DE1126449B - Multi-wave barrier for power lines - Google Patents

Description

INTERNAT. KL. H 04 j

GERMAN

PATENT OFFICE

T14992VIIIa / 21a ²

REGISTRATION DATE: 12. A P R I L 1958

NOTICE
THE REGISTRATION
AND ISSUE OF
EDITORIAL: MARCH 29, 1962

The invention relates to a multi-wave barrier for power lines, in which at the same time the power and multiple high frequency information with a relatively wide frequency range for each Channel are transmitted, especially for the so-called high-frequency telephony for power plants.

Shaft locks are used to prevent high-frequency energy from flowing away in an undesired direction prevent, they consist of an induction coil assembly and a tuning member.

As is known, in an induction coil provided with a branch, the mutual induction M between the two coil parts on both sides of the branch point B, as indicated in the equivalent circuit diagram in FIG. 1, can be referred to as a negative inductance.

If the induction coil is provided with a branch B , the inductance L measured between one coil end A and branch B is _{L AB} , and between the second coil end C and branch B there is an inductance L [) _C ; the sum of these partial inductances is smaller than the total inductance L _{AC of} the coil (L _AB + L _BC <L _4C ). The equivalent circuit diagram of the induction coil with branch B can therefore be represented as two non-coupled, series-connected inductances L ₁ and L ₂ and a negative inductance - M between the connection point of the inductances and branch point B.

So it applies

L _AC ^

L ₂ = (L _AB + M) + (L _BC + M)

From which follows:

M = I [L _AC - (L _AB + L _BC ) 1.

If an inductance + M is connected in series with the branch point B of the induction coil, two coils L ₁ and L _{2 are obtained} , which are connected in series without mutual coupling, as shown in FIG. The sum of the inductances of the two coils L ₁ and L ₂ then equals the inductance of the original coil L _AC .

It is known in an induction coil assembly for the above-mentioned purpose, which means two connection ends is switched into a conductor of the power line, between the two connection ends lead out at least one intermediate connection with an induction element is connected, which acts as a compensation circuit, the mutual induction between the individual on each other acting through the intermediate connection multi-wave barrier for power lines

Applicant: TESLA, närodni podnik, Prague-EQoubetin

Representative: Dipl.-Ing. A. Spreer, patent attorney, Göttingen, Groner Str. 37

Claimed priority: Czechoslovakia from April 16, 1957 (No. P. V. 1370)

Stepan Siladij, Prague, has been named as the inventor

resulting coil parts of the induction coil arrangement compensated, with between two consecutive Connections including the connection ends on the induction coil assembly and A single tuning element for setting the blocking range via the associated compensation circuit is switched.

This two-shaft barrier shown in FIG. 3 has the advantage that by compensating for the mutual induction M, the induction coil arrangement can be designed with a significantly lower inductance. Their disadvantage, however, is that because of the mutual capacitance of the coil parts, the induction coil arrangement no longer functions as a wave lock at higher frequencies.

The disadvantage of the unbalanced capacity of the individual coil parts occurs with three- and four-wave locks even more expressive. As the number of restricted areas increases, the corresponding Resistances higher frequencies are used, since the effective resistance at the same induction of the induction coil arrangement and the same width of the blocking area proportional to the square of the middle The frequency of the stop band used is, as can be seen from the Bode theorem. Of the As is well known, effective resistance should be about two to three times higher than the wave resistance of the line be.

It must also be taken into account that when information is transmitted over high-voltage

209 557/291

lines the development of the higher frequencies strives, since the wavelengths already used at further expansion is not sufficient.

The invention aims to eliminate the disadvantages mentioned and to create a multi-wave barrier, the scope of which also extends to frequencies above 150 kHz. In this extended area can then be more sufficiently wide with the values of the induction coil arrangement that have been customary up to now Blocked areas for the individual transmission channels are accommodated as before, so that the block except for twice the number of restricted areas in relation to the number of voting devices is tunable. The invention is based on a multi-wave barrier for power lines in which at the same time the power and multiple high-frequency information with a relatively wide frequency range be transmitted for each channel, consisting of an induction coil arrangement, which by means of two connection ends is connected in a conductor of the power line and between the two connection ends has an intermediate terminal which is connected to an induction element, which as Compensation circuit, the mutual induction between the individual interacting, Compensated by the tap coil parts of the induction coil arrangement, with between two consecutive connections to the induction coil arrangement and via the associated one Compensation circuit, a single tuning element is connected to set the blocking range. That The essence of the invention is that in the compensation circuit, the mutual capacitance of the two induction coil parts is compensated by having capacitors parallel to the compensating Induction element are connected in such a way that the can be used for the transmission of messages The high frequency range is extended to frequencies also above 150 kHz and that the lock with the help of of voting members also to a larger or double the number of voting members Number of restricted areas is tunable.

