be easily adjusted. As can be seen from FIG. 7, the core cross-sectional area is of the second partial winding 134 corresponding to the configuration of the slot 125 is smaller than the core cross-sectional area of the first partial winding 132. When in the slot 125 provides further steps in the manner of a staircase (not shown in FIG. 7), one has several winding areas with different windings for the second partial winding 134 Core cross-sectional area to choose from.

Finally, FIG. 8 shows a transformer device 140 whose Core body is formed by a two-hole core 142. The two-hole core 142 is cylindrical with an approximately oval cross-section and is supported by two side by side, for Cylinder axis parallel round holes 145 and 147-interspersed. A first connection winding 144 runs through both round holes 145 and 147 and encloses the between Area 149 located these round holes 145 and 147.

A second connection winding 146 is surrounded by a first partial winding 152 also the area 149 between the round holes 145 and 147, with a second Partial winding 154, however, exclusively between the round hole 147 and the outer circumference 161 area 163.

In the following, using the example of particularly simple transformer devices, namely those with only a single connection winding are shown how to by dividing this connection winding into different part windings Core cross-sectional areas can achieve that the inductance of the connection winding at low-frequency voltages is relatively high, and then at increasing frequencies to fall off rapidly.

A transformer device 310 is shown in FIGS. 9a-9c, which differs from the transformer device 120 shown in FIG. 7 essentially differs in that only a single connection winding 326 is provided here is whose first partial winding 332 with a number of turns w1 on the tubular core 322 is wound in its full length and the second partial winding 334 with a Number of turns w2, running through a slot 325 for only part of the length of the tube core 322 is wound.

If you apply a low frequency to the connection winding 326 tension in the range between 0 and 100 Hz, this induces a magnetic field, its Magnetic field line distribution is given in Fig. 9b. You can see that the magnetic field lines 311 due to the high low frequency permeability of the core body material on its run all the way within the tube core 322. Both partial windings 332 and 334 should be traversed by magnetic field lines 311, the density of the magnetic field lines (Induction flux density) of the partial winding 334 due to its smaller core cross-sectional area is greater than the density of the magnetic field lines of the partial winding 332. With increasing frequency the applied voltage decreases the permeability, so that the magnetic field lines 311 in the region of the slot 325 more and more along the shortest path, i.e. across through slot 325. At high frequencies in the range between 106 and 9 Hz, the homogeneous magnetic field line distribution shown in FIG. 9c occurs. While the partial winding 332 still surrounds all magnetic field lines, run through the partial winding 334 corresponding to its smaller core cross-sectional area only a part of the magnetic field lines.

The inductance of the partial winding 334 drops sharply as a result. Man thus receives a component whose inductance is high at low frequencies and falls rapidly with increasing frequency.

A transformer device 400 is shown in FIGS. 10a-19c, ' which differs from the transformer device 100 in FIG. 6 only in that that only a single connection winding 406 is provided here. The circular cylindrical Core body 402 is wound with a first partial winding 412; an axial extension 405 is wound with a second partial winding 414. At low frequencies, to the Terminal winding 406 applied voltages results in a magnetic field line distribution corresponding Figure 10b. Due to the great low frequency permeability pass through all magnetic field lines 411 both partial windings 412 and 414, the Magnetic field line density in the partial winding 414 due to its smaller core cross-sectional area is correspondingly larger. The stray magnetic field emanating from the upper face 409 emerges next to the extension 405, can still be neglected. Growing with However, the frequency of the applied voltage increases this stray field; at high frequencies the magnetic field line distribution shown in FIG. 10c results. Since the partial winding 414 is only penetrated by a part of the magnetic field lines, is the inductance of the partial winding 414 and thus the total inductance of the connection winding 406 is high degraded.

