DE1153081B - Transmission fork with a transformer - Google Patents

Description

GERMAN

PATENT OFFICE

kl. 21a ² 36/03

INTERNATIONAL KL.

H 03h; H 04in

N20064Vffla / 21a ²

REGISTRATION DATE: MAY 18, 1961

NOTICE
THE REGISTRATION
AND ISSUE OF
EDITORIAL: AUGUST 22, 1963

The invention relates to a transmission fork with a transformer, over which two mutually decoupled fork branches are inductively coupled to a common fork branch, z. B. around the two branches of a four-wire line to a two-wire line for feeding two independent To connect loads and the like. Such symmetrical type transmission forks have the The advantage that a center tap of each of the fork branches that are decoupled from one another is grounded can, which, however, their structure is more complex than in the case of transmission forks of the non-symmetrical Type in which only one point of the two fork branches that are decoupled from one another are earthed allowed.

In practice, especially the transformer forks are because of their particularly cheap electrical Properties are generally known, since in this case the fork branches that are decoupled from one another are exactly on the common fork branch can be adapted while the signal transmission in the fork in itself no energy is lost. The transformers used in such transformer forks however, have an intricate structure; namely, they have z. B. five transformer windings with ten outward connecting lines, whereby this type of construction requires special care to the to meet the fork's requirements.

To simplify such a transmission fork, it is already known to provide a transformer with two coupling windings with a winding connected to the common fork branch are inductively coupled, the The ends of the latter winding form the terminals for the common fork branch. In the connection from the ends of the coupling windings to the terminals of the decoupled Fork branches added as a voltage divider switched fork resistors, which with a suitable setting the voltage divider ratios the desired decoupling of the fork branches by means of compensation cause. Together with the desired decoupling of the fork branches, these have voltage dividers however, the result is that there is a significant loss of power in these voltage dividers, the may have to be eliminated by amplifiers.

The invention aims at a novel circuit of a transmission fork with a transformer having two coupling windings and with a decoupling of the two mutually decoupled fork branches by means of fork resistors, which characterized by a simple structure that connects this transmission fork with a transformer

Applicant:

N. V. Philips' Gloeilampenfabrieken, Eindhoven (Netherlands)

Representative: Dipl.-Ing. E. E. Walther, patent attorney, Hamburg 1, Mönckebergstr. 7th

Claimed priority: Netherlands of May 21, 1960 (No. 251 885)

Petrus Cornell's Maria Ahnering,

Hüversum (Netherlands) has been named as the inventor

Transmission fork makes it particularly suitable for the miniature design required in transistor technology and in which the power losses in the transmission fork are largely eliminated.

The transmission fork according to the invention is characterized in that between one end one coupling winding and the corresponding end of the other, identical coupling winding a fork resistor is connected, the value of which is equal to the characteristic impedance of the decoupled Fork branches is, and that the connection terminals for the two decoupled fork branches through the end of one coupling winding and the end of the other coupling winding winding that are not connected to one another by a fork resistance.

The transmission fork according to the invention is explained in more detail below with reference to the figure. The transmission fork of the symmetrical type shown in the figure contains two decoupled fork branches 1, 2 with associated terminals 3, 4 and 5, 6 and a common fork branch 7 with associated terminals 8, 9 which branch by means of a transformer 10 with the two decoupled from one another Fork branches 1, 2 is connected. In the illustrated embodiment, the transmission fork in FIG

309 668/241

a transistorized line amplifier used for carrier-frequency telephone traffic, the line amplifier on the one hand feeding a cable connected to terminals 5, 6 and on the other hand a measuring unit connected to terminals 3, 4. The line amplifier is indicated schematically in the figure by a signal source 11 which has an EMK2Zs and with which a resistor 12 is connected in series, which indicates the internal resistance of the line amplifier. The loads on terminals 3, 4 and 5, 6 created by the cable and the measuring mechanism are created by the resistors 13 and 14, respectively.