The invention is further illustrated by some exemplary embodiments shown in the drawings explained in more detail. It shows

4 shows an equivalent diagram of an induction coil arrangement with inductive and capacitive coupling,

FIG. 5 shows the impedance equivalent scheme from FIG. 4 after reshaping,

6 shows the simplified substitute scheme after reshaping of FIG. 4,

7 shows an embodiment of the wave lock according to the invention for two or more wave bands with tuning elements in bandpass circuit,

Fig. 8 shows an embodiment of the wave lock according to the invention for two wave bands with Parallel resonance circuits as tuning elements,

9 shows an example of a resistance characteristic curve of a double wave lock according to the invention,

10 shows an example of a resistance characteristic of a four-wave barrier according to the invention.

4 shows an equivalent diagram of the induction coil arrangement with a branch point, where the mutual inductive coupling

and - means the mutual capacitive coupling between the two partial coils, each with an impedance of / CjL ₁ or j co L ₂ .

By reshaping the resistance triangle 012 into a star connection, FIG. 5 results with the following Resistance values:

" Jo) L ₁ · jcoL ₂

Λ.Λ

Xn =

Xr =

/ CjL ₁ -f- jo) L ' ² y 1 I / OjL ₁ + / cj ^L -z + - co C
L. 1 / cj C
>

[Jo) L ₁ + j ο) L ₂ +

jcoC

Since the induction coil arrangement's own anti-resonance frequency for the multi-wave high-frequency barrier must be significantly (approximately three times) greater than the upper limit frequency, the sum jCj) L ₁ + jO) L _{2 is} always significantly (approximately nine times) smaller

as - and can therefore be neglected so

JO) C °

that the following relationships apply to a good approximation:

² SZ ^ = - JcO ³ L ₁ L ₂ C; Z # = Jo) L ₁ ; Xc ⁼ JoL ₂

The mutual capacitive coupling between the parts of the induction coil arrangement can accordingly be taken into account by a ^{reactance - / CJ 3} L ₁ L ₂ C connected in series with the reactance -jcoM (FIG. 4).

The total coupling results from the sum of both mentioned at the branch point of the induction coil arrangement connected reactances

Z = -J

Is practical

a =

so that according to the approximation formula

1 -a

the following relationship is found for the total coupling reactance:

j co M

Z =

L ₁ L ₂ C

This relationship corresponds to the expression for the total reactance of the parallel connection of a negative inductance - M and a negative capacitance
TJC

~ ^K w

(see Fig. 6).

This shows that in the imaginary area the mutual coupling between the two parts of the induction coil arrangement can be compensated S ₀ by adding a capacitance with a corresponding value parallel to the compensating induction element (in the given case induction coil with inductance M)

(in the given case K = '

is switched.

Fine tuning of the capacitance is done by putting M at a low frequency and

then only K is set at a high frequency of the required frequency range.

By compensating for the capacitance of the induction coil assembly parts As mentioned above, it is achieved that the number of blocking areas is achieved with values of the induction coil arrangement that have been customary up to now can be greater than the number of voting members. The voting members are here as in themselves known bandpass or parallel resonance circuits switched.

In Fig. 7, a wave lock for two or more wavebands is shown with tuning elements, which are designed as band-pass filters, the inputs of which are connected in series. The bandpass filters labeled P ₁ and P, are terminated by terminating resistors R ₁ and R ₂ . Each band-pass filter can be implemented as a whole or half element in a basic or transformed circuit. The input transverse inductances of the barrier are formed by the induction coil arrangement, which is provided with a branch connection. The inductive coupling between the two parts of the induction coil arrangement is compensated for by the positive inductance M connected to the junction, and the capacitance of the two parts is compensated for by a capacitance K connected in parallel to the induction coil M.