Another transformer device 500 is shown in FIGS.

lla-llc shown. A circular cylinder core 502 is provided with a connection winding 506. A partial winding 514 of the connection winding 506 is wound on the circumference of the lower part of the cylinder core 502 or with a small spacing. A partial winding 512 also surrounds the cylinder core 502, but with air-coil-like windings, the diameter of which is a multiple of the cylinder core diameter. At low frequencies of the applied voltage, all magnetic field lines run through the cylinder core 502 and therefore penetrate both partial coils 512 and 514. At high frequencies, on the other hand, magnetic field lines 511 'separate and circle exclusively around the turns of the partial winding 512 without penetrating the cylinder core 502. The inductance of the partial winding 514 and thus the total inductance is correspondingly reduced. Indicating partial winding 512, a further cylinder core 502 '(shown in dashed lines in Fig. 11a) can be used, which is magnetically decoupled from the cylinder core 502 (no ferromagnetic connecting parts between the two cylinder cores 502 and 502') and whose permeability is lower than that of the At lower frequencies, the magnetic field lines run essentially exclusively through the cylinder core 502 with the greater permeability, so that a magnetic field line distribution similar to that shown in FIG. 11b is obtained. At high frequencies, on the other hand, some of the field lines split off and exclusively surround the turns of the partial winding 512, whereby they also run through the cylinder core 502 '. A magnetic field line distribution similar to FIG. 11c is the result.

A transformer device 600 is shown in FIGS. 12a-12c, the core body of which is formed by a slotted tubular core 602. In contrast The slot 625 here runs parallel to the tube cores 122 and 322 of FIGS. 7 and 9a to a circumference of the pipe core 602. The pipe core 602 is composed of two attached to each other adjacent ferromagnetic parts 618 and 620, the slot 625 in the circumferential direction and in the axial direction downwards (see Fig. 12a) from the part 618 and is limited in the axial direction upwards by part 620. The circular one For this purpose, part 618 is provided with a recess 61 9 that is open at the top. These Recess 619 becomes circular ring-shaped at the top, forming slot 625 Part 620 covered. A terminal winding 606 is toroidally coiled on the pipe core 602 wound, with a first partial winding 612 the tubular core 602 on its full Length encloses, a second partial winding 614, however, runs through the slot 625 and only encloses the upper part 620. The permeability of this part 620 is greater than the permeability of the lower part 618, so that at low frequencies essentially all magnetic field lines 611 run through the upper part 620 (see Fig. 12b). Both partial windings 612 and 614 enclose the part 620 and thus all of them Field lines. At high frequencies, on the other hand, some split again Magnetic field lines 611 'and pass through the lower part 618. So while the connection winding 612 still enclosing all magnetic field lines, only a part of the magnetic field lines lead through the connection winding 612, so that its inductance drops accordingly.

The transformer devices 310 shown in FIGS. 9a-12c, 400, 500 and 600 have in common that one of the connection windings around a narrow point is wound in the core body of these transformer devices and that the permeability of the core material in the area of this constriction is so high that the entire magnetic Flow at low frequencies passes through this bottleneck.

The other partial winding also encloses the whole Magnetic flux, so that the total inductance of the corresponding terminal winding is particularly is high.

As the frequency of the applied voltage increases, the permeability-des decreases Core body material; the tendency of the magnetic field to be distributed homogeneously in space grows accordingly, so that more and more magnetic field lines emerge from the narrow point and thus step out of the partial winding surrounding the constriction. Die inductance this partial winding and subsequently the total inductance of the corresponding connection winding correspondingly decreases rapidly.

The following is an application of the inventive concept to directional couplers treated.

In Fig. 13 is a circuit diagram of a directional coupler is provided. The high-frequency signals applied to an input 200 should be as unattenuated as possible, -th. with low transmission loss to a first output 2Q2, where a throughv is the tap loss defined energy share to be delivered to a second output 204 (branch). Signals at the input 200 or at one of the two outputs 202 or 204 should be fed into the Directional couplers are delivered as largely as possible to the other connections; the The energy of the signal emerging again at the feed connection should be as low as possible i.e. a high return loss is desirable.

These goals can be achieved in principle with the circuit shown in FIG achieve, however, in practice it comes down to the inductances to achieve a optimal behavior of the directional coupler. There are four connection windings intended.

A first terminal winding 206 connects with a number of turns W1 the input 200 with the first output '202.