To achieve a transmission fork that is particularly favorable in electrical and structural terms the transformer 10 has two identical coupling windings 15,16, which are connected to one of the common Fork branch 7 connected winding 17 are inductively coupled, the ends of which the terminals d i Gbli picture Gäß

and the two coupling windings 15, 16 is the same, the simple relationship applies:

A current I ₀ thus flows through each of the coupling windings 15, 16 , and the voltage across these coupling windings will be 2 E − Z ₀ R.

Despite the connection of the fork resistors 18, 19 in the transmission fork, no losses occur in the transmission fork in the matched state, and the power supplied by the signal source 11 to the transmission fork is divided into equal halves between the load resistors 13, 14, which follows from the following Network analysis can be seen. The current flow through the transmission fork can be determined in a simple manner by assuming that the voltage across the coupling winding 15 in the fork resistor 18 has a current Z ₁ and the voltage across the Koppi d Gblidd

gpp ₁ pg pp

8, 9 form for the common fork branch. According to 20 development winding 16 in the fork resistor 19 one d d hd Ed d S / hf h d

According to the invention, the respective ends of the two identical coupling windings 15, 16 are over each a fork resistor 18 and 19 connected to each other, and the terminals 3, 4 and 5, 6 for the two decoupled fork branches 1, 2 are each connected by one end of a coupling winding 15 and one end of the other coupling winding 16 is formed which is not through a fork resistor 18 or 19 are connected to each other. These fork resistors 18, 19 are practically equal in value the wave resistance of the decoupled fork branches 1, 2 made. Without further ado you can in this Circuit the centers of the load resistors 13 and 14 are connected to earth at the same time.

In the usual operating state of the transmission fork, each of the fork branches 1, 2, which are decoupled from one another, is loaded by a load resistor 13 or 14, which is equal to the characteristic impedance R. As a result, each of the resistors 18, 19, 13, 14 of the fork is equal in value to the characteristic impedance, the signal source 11 with the internal resistance 12 being adapted to the load translated by the transmission fork. that is, the internal resistance 12 of the signal source 11 is equal to the load formed by the transmission fork, which can always be achieved by a suitable choice of the transmission ratio of the winding 17 and the two coupling windings 15, 16. If the internal resistance 12 of the signal source z. B. ¹ hR, the transmission ratio 1: 1: 1 should be selected to adapt the load.

If in this state the EMF of the signal source 11 by 2Zi and that by the internal resistance 12 flowing current is denoted by Z, occurs across the winding 17 a voltage of

which, since the transformation ratio is equal to 1: 1: 1, thus also the voltage across the coupling windings 15, 16 represents. Because of the symmetry of the transmission fork, the currents are through the two Coupling windings 15, 16 equal to each other and b B Z ih d d

Causes current / ₂ , while the current through the load resistor is 13 Z ₃ . In the figure, the direction of the various currents is indicated by the arrows.

The following equations can be written for the following circles to determine the currents I ₁ , Z ₂ and Z _3:

Circle: coupling winding 15, load resistor 14, fork resistor 18, coupling winding 15:

- Zl ₁ K

I ₂ K

I ₃ K

(111)

Circle: coupling winding 16, fork resistor 19, load resistor 14, coupling winding 16:

_ _
I ₀ K- Zl ₂

I ₁ K

Circle:
booth 13,
booth 16:

Coupling winding 16, fork resistor 18,

(IV)

Load counter coupling counter 2E
^Further

I R = 21 rows

I R,

(V)

T - T h ~ h

-1 /

+ h

From these equations it is deduced that

No. ₁

7 = 0

2 ->

β
Z ₃ = ■■ -

(VII)

(VUl)

(IX)

Thus, the fork resistors 18, 19 are not traversed by current, so that no power is lost in these resistors 18, 19, while each of the load resistors 13, 14 is traversed by a current that is equal to EIR and corresponding to a power E ² ZR , ie exactly half of the power delivered by the signal source 11 to the fork; namely, this power is equal to the voltage across the winding 17 (2Zs- I _e R); multiplied by the current 2 Z ₀ flowing through this winding 17 and thus equal to 2E ² JR. The via id d

pg g

amount to z. B. Z ₀ , and between these currents Z ₀ and the current Z behaving through the winding 17

