DE336453C - Transmitter for damped Hertzian waves - Google Patents

Description

The invention relates to a transmitting apparatus for damped Hertzian waves in which the ripples caused by the oscillating discharge of a battery of capacitors through a Self-induction are generated through it; this self-induction forms the primary winding a vibration transformer whose secondary winding is connected in series with the antenna. The battery is powered by

ίο a multi-phase generator with low periodicity fed either directly or through the intermediary of a step-up transformer. For this purpose, the battery consists of so much Capacitors of the same capacity, "as phases are present. The capacitors are connected in series in such a way that they form a closed polygon, the tips of which are connected to the terminals of the generator. In the course of a period the

ao voltage at the terminals of each of the capacitances of the polygon in succession by the maximum.

This circuit has already been proposed for various arrangements been !, which generally have as many discharge circuits as phases, where the secondary windings of the various vibration transformers in the antenna are connected in series. These arrangements increase the number of devices and complicate the system; in addition, the current of the 'antenna, e.g. B. when using I of a three-phase current, constantly going through two inactive secondary windings.

The invention is characterized by the use of a single high-frequency transformer, whose secondary winding is connected to the antenna, and its primary winding with the capacity to be discharged connected by a special rotating commutator. This commutator is built so that every capacitor of the polygon carries out as many discharges per second as the generator changes polarity Has. The total sum of the discharges per second is therefore equal to twice the product of the periodenzaM and the number of phases. A three-phase generator with 50 periods is e.g. B. 300 discharges result. Between every two discharges, the charging always takes place in the same one Area of the generator electromotive force curve. If further the own frequency of the charge circuit is regulated in such a way that the voltage at the terminals of the capacitor is instantaneously the discharge always goes through, the maximum goes, you get a sequence of discharges in periodic intervals, all of the same electrostatic energy in effectiveness set. The invention thus makes it possible to use generators of fairly low periodicity, which are of a threadier design and are more efficient than the single-phase generators musical frequency (up to 2000 periods) commonly used to generate musical tones.

In the drawing is:

Fig. Ι the circuit diagram of the transmitter when using a three-phase generator ^

Fig. 2 is a diagram of the curves of the electromotive forces at the terminals of the various Capacitors.

The rotating commutator, which successively each capacitor with the oscillator connects can be implemented in the most varied ίο ways.

FIGS. 3, 4 and 5 on the one hand and the

Figs. 6, 7 and - 8, on the other hand, stiff one

first embodiment of the commutator for

a four-pole and a six-pole three-phase generator.

9, 10 and 11 on the one hand and 12, 13 and 14, on the other hand, represent a second embodiment for four-pole and six-pole three-phase generators.

FIGS. 15 and 16 show both embodiments when using a two-pole three-phase generator.

From the terminals of the three phases of the power generator A lead wires go out, which lead through self-induction fuse S to the primary windings of three transformer furnace T ; the secondary windings of these transformers are connected to the vertices C ¹ , C ² , C ^{8 of} a line triangle, in the sides of which three capacitors C, C ", C" are connected. The three lead wires go from the vertices C ¹ , C ² , C ^a to a fixed circle with three points 1, 2, 3. From two tips 4, 5 provided on this stationary circle, two wires go to an oscillation transformer 6, Oudin system, which consists of a self-induction coil. One of the two wires terminates in a fixed contact 8 at one end of the coil and the other wire terminates in an adjustable contact Q at a variable point on the coil. The two ends of the coil are connected to the antenna 7 and to the earth 10. The commutator consists of a rotating part R, which is keyed on the shaft of the generator and rotates within the fixed circle; this part is provided with tips and suitable lead wires, as will be described below, so that at the appropriate moment z. B. the two tips-i and 2 are connected to the tips 4 and 5 so that the capacitor C " is short-circuited through the oscillation transformer 6, whereby an oscillating discharge and a series of waves through the antenna 7 arise.. The three Curves C ¹ -C ² , CO, OC ¹ of FIG. 2 show the voltages at the So terminals of the capacitors C "',. C ", Cf, where the axis ox represents the axis of the times starting from ο.

. When in Figures 3, 4 and 5 shown embodiment of the rotary commutator are the peaks i, 2 and 3 of the fixed circle to which the three phases end, offset by 120 ⁰ with each other; the tips 4 and S, with which the ends of the transformer 6 are connected, are 30 ⁰ right and left of -the tip 1 and are each connected to the 30 ⁰ remote from them tips 4 'and 5'. The rotating part R consists of a group of four equally spaced groups of two points r \ r ² ; r ^a , r ⁴ ", r ^s , r °; r ⁷ , r ^s equipped disc. The two tips of each group are 30 ⁰ apart and are connected to one another; the groups facing one another, e.g. r ¹ , r " and r", r ^e are also connected to one another in pairs. If the tip r ^{1 of} the disk passes in front of the tip 1 of the fixed circle at the time ο and at this moment the voltage at the terminal C " goes through the maximum, then the two vertices C ² , C ³ through the oscillating transformer 6 by means of a circuit: i, r ¹ , r ² , 5, 6, 4, 4 ', r ^s , r ⁴ , "2' connected, and the capacitor C" ' sends an oscillating discharge through the transformer 6.

4 shows the position after the disk R has rotated by 30 ^° ; the sharpener ¹ is opposite the tip 5. Fig. 2 shows that at this moment the voltage at the terminal of C goes through the maximum. Since the generator has four poles, there are four phases for each revolution; the distance 0-12 between two successive phase _{peaks will therefore be equal to V 12} "of the revolution or 30 °, _ Ih 'of the position Fig. 4 are the peaks 2 and 3 through the circuit: 2, r ^s , r ^a , 4, 6, 5Vr ¹ , r ^e , 3 connected; the capacitor C, the voltage of which goes through the maximum, thus causes an oscillating .. discharge, whereby a new series of waves is emitted.