It is usually in a straight line through a core body 208 of the Directional coupler out to keep the transmission loss low. A second Terminal winding 210 with a number of turns w2 connects input 200 to one Ground connection 212, to which also a fourth connection winding coming from the second connection 204 214 is connected with a number of turns w4. Finally, a third connects Terminal winding 216 connects the second output 204 with one connected to ground Resistor 218. By the ratio of the number of turns w1 to W4 is essentially the branch attenuation is determined.

To reduce the coupling attenuation between the two outputs 202 'and 204 To keep it low, it is necessary to keep the ratio w1 to w4 approximately equal to that To make ratio w3 to w2. In the foregoing, the possibility was described Adjust inductances finely graduated.

One of two partial windings with different core cross-sectional areas existing connection winding can be assigned an effective number of turns. Man can therefore also turn number ratios and thus branch losses in one set fine grid. You can also see the difference between the number of turns Determine w2 and w4 so that the ratio w1 to w4 matches the ratio w3 to W2 is and results in the best possible adaptation and / or directional attenuation.

14 shows a directional coupler 220 whose core body 221 is formed from four individual tube cores 222, 224j 226 and 228, which are with each other parallel axes are arranged in the corners of a rectangle such that the axes of tube cores 222 and 224 (and those of tube cores 226 and 228) coincide. the first terminal winding 206 runs in a straight line through cores 222 and 224. The fourth Terminal winding 214 wraps around with a first partial winding 234 exclusively the tube core 224 and, with a second partial winding 232, both tube cores at the same time 222 and 224.

The winding of the tube cores 226 and 228 is symmetrical to that of the Tube cores 222 and 224. The two tube cores 226 and 228 are from the third connection line Go through 216 in a straight line. The second connection winding 210 is in a first, the tubular core 226 wrapped around partial winding 224 and in a second, both tubular cores 226 and 228 looping partial winding 242 divided. As can be seen in Fig. 14, the number of turns w2 and W4 are the same.

However, you can improve the return loss and / or the Directional attenuation increase the number of turns w2 of the second connection winding 210, wherein the number of turns of the partial windings 242 and 244 is determined in such a way that with the resulting effective number of turns w2 the number of turns ratios w1 to w4 and w2 approximately coincide with w3.

15 is a second embodiment 250 of a directional coupler shown, the core body 251 of two, axially arranged one behind the other two-hole cores 252 and 254 exists. The directional coupler 250 is of the same type like the directional coupler 220. If you slide the tube cores 222 and 228 and the tube cores 224 and 226 together in the direction of the arrow in FIG one of FIG. 15 corresponding arrangement.

The directional coupler 250 is distinguished by its particular robustness.

In FIGS. 16 and 17, two further Kerribodies 261 and 271 are shown, the connection windings being omitted for the sake of simplicity. The core body 261 in Fig. 16 consists of an elongated tubular core 262 and two, adjacent to the tubular core 262 and tube cores 264 and 266 arranged axially one behind the other. The total length the arrangement of the two tube cores 264 and 266 corresponds to the total length of the tube core 262. The individual numbers of turns w1 to w4 of the individual connection windings 206, 210, 214 and 216 are chosen so that only the fourth connection winding 214 is in partial windings 232, 234 must be subdivided, which wind up on the two tube cores 264 and 266 are.

The pipe core 271 in Fig. 17 consists of a two-hole core 272 and a tube core arranged as an extension of a tube axis next to the two-hole core 272 274. Here, too, only the fourth connection winding 214 is subdivided and with one of its partial windings 232, 234 is wound onto the tubular core 274.

The winding areas of the core body shown in the figures which the two partial windings of a connection winding are wound, differentiate in their core cross-sectional areas: In addition, they can also be in material properties differentiate. In this way, core parts with different initial permeability can be used will. In addition, you can use core parts, the permeability of which is different Has frequency behavior, as in the example of transformer devices with a single connection winding (Fig. 9a-12c) was carried out. If you have another Add connection winding to get a transformer or transformer, as this was treated with reference to FIGS. 1-8, is a component with a frequency-dependent Gear ratio the result. Accordingly, one can use a directional coupler build whose transmission range is frequency-dependent in a desired manner is set.