The power developed by the internal resistance 12 of the signal source with the magnitude ¹ ItR is also the same

g 2E ² IR ₇ which just means that the signal source

there is the known relationship that the total number of 65 ampere-turns of the transformer 10 matched to the fork with the internal resistance 12 is equal to 0, which is already mentioned above, ie, in the exemplary embodiment shown,
in which the number of turns of the winding is 17

In the illustrated circuit, each of the fork resistors 18, 19 is sized to be the same

the characteristic impedance R ensures that the load resistors 13, 14 are effectively decoupled from one another, that is, a change to the terminals 3, 4 does not cause any change to the terminals 5, 6. B. changed one of the load resistors 13 or 14, then according to the Formeini to VI in the specified dimensioning of the fork resistors 18, 19 equal to the characteristic impedance R such a compensating current flow through these fork resistors 18, 19 that the current through the other resistor 14 or 13 and thus also the voltage across this resistor 14 or 13 remain constant. Even with an extraordinary change z. B. the load resistor 13 in the form of an interruption or a short circuit, whereby the current through the load resistor 13 or the voltage across this resistor is zero, there is no change in the other load resistor 14 flowing current, which is equal to the value EIR in the adjusted condition of the fork remains. Conversely, even in the event of a short circuit or interruption of the load resistor 14, the current flowing through the other load resistor 13 will remain equal to the value E / R in the adapted state of the fork.

Besides the mentioned advantages of the illustrated transmission fork, namely no loss of energy in the adapted state and effective decoupling of the fork branches 13,14 from one another the transmission fork according to the invention has the important advantage in electrical terms that the Fork transformer 10 requirements to be made are considerably simplified, since the transformer leakage impedances which could influence the fork properties are particularly low. With the special simple design of the transformer, which contains only three windings with six connection lines, this fork is particularly suitable for miniature construction in transistor technology.

It has been assumed above that the transformation ratio between the winding 17 and the coupling windings 15, 16 is 1: 1: 1; however, the same considerations apply with the same accuracy if a different transformation ratio is used to adapt the signal source 11 to the fork is used.

The following is the data of a fork of the illustrated which has been extensively tested in practice Type specified:

Winding 17: 59 turns, inductance: 10 mH;

Coupling windings 15, 16: 42 turns each and inductance 5 mH each;
Resistors 13, 14, 18, 19: 150 ohms;

Transformation ratio of the windings 17, 16, 15: 1.41: 1: 1.

For the ferromagnetic core of the transformer 10, a cross core with the dimensions -20-20 mm made of highly permeable, non-conductive ferrites, with the dimensions of the transmission fork as a whole will be 16 x 22.5 x 22.5 mm.

For the sake of completeness, it should be noted that the circuit shown is also used for other purposes can be. It can e.g. B. to terminals 8, 9 a two-wire line and to terminals 3, 4 or 5, 6, a transmission branch and a reception branch can be connected, with reference to the one described above Way an effective mutual decoupling between the transmitting branch and the receiving branch is obtained.

Claims (1)

PATENT CLAIM: Transmission fork with a transformer, via which two mutually decoupled fork branches are inductively coupled by two coupling windings to a winding connected to a common fork branch and in which fork resistors are provided for decoupling the two mutually decoupled fork branches, characterized in that between one end of the one Coupling winding (15) and the corresponding end of the other, identical coupling winding (16) each have a fork resistor (18, 19) connected, the value of which is equal to the characteristic impedance of the decoupled fork branches (1, 2), and that the connecting terminals (3, 4 or 5, 6) for the two decoupled fork branches (1, 2) are each formed by that end of one coupling winding (15) and that end of the other coupling winding (16) that are not connected to one another by a fork resistor (18, 19) are connected. Considered publications:
Patent No. 1062 of the Office for Inventions and Patents in the Soviet Zone of Occupation in Germany. 1 sheet of drawings © 309 668/241 8.