8 shows a barrier for two wavebands, the tuning elements of which are designed with a significantly smaller number of elements than bandpass filters, which are connected as parallel resonance circuits A ₁ and A ₂ damped by the ohmic resistors R _A and R ₁ . The attenuation can, however, also be achieved by ohmic resistors connected in series. The parallel resonance circuits can also remain undamped. The inductive coupling of the two parts of the induction coil arrangement provided with a branch connection is again compensated by a positive inductance M connected to the branch connection, and the capacitance of the two parts is compensated by a capacitance connected in parallel to the compensating induction coil M.

A block for two wavebands can be achieved in a known manner in that each part of the induction coil arrangement, to whose branch connection the compensating inductance M is connected, is matched with the associated tuning element to a waveband, both tuning elements either by bandpass filters, their terminating resistors R ₁ and R _{9 have} a value equal to the nominal value, or are formed by damped or undamped parallel resonance circuits, or a tuning element as a bandpass filter whose terminating resistor has a value equal to the nominal value and the other tuning element is connected as a parallel resonance circuit. The inventive capacitance compensation of the two parts of the induction coil arrangement makes it possible to use these locks also for higher frequencies.

An example of the resistance curve showing the active component of the blocking impedance as a function the frequency represents, is for double-wave barriers with as bandpass filters with nominal value terminating resistors switched tuning elements shown in FIG.

If the tuning element switched as a bandpass filter is not terminated by the nominal value terminating resistor is, but with a π-termination network by a larger one, with a T-termination network with a smaller resistance, it can be tuned to two wavebands, so that with the help of two such tuning members a lock for four wavebands is achieved.

An example of a resistance characteristic of a wave barrier for four wave bands is shown in FIG.

If a tuning element is designed as a bandpass filter with a terminating resistor that differs from the nominal value so that it can be tuned to two wavebands, and the other as attenuated or Undamped parallel resonance circuit or as a bandpass filter terminated with a nominal value terminating resistor is executed, there is a lock for three wavebands.

Especially with these multi-wave barriers for three or more wave ranges the advantage of Capacitance compensation of the two parts of the induction coil assembly comes into its own with regard to to the achievement of the required effective resistance already mentioned at the beginning.

Claims (3)

PATENT CLAIMS: 1.Multi-wave barrier for power lines, in which the power and multiple high-frequency information are transmitted simultaneously with a relatively wide frequency range for each channel, consisting of an induction coil arrangement which is connected to a conductor of the power line by means of two connection ends and has an intermediate connection between the two connection ends, which is connected to an induction element which, as a compensation circuit, compensates for the mutual induction between the individual coil parts of the induction coil arrangement that act on one another and are created by the tap, whereby a single tuning element for setting the blocking range is connected between two consecutive connections on the induction coil arrangement and via the associated compensation circuit is characterized in that the mutual capacitance of the two induction coil parts is compensated in the compensation circuit, that capacitors (K) are connected in parallel to the compensating induction element (M) in such a way that the high-frequency range that can be used for communication is extended to frequencies above 150 kHz, and that the lock is activated with the aid of the tuning elements (D ₁ , D ₂ in FIG ) can also be tuned to a number of restricted areas that is greater than or equal to twice the number of voting members. 2. Multi-wave barrier according to claim 1, characterized in that a tuning element (D ₁ in Fig. 3) with the associated part of the induction coil arrangement and the compensation circuit forms a bandpass circuit whose terminating resistor has a value different from the nominal value, and that the second part the induction coil arrangement connected tuning element (D ₂ ) with this part and the compensation circuit a with the nominal value of the terminating resistor closed bandpass circuit (Fig. 7) or a damped or undamped parallel resonance circuit (Fig. 8) forms, so that there is a three-wave lock. 3. Multi-wave barrier according to claim 1, characterized in that each tuning element (D ₁ , D ₂ in Fig. 3) with the compensation circuit and the induction coil part to which it is connected, forms a bandpass circuit (Fig. 7) and that the inputs of this Bandpass circuits in Are connected in series and their terminating resistances differ from the nominal value, so that results in a four-wave lock. Considered publications: The Bell System Technical Journal, April 1951, pp. 428/429. Older patents considered: ίο German Patent No. 1 067 481. 1 sheet of drawings