By turning it further by 30 °, the point ^{1 of} the disk R (FIG. 5) comes in front of the point 5 ', whereby the points 1 and 3 are connected, that is, a discharge of the capacitor C " takes place, its voltage in this The moment passes through the maximum and so on. Twelve sparks are produced with one revolution of the commutator or generator.

In a six-pole three-phase generator (Figs. 6, 7 and 8) the rotating part R has twelve tips connected in pairs and arranged in two independent groups. In the position of FIG. 6, the discharge takes place

between the tips ι and "2 through the circuit: 1, r ¹ , r ² , 5, 6, 4 ', r ^x \ r \ r \ 2.

In the position of Fig. 7, the discharge takes place between the tips 2 and 3 through the circuit: 2, r \ r ¹² , 4, .6 ", 5, r ¹ , r ¹⁰ , 3.

In the position of FIG. 8, the discharge takes place between the tips "3 and 1 through the circuit: 3, r \ r ¹⁰ , r \ 5", 6, 4, r ¹¹ , r ¹² , 1.

In the more general case of a two-pole Three-phase generator (Fig. 15) are the Positions of the tips on the fixed and the rotating part at angular intervals expressed as follows:

, e 4 X 120 °
^L O T- * 9 - T- "3 - -

1-4 = 4-4 '= 1-5 = 5-5' =

120

The rotating part R has 4 p tips in

. , ..,, 1 fj 120 ° j IX 120 °

Distancing alternating —— and -.

P P

I2O °

The tips at a distance of are pair-

grouped wisely, and all even-numbered groups of two peaks are electrical united into a polygon, and all odd-numbered groups of two peaks each are electrically united to a second polygon that isolates from the first polygon is.

In Figs. 9, 10 and 11 there is another Embodiment of the commutator for a four-pole three-phase generator shown.

The vertices of the triangle of the capacitors are, as above, with the tips 1, 2, 3 connected, which are arranged offset to one another on the fixed circle I2o °. The tips 4 and 5 are, as above, with

connected to the vibration transformer 6; the tips are 4 'and 5', as are the Tips 4 "and 5", connected together. The angular distances between the different Tips are as follows:

1-2 = 2-3 = 3-1 = i2o °;

2-4 = 2-5 = 3-4 '= 3-5' = _I - ₄ "= r_ ₅ " _{: == 4} 5 °;

The rotating part R has four groups of five points each; the five tips of each group are interconnected. The groups are arranged on the circumference of the disc at a distance of 90 °. The tips

of a group are 15 ° apart. 9 shows the position of the commutator at the moment when the voltage between tips 1 and 2 passes through the maximum; the discharge follows the circuit: 1, 5 ", 4", 5 ', 4', 5, 6, 4, 2, The discharge spark is divided into eight sparks connected in series. :

10 shows the position of the commutator after a rotation of ¹ Z ₁₂ , that is to say at the moment when the voltage between tips 2 and 3 passes through the maximum; the discharge follows the circuit: 2, 5, 6, 4, 5 "» 4 "> 5 '. 4 ', 3

Fig. 11 shows the commutator in the position according to _^2/12 revolution, ie in the moment when the voltage between the points 3 and 1 passes through the maximum; the discharge follows the circuit: 3, 5 ', 4', 5, 6, 4, 5 ", 4", i.

So there is sparking after every twelfth revolution. "

Figures 12, 13 and 14 show the application this second embodiment of the commutator in a six-pole three-phase generator. The rotating part of the commutator has six groups of five tips each arranged at 10 degrees. the Groups are 60 ° apart.

Figures 12, 13 and 14 correspond to Positions of the commutator in the moments where the voltage between the Tips ι-2 or 2-3 or 3-1 by that Maximum goes.

Fig. 16 shows the arrangement of the commutator in a two-pole three-phase generator. The rotating part R has 2 p groups of five tips each. The tips of everyone

20 °

Group have ^j3 - spacing, and the groups

have angular distance; they are of one-

other isolated. The fixed part has eleven points that point to a circle in the following Angular distances are distributed:

1-2 = 1-3 =

240 '

ι- = 1-5 = 2-4 '= 2-5' = 3-4 "= 3-5 =

90 <

The tips 4 '"and 5'" (which are not available on a four-pole generator) close the circuit and stand in one

Distance from 5'-4 " ^/ = 4" -5 '"= ---.

The operation of this commutator is exactly the same as with 'the four and six-pole generators.

The rotating part can be implemented in a wide variety of ways, provided that the commutator always has the same speed of rotation as the Generator. It can possibly be keyed onto the end of the generator shaft. The commutator could as a result of the proportionate

low frequency of the generator driven by a synchronous motor.

Claims (1)

Patent claim: Transmitting apparatus for damped Hertzian waves, containing a multiphase generator, its η clamps with the η vertices of a closed polygon, equal to that of η, are connected in series switched capacitors is formed, characterized in that a rotating Commutator is used, consecutively each of the vertices of the Polygons with the vertex which has the greatest potential difference with the former has through the primary circuit of a single vibration transformer connects at the moment where the potential difference between the two Vertex goes through the maximum, for the purpose of 'discharges per second' the number of which can be equal to twice the product of the number of periods and the number of phases 1 sheet of drawings.