L e r s e i t e

Claims (1)

P a t e n t a n s p r ü c h e 1. Transformer device with a ferromagnetic core body on which at least one connection winding is wound is, characterized in that at least one of the connection windings (16, 16 ', 56, 56 '86, 106, 126, 146) two partial windings (22, 24; 22', 24 '; 62, 64; 62', 64 '; 92, 94; 112, 114; 132, 134; 152, 154), which on two winding areas different core cross-sectional area (21, 23; 81, 83) are arranged. 2. Transformer device according to claim 1, characterized in that; that the two partial windings (22, 24; 22 ', 24'; 62, 64; 62 ', 64'; 92, 94; 112, 114; 132, 134; 152, 154) a connection winding (16, 16 ', 56, 56', 86, 106, 126, 146) are wound in the same direction. 3. Transformer device according to claim 1, characterized in that that the two partial windings of a connection winding are wound in opposite directions. 4. Transformer device according to one of the preceding claims, characterized in that the core body (102, 122) with merging, mutually stepped core sections is formed, which are the winding areas form. 5. Transformer device according to claim 4, characterized in that that the core body is a cylindrical body formed with an axial extension (105S (102) and that the partial windings (112, 114) of the connection winding (1o6) like a cylinder coil are wound on the cylinder body (102) or the axial extension (105). 6. Transformer device according to claim 4, characterized in that that the core body comprises a tubular core (122) which is provided with a slot (125) and that the partial windings (132, 134) of a connecting winding (126) are like a toroidal coil to a winding area extending over the full length of the pipe or on one through the slot (125) leading to only one Part of the tube length extending winding area are wound. 7. Transformer device according to claim 6, characterized in that that the slot (125) is arranged in the axial direction of the tube core (122) and is open towards one end of the pipe. 8. Transformer device according to claim 6, characterized in that that the slot (625) is arranged in the circumferential direction of the tube core (602). 9. Transformer device according to one of claims 1 to 3, characterized characterized in that the core body (12, (12 ', 42, 42', 72, 142) two core parts (18, 20; 18 ', 20'; 50, 52; 50 ', 52' .; 81, 83; 143, 163) comprises that one of the partial windings (22, 22 ', 62, 62', 94, 154) of a connection winding (16, 16 ', 56, 56', 86, 146) only by one of the core parts (20, 20 ', 52, 52', 83, 163) is wound and that the other partial winding (24, 24 ', 64, 64', 92, 152) around both core parts (18, 20; 50, 52; 81, 83), enclosing them, or just wrapped around the other core part (18, 50 ', 149). 10. Transformer device according to claim 9, characterized in that that in a winding-free area (74) between the core parts (81, 83) one magnetically ineffective intermediate layer (85, 87) is provided. 11. Transformer device according to claim 1o, characterized in that that the intermediate layer (85, 87) as a common carrier for the core parts (81, 83) is trained. 12. Transformer device according to claim 8 and one of the claims 9 to 11, characterized in that in the axial direction of the tube core (602) on both sides of the slot (625) arranged ring sections (618, 620) of the tube core (602) - are designed as the core parts on which the partial windings (512, 614) are wound like a toroidal coil. 13. Transformatorv'orrichtung according to any one of claims 9 to 11, characterized characterized in that the core parts as tubular cores arranged coaxially one behind the other (18, 20) are formed on which the partial windings (22, 24; 22 ', 24') like a ring coil are wrapped. 14. Transformer device according to one of claims 9 to 11, characterized characterized in that the core parts as cylinder cores arranged parallel to one another (50, 52; 50 ', 52'; 81, 83) are formed on which the partial windings (62, 64; 62 ', 64'; 92, 94) are wound like a cylinder coil. 15. Transformer device according to claim 14, characterized in that that the cylinder cores (50, 52; 50 ', 52') form parts of a frame core (42; 42 '). 16. Transformer device according to one of claims 9 to 11, characterized characterized in that the core body has a multi-hole core, in particular a two-hole core (142) comprises that a partial winding (152) leads through two of the holes (145, 147) and encloses the area (149) located between the two holes (145, 147), and that the other partial winding (154) through only one of the holes (147) and the outer circumference (161) of the multi-hole core (142) located area (163) encloses. 17. Transformer device according to one of the preceding claims, characterized in that the magnetic properties of the core sections or of the core parts, in particular due to different permeability or shear are different. 18. Transformer device according to claim 17, characterized in that that the magnetic properties of the core sections or the core parts such are determined that the induction flux density of one of the core sections or core parts in the case of a lower frequency, one of the connection windings (326, 406, 506, 606) is applied Voltage especially in the range from 0 to 100 Hz is greater than that of the other core section or core part and in particular in the case of high-frequency voltage in the range from 106 to 10 Hz is approximately the same size as that of the other core section or core part. 19. Transformer device according to claim 17 or 18, characterized in that that the one core section or the one core part in the case of low-frequency voltages essentially of the entire magnetic flux and, in the case of high-frequency voltages, only a part of the magnetic flux is penetrated, and that the other core section or the other core parts at high-frequency voltages essentially from the rest of the part the magnetic flux is permeated. 2o. Transformer device according to claim 19, characterized in that that one of the partial windings (334, 414, 514, 614) only on one core part is wound, and that the other partial winding (336, 412, 512, 612) on both core parts, this is wrapped around it. 21. Transformer device according to claim 20, characterized in that that the permeability of one core part is greater than the permeability of the other Core part. 22. Transformer device according to claim 20, characterized in that that the other partial winding (512) is designed like an air coil, the other Core part is completely removed. 23. Transformer device according to one of the preceding claims, characterized in that it is used as an inductive resistor (310, 400, 500, 600) a single connection winding (326, 406, 506, 606) is formed. 24. Transformer device according to one of claims 1 to 22, characterized marked as a transformer (1o, 1o ', 40, 40', 70, 10o, 120, -140) with two connection windings (14, 16; 14 ', 16'; 54, 56; 54 ', 56'; 84, 86; 104, 106; 132, 134; 144, 146) is formed. 25. Transformer device according to one of claims 1 to 22, characterized characterized in that the transformer device for broadband, direction-dependent Transmission of high-frequency signals, especially as a branch or distributor for Community antenna systems are designed with an input (200) and two outputs (202, 204), which in a known manner with four connection windings (206, 210, 214, 2i6) are connected together, with a first connection winding (206) being the input (ovo) connects to a first output (202), a second connection winding (210) connects the input (200) to ground (212), a third connection winding (216) connects the second output (204) to a resistor (218) connected to ground and a fourth connection winding (214) the second output (204) to ground (212) connects, and where the ratio of the number of turns (w1 / w4) of the first and the fourth connection winding (206, 214) approximately equal to the ratio of the number of turns (w3 / w2) of the third and second terminal windings (216, 210). 26. Transformer device according to claims 9 and 25, characterized characterized in that the other partial winding (232) both core parts (222, '224; 252, 254) encloses. 27. Transformer device according to claim 25 or 26, characterized in that that the two partial windings (232, 234; 242, 244) having Connection windings through the second connection winding (210) and / or the fourth Connection winding (214) are formed. 28. Transformer device according to one of claims 25 to 2-7, characterized in that the core body (221, 251, 261, -271) has at least two, connected by the connection windings (2o6, 210, 214, 216) to form a structural unit Core parts (222, 224, 226, 228; 252, 254; 262, 264, 266; 272, 274) comprises 29. Transformer device according to claim 28, characterized in that at least one core part is a tubular core (222, 266, 274) is formed. 30. Transformer device according to claim 29, characterized by three tube cores (262, 264, 266) forming the core body (261). 31. Transformer device according to claim 29, characterized by four tube cores (222, 224, 226, 228) forming the core body (221). 32. Transformer device according to claim 28 or 29, characterized in that that at least one core part is designed as a two-hole core (252; 272). 33. Transformer device according to claim 32, characterized by two two-hole cores (252, 254) forming the core body (251). 34. Transformer device according to claims 29 and 32, characterized characterized in that the core body (271) by a two-hole core (272) and a Tube core (274) is